codec2/include/C2.h - platform/hardware/google/av - Git at Google

 /*
  * 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 C2_H_
 #define C2_H_

 #include <errno.h>

 #include <string>

 /** nanoseconds with arbitrary origin. */
 typedef int64_t c2_nsecs_t;

 /** \mainpage Codec2
  *
  * Codec2 is a generic frame-based data processing API.
  *
  * The media subsystem accesses components via the \ref API.
  */

 /** \ingroup API
  *
  * The Codec2 API defines the operation of data processing components and their interaction with
  * the rest of the system.
  *
  * Coding Conventions
  *
  * Mitigating Binary Compatibility.
  *
  * While full binary compatibility is not a goal of the API (due to our use of STL), we try to
  * mitigate binary breaks by adhering to the following conventions:
  *
  * - at most one vtable with placeholder virtual methods
  * - all optional/placeholder virtual methods returning a c2_status_t, with C2_OMITTED not requiring
  *   any update to input/output arguments.
  * - limiting symbol export of inline methods
  * - use of pimpl (or shared-pimpl)
  *
  * Naming
  *
  * - all classes and types prefix with C2
  * - classes for internal use prefix with _C2
  * - enum values in global namespace prefix with C2_ all caps
  * - enum values inside classes have no C2_ prefix as class already has it
  * - supporting two kinds of enum naming: all-caps and kCamelCase
  * \todo revisit kCamelCase for param-type
  *
  * Aspects
  *
  * Aspects define certain common behavior across a group of objects.
  * - classes whose name matches _C2.*Aspect
  * - only protected constructors
  * - no desctructor and copiable
  * - all methods are inline or static (this is opposite of the interface paradigm where all methods
  *   are virtual, which would not work due to the at most one vtable rule.)
  * - only private variables (this prevents subclasses interfering with the aspects.)
  */

 /// \defgroup types Common Types
 /// @{

 /**
  * C2String: basic string implementation
  */
 typedef std::string C2String;

 /**
  * C2StringLiteral: basic string literal implementation.
  * \note these are never owned by any object, and can only refer to C string literals.
  */
 typedef const char *C2StringLiteral;

 /**
  * c2_status_t: status codes used.
  */
 enum c2_status_t : int32_t {
 /*
  * Use POSIX errno constants.
  */
     C2_OK        = 0,            ///< operation completed successfully

     // bad input
     C2_BAD_VALUE = EINVAL,       ///< argument has invalid value (user error)
     C2_BAD_INDEX = ENXIO,        ///< argument uses invalid index (user error)
     C2_CANNOT_DO = ENOTSUP,      ///< argument/index is valid but not possible

     // bad sequencing of events
     C2_DUPLICATE = EEXIST,       ///< object already exists
     C2_NOT_FOUND = ENOENT,       ///< object not found
     C2_BAD_STATE = EPERM,        ///< operation is not permitted in the current state
     C2_BLOCKING  = EWOULDBLOCK,  ///< operation would block but blocking is not permitted
     C2_CANCELED  = EINTR,        ///< operation interrupted/canceled

     // bad environment
     C2_NO_MEMORY = ENOMEM,       ///< not enough memory to complete operation
     C2_REFUSED   = EACCES,       ///< missing permission to complete operation

     C2_TIMED_OUT = ETIMEDOUT,    ///< operation did not complete within timeout

     // bad versioning
     C2_OMITTED   = ENOSYS,       ///< operation is not implemented/supported (optional only)

     // unknown fatal
     C2_CORRUPTED = EFAULT,       ///< some unexpected error prevented the operation
     C2_NO_INIT   = ENODEV,       ///< status has not been initialized
 };

 /**
  * Type that describes the desired blocking behavior for variable blocking calls. Blocking in this
  * API is used in a somewhat modified meaning such that operations that merely update variables
  * protected by mutexes are still considered "non-blocking" (always used in quotes).
  */
 enum c2_blocking_t : int32_t {
     /**
      * The operation SHALL be "non-blocking". This means that it shall not perform any file
      * operations, or call/wait on other processes. It may use a protected region as long as the
      * mutex is never used to protect code that is otherwise "may block".
      */
     C2_DONT_BLOCK = false,
     /**
      * The operation MAY be temporarily blocking.
      */
     C2_MAY_BLOCK = true,
 };

 /// @}

 /// \defgroup utils Utilities
 /// @{

 #define C2_DO_NOT_COPY(type) \
     type& operator=(const type &) = delete; \
     type(const type &) = delete; \

 #define C2_DEFAULT_MOVE(type) \
     type& operator=(type &&) = default; \
     type(type &&) = default; \

 #define C2_ALLOW_OVERFLOW __attribute__((no_sanitize("integer")))
 #define C2_CONST    __attribute__((const))
 #define C2_HIDE     __attribute__((visibility("hidden")))
 #define C2_INLINE   inline C2_HIDE
 #define C2_INTERNAL __attribute__((internal_linkage))
 #define C2_PACK     __attribute__((aligned(4)))
 #define C2_PURE     __attribute__((pure))

 #define DEFINE_OTHER_COMPARISON_OPERATORS(type) \
     inline bool operator!=(const type &other) const { return !(*this == other); } \
     inline bool operator<=(const type &other) const { return (*this == other) || (*this < other); } \
     inline bool operator>=(const type &other) const { return !(*this < other); } \
     inline bool operator>(const type &other) const { return !(*this < other) && !(*this == other); }

 #define DEFINE_FIELD_BASED_COMPARISON_OPERATORS(type, field) \
     inline bool operator<(const type &other) const { return field < other.field; } \
     inline bool operator==(const type &other) const { return field == other.field; } \
     DEFINE_OTHER_COMPARISON_OPERATORS(type)

 #define DEFINE_FIELD_AND_MASK_BASED_COMPARISON_OPERATORS(type, field, mask) \
     inline bool operator<(const type &other) const { \
         return (field & mask) < (other.field & (mask)); \
     } \
     inline bool operator==(const type &other) const { \
         return (field & mask) == (other.field & (mask)); \
     } \
     DEFINE_OTHER_COMPARISON_OPERATORS(type)

 #define DEFINE_ENUM_OPERATORS(etype) \
     inline constexpr etype operator|(etype a, etype b) { return (etype)(std::underlying_type<etype>::type(a) | std::underlying_type<etype>::type(b)); } \
     inline constexpr etype &operator|=(etype &a, etype b) { a = (etype)(std::underlying_type<etype>::type(a) | std::underlying_type<etype>::type(b)); return a; } \
     inline constexpr etype operator&(etype a, etype b) { return (etype)(std::underlying_type<etype>::type(a) & std::underlying_type<etype>::type(b)); } \
     inline constexpr etype &operator&=(etype &a, etype b) { a = (etype)(std::underlying_type<etype>::type(a) & std::underlying_type<etype>::type(b)); return a; } \
     inline constexpr etype operator^(etype a, etype b) { return (etype)(std::underlying_type<etype>::type(a) ^ std::underlying_type<etype>::type(b)); } \
     inline constexpr etype &operator^=(etype &a, etype b) { a = (etype)(std::underlying_type<etype>::type(a) ^ std::underlying_type<etype>::type(b)); return a; } \
     inline constexpr etype operator~(etype a) { return (etype)(~std::underlying_type<etype>::type(a)); }

 template<typename T, typename B>
 class C2_HIDE c2_cntr_t;

 /// \cond INTERNAL

 /// \defgroup utils_internal
 /// @{

 template<typename T>
 struct C2_HIDE _c2_cntr_compat_helper {
     template<typename U, typename E=typename std::enable_if<std::is_integral<U>::value>::type>
     C2_ALLOW_OVERFLOW
     inline static constexpr T get(const U &value) {
         return T(value);
     }

     template<typename U, typename E=typename std::enable_if<(sizeof(U) >= sizeof(T))>::type>
     C2_ALLOW_OVERFLOW
     inline static constexpr T get(const c2_cntr_t<U, void> &value) {
         return T(value.mValue);
     }
 };

 /// @}

 /// \endcond

 /**
  * Integral counter type.
  *
  * This is basically an unsigned integral type that is NEVER checked for overflow/underflow - and
  * comparison operators are redefined.
  *
  * \note Comparison of counter types is not fully transitive, e.g.
  * it could be that a > b > c but a !> c.
  * std::less<>, greater<>, less_equal<> and greater_equal<> specializations yield total ordering,
  * but may not match semantic ordering of the values.
  *
  * Technically: counter types represent integer values: A * 2^N + value, where A can be arbitrary.
  * This makes addition, subtraction, multiplication (as well as bitwise operations) well defined.
  * However, division is in general not well defined, as the result may depend on A. This is also
  * true for logical operators and boolean conversion.
  *
  * Even though well defined, bitwise operators are not implemented for counter types as they are not
  * meaningful.
  */
 template<typename T, typename B=typename std::enable_if<std::is_integral<T>::value && std::is_unsigned<T>::value>::type>
 class C2_HIDE c2_cntr_t {
     using compat = _c2_cntr_compat_helper<T>;

     T mValue;
     constexpr static T HALF_RANGE = T(~0) ^ (T(~0) >> 1);

     template<typename U>
     friend struct _c2_cntr_compat_helper;
 public:

     /**
      * Default constructor. Initialized counter to 0.
      */
     inline constexpr c2_cntr_t() : mValue(T(0)) {}

     /**
      * Construct from a compatible type.
      */
     template<typename U>
     inline constexpr c2_cntr_t(const U &value) : mValue(compat::get(value)) {}

     /**
      * Peek as underlying signed type.
      */
     C2_ALLOW_OVERFLOW
     inline constexpr typename std::make_signed<T>::type peek() const {
         return static_cast<typename std::make_signed<T>::type>(mValue);
     }

     /**
      * Peek as underlying unsigned type.
      */
     inline constexpr T peeku() const {
         return mValue;
     }

     /**
      * Peek as long long - e.g. for printing.
      */
     C2_ALLOW_OVERFLOW
     inline constexpr long long peekll() const {
         return (long long)mValue;
     }

     /**
      * Peek as unsigned long long - e.g. for printing.
      */
     C2_ALLOW_OVERFLOW
     inline constexpr unsigned long long peekull() const {
         return (unsigned long long)mValue;
     }

     /**
      * Convert to a smaller counter type. This is always safe.
      */
     template<typename U, typename E=typename std::enable_if<(sizeof(U) < sizeof(T))>::type>
     inline constexpr operator c2_cntr_t<U>() {
         return c2_cntr_t<U>(mValue);
     }

     /**
      * Arithmetic operators
      */

 #define DEFINE_C2_CNTR_BINARY_OP(attrib, op, op_assign) \
     template<typename U> \
     attrib inline c2_cntr_t<T>& operator op_assign(const U &value) { \
         mValue op_assign compat::get(value); \
         return *this; \
     } \
     \
     template<typename U, typename E=decltype(compat::get(U(0)))> \
     attrib inline constexpr c2_cntr_t<T> operator op(const U &value) const { \
         return c2_cntr_t<T>(mValue op compat::get(value)); \
     } \
     \
     template<typename U, typename E=typename std::enable_if<(sizeof(U) < sizeof(T))>::type> \
     attrib inline constexpr c2_cntr_t<U> operator op(const c2_cntr_t<U> &value) const { \
         return c2_cntr_t<U>(U(mValue) op value.peeku()); \
     }

 #define DEFINE_C2_CNTR_UNARY_OP(attrib, op) \
     attrib inline constexpr c2_cntr_t<T> operator op() const { \
         return c2_cntr_t<T>(op mValue); \
     }

 #define DEFINE_C2_CNTR_CREMENT_OP(attrib, op) \
     attrib inline c2_cntr_t<T> &operator op() { \
         op mValue; \
         return *this; \
     } \
     attrib inline c2_cntr_t<T> operator op(int) { \
         return c2_cntr_t<T, void>(mValue op); \
     }

     DEFINE_C2_CNTR_BINARY_OP(C2_ALLOW_OVERFLOW, +, +=)
     DEFINE_C2_CNTR_BINARY_OP(C2_ALLOW_OVERFLOW, -, -=)
     DEFINE_C2_CNTR_BINARY_OP(C2_ALLOW_OVERFLOW, *, *=)

     DEFINE_C2_CNTR_UNARY_OP(C2_ALLOW_OVERFLOW, -)
     DEFINE_C2_CNTR_UNARY_OP(C2_ALLOW_OVERFLOW, +)

     DEFINE_C2_CNTR_CREMENT_OP(C2_ALLOW_OVERFLOW, ++)
     DEFINE_C2_CNTR_CREMENT_OP(C2_ALLOW_OVERFLOW, --)

     template<typename U, typename E=typename std::enable_if<std::is_unsigned<U>::value>::type>
     C2_ALLOW_OVERFLOW
     inline constexpr c2_cntr_t<T> operator<<(const U &value) const {
         return c2_cntr_t<T>(mValue << value);
     }

     template<typename U, typename E=typename std::enable_if<std::is_unsigned<U>::value>::type>
     C2_ALLOW_OVERFLOW
     inline c2_cntr_t<T> &operator<<=(const U &value) {
         mValue <<= value;
         return *this;
     }

     /**
      * Comparison operators
      */
     C2_ALLOW_OVERFLOW
     inline constexpr bool operator<=(const c2_cntr_t<T> &other) const {
         return T(other.mValue - mValue) < HALF_RANGE;
     }

     C2_ALLOW_OVERFLOW
     inline constexpr bool operator>=(const c2_cntr_t<T> &other) const {
         return T(mValue - other.mValue) < HALF_RANGE;
     }

     inline constexpr bool operator==(const c2_cntr_t<T> &other) const {
         return mValue == other.mValue;
     }

     inline constexpr bool operator!=(const c2_cntr_t<T> &other) const {
         return !(*this == other);
     }

     inline constexpr bool operator<(const c2_cntr_t<T> &other) const {
         return *this <= other && *this != other;
     }

     inline constexpr bool operator>(const c2_cntr_t<T> &other) const {
         return *this >= other && *this != other;
     }
 };

 template<typename U, typename T, typename E=typename std::enable_if<std::is_integral<U>::value>::type>
 inline constexpr c2_cntr_t<T> operator+(const U &a, const c2_cntr_t<T> &b) {
     return b + a;
 }

 template<typename U, typename T, typename E=typename std::enable_if<std::is_integral<U>::value>::type>
 inline constexpr c2_cntr_t<T> operator-(const U &a, const c2_cntr_t<T> &b) {
     return c2_cntr_t<T>(a) - b;
 }

 template<typename U, typename T, typename E=typename std::enable_if<std::is_integral<U>::value>::type>
 inline constexpr c2_cntr_t<T> operator*(const U &a, const c2_cntr_t<T> &b) {
     return b * a;
 }

 typedef c2_cntr_t<uint32_t> c2_cntr32_t; /** 32-bit counter type */
 typedef c2_cntr_t<uint64_t> c2_cntr64_t; /** 64-bit counter type */

 /// \cond INTERNAL

 /// \defgroup utils_internal
 /// @{

 template<typename... T> struct c2_types;

 /** specialization for a single type */
 template<typename T>
 struct c2_types<T> {
     typedef typename std::decay<T>::type wide_type;
     typedef wide_type narrow_type;
     typedef wide_type min_type; // type for min(T...)
 };

 /** specialization for two types */
 template<typename T, typename U>
 struct c2_types<T, U> {
     static_assert(std::is_floating_point<T>::value == std::is_floating_point<U>::value,
                   "mixing floating point and non-floating point types is disallowed");
     static_assert(std::is_signed<T>::value == std::is_signed<U>::value,
                   "mixing signed and unsigned types is disallowed");

     typedef typename std::decay<
             decltype(true ? std::declval<T>() : std::declval<U>())>::type wide_type;
     typedef typename std::decay<
             typename std::conditional<sizeof(T) < sizeof(U), T, U>::type>::type narrow_type;
     typedef typename std::conditional<
             std::is_signed<T>::value, wide_type, narrow_type>::type min_type;
 };

 /// @}

 /// \endcond

 /**
  * Type support utility class. Only supports similar classes, such as:
  * - all floating point
  * - all unsigned/all signed
  * - all pointer
  */
 template<typename T, typename U, typename... V>
 struct c2_types<T, U, V...> {
     /** Common type that accommodates all template parameter types. */
     typedef typename c2_types<typename c2_types<T, U>::wide_type, V...>::wide_type wide_type;
     /** Narrowest type of the template parameter types. */
     typedef typename c2_types<typename c2_types<T, U>::narrow_type, V...>::narrow_type narrow_type;
     /** Type that accommodates the minimum value for any input for the template parameter types. */
     typedef typename c2_types<typename c2_types<T, U>::min_type, V...>::min_type min_type;
 };

 /**
  *  \ingroup utils_internal
  * specialization for two values */
 template<typename T, typename U>
 inline constexpr typename c2_types<T, U>::wide_type c2_max(const T a, const U b) {
     typedef typename c2_types<T, U>::wide_type wide_type;
     return ({ wide_type a_(a), b_(b); a_ > b_ ? a_ : b_; });
 }

 /**
  * Finds the maximum value of a list of "similarly typed" values.
  *
  * This is an extension to std::max where the types do not have to be identical, and the smallest
  * resulting type is used that accommodates the argument types.
  *
  * \note Value types must be similar, e.g. all floating point, all pointers, all signed, or all
  * unsigned.
  *
  * @return the largest of the input arguments.
  */
 template<typename T, typename U, typename... V>
 constexpr typename c2_types<T, U, V...>::wide_type c2_max(const T a, const U b, const V ... c) {
     typedef typename c2_types<T, U, V...>::wide_type wide_type;
     return ({ wide_type a_(a), b_(c2_max(b, c...)); a_ > b_ ? a_ : b_; });
 }

 /**
  *  \ingroup utils_internal
  * specialization for two values */
 template<typename T, typename U>
 inline constexpr typename c2_types<T, U>::min_type c2_min(const T a, const U b) {
     typedef typename c2_types<T, U>::wide_type wide_type;
     return ({
         wide_type a_(a), b_(b);
         static_cast<typename c2_types<T, U>::min_type>(a_ < b_ ? a_ : b_);
     });
 }

 /**
  * Finds the minimum value of a list of "similarly typed" values.
  *
  * This is an extension to std::min where the types do not have to be identical, and the smallest
  * resulting type is used that accommodates the argument types.
  *
  * \note Value types must be similar, e.g. all floating point, all pointers, all signed, or all
  * unsigned.
  *
  * @return the smallest of the input arguments.
  */
 template<typename T, typename U, typename... V>
 constexpr typename c2_types<T, U, V...>::min_type c2_min(const T a, const U b, const V ... c) {
     typedef typename c2_types<U, V...>::min_type rest_type;
     typedef typename c2_types<T, rest_type>::wide_type wide_type;
     return ({
         wide_type a_(a), b_(c2_min(b, c...));
         static_cast<typename c2_types<T, rest_type>::min_type>(a_ < b_ ? a_ : b_);
     });
 }

 /**
  *  \ingroup utils_internal
  */
 template<typename T, typename U, typename V>
 inline constexpr typename c2_types<T, V>::wide_type c2_clamp(const T a, const U b, const V c) {
     typedef typename c2_types<T, U, V>::wide_type wide_type;
     return ({
         wide_type a_(a), b_(b), c_(c);
         static_cast<typename c2_types<T, V>::wide_type>(b_ < a_ ? a_ : b_ > c_ ? c_ : b_);
     });
 }

 /// @}

 #include <functional>
 template<typename T>
 struct std::less<::c2_cntr_t<T>> {
     constexpr bool operator()(const ::c2_cntr_t<T> &lh, const ::c2_cntr_t<T> &rh) const {
         return lh.peeku() < rh.peeku();
     }
 };
 template<typename T>
 struct std::less_equal<::c2_cntr_t<T>> {
     constexpr bool operator()(const ::c2_cntr_t<T> &lh, const ::c2_cntr_t<T> &rh) const {
         return lh.peeku() <= rh.peeku();
     }
 };
 template<typename T>
 struct std::greater<::c2_cntr_t<T>> {
     constexpr bool operator()(const ::c2_cntr_t<T> &lh, const ::c2_cntr_t<T> &rh) const {
         return lh.peeku() > rh.peeku();
     }
 };
 template<typename T>
 struct std::greater_equal<::c2_cntr_t<T>> {
     constexpr bool operator()(const ::c2_cntr_t<T> &lh, const ::c2_cntr_t<T> &rh) const {
         return lh.peeku() >= rh.peeku();
     }
 };

 #endif  // C2_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 C2_H_
	#define C2_H_

	#include <errno.h>

	#include <string>

	/** nanoseconds with arbitrary origin. */
	typedef int64_t c2_nsecs_t;

	/** \mainpage Codec2
	*
	* Codec2 is a generic frame-based data processing API.
	*
	* The media subsystem accesses components via the \ref API.
	*/

	/** \ingroup API
	*
	* The Codec2 API defines the operation of data processing components and their interaction with
	* the rest of the system.
	*
	* Coding Conventions
	*
	* Mitigating Binary Compatibility.
	*
	* While full binary compatibility is not a goal of the API (due to our use of STL), we try to
	* mitigate binary breaks by adhering to the following conventions:
	*
	* - at most one vtable with placeholder virtual methods
	* - all optional/placeholder virtual methods returning a c2_status_t, with C2_OMITTED not requiring
	* any update to input/output arguments.
	* - limiting symbol export of inline methods
	* - use of pimpl (or shared-pimpl)
	*
	* Naming
	*
	* - all classes and types prefix with C2
	* - classes for internal use prefix with _C2
	* - enum values in global namespace prefix with C2_ all caps
	* - enum values inside classes have no C2_ prefix as class already has it
	* - supporting two kinds of enum naming: all-caps and kCamelCase
	* \todo revisit kCamelCase for param-type
	*
	* Aspects
	*
	* Aspects define certain common behavior across a group of objects.
	* - classes whose name matches _C2.*Aspect
	* - only protected constructors
	* - no desctructor and copiable
	* - all methods are inline or static (this is opposite of the interface paradigm where all methods
	* are virtual, which would not work due to the at most one vtable rule.)
	* - only private variables (this prevents subclasses interfering with the aspects.)
	*/

	/// \defgroup types Common Types
	/// @{

	/**
	* C2String: basic string implementation
	*/
	typedef std::string C2String;

	/**
	* C2StringLiteral: basic string literal implementation.
	* \note these are never owned by any object, and can only refer to C string literals.
	*/
	typedef const char *C2StringLiteral;

	/**
	* c2_status_t: status codes used.
	*/
	enum c2_status_t : int32_t {
	/*
	* Use POSIX errno constants.
	*/
	C2_OK = 0, ///< operation completed successfully

	// bad input
	C2_BAD_VALUE = EINVAL, ///< argument has invalid value (user error)
	C2_BAD_INDEX = ENXIO, ///< argument uses invalid index (user error)
	C2_CANNOT_DO = ENOTSUP, ///< argument/index is valid but not possible

	// bad sequencing of events
	C2_DUPLICATE = EEXIST, ///< object already exists
	C2_NOT_FOUND = ENOENT, ///< object not found
	C2_BAD_STATE = EPERM, ///< operation is not permitted in the current state
	C2_BLOCKING = EWOULDBLOCK, ///< operation would block but blocking is not permitted
	C2_CANCELED = EINTR, ///< operation interrupted/canceled

	// bad environment
	C2_NO_MEMORY = ENOMEM, ///< not enough memory to complete operation
	C2_REFUSED = EACCES, ///< missing permission to complete operation

	C2_TIMED_OUT = ETIMEDOUT, ///< operation did not complete within timeout

	// bad versioning
	C2_OMITTED = ENOSYS, ///< operation is not implemented/supported (optional only)

	// unknown fatal
	C2_CORRUPTED = EFAULT, ///< some unexpected error prevented the operation
	C2_NO_INIT = ENODEV, ///< status has not been initialized
	};

	/**
	* Type that describes the desired blocking behavior for variable blocking calls. Blocking in this
	* API is used in a somewhat modified meaning such that operations that merely update variables
	* protected by mutexes are still considered "non-blocking" (always used in quotes).
	*/
	enum c2_blocking_t : int32_t {
	/**
	* The operation SHALL be "non-blocking". This means that it shall not perform any file
	* operations, or call/wait on other processes. It may use a protected region as long as the
	* mutex is never used to protect code that is otherwise "may block".
	*/
	C2_DONT_BLOCK = false,
	/**
	* The operation MAY be temporarily blocking.
	*/
	C2_MAY_BLOCK = true,
	};

	/// @}

	/// \defgroup utils Utilities
	/// @{

	#define C2_DO_NOT_COPY(type) \
	type& operator=(const type &) = delete; \
	type(const type &) = delete; \

	#define C2_DEFAULT_MOVE(type) \
	type& operator=(type &&) = default; \
	type(type &&) = default; \

	#define C2_ALLOW_OVERFLOW __attribute__((no_sanitize("integer")))
	#define C2_CONST __attribute__((const))
	#define C2_HIDE __attribute__((visibility("hidden")))
	#define C2_INLINE inline C2_HIDE
	#define C2_INTERNAL __attribute__((internal_linkage))
	#define C2_PACK __attribute__((aligned(4)))
	#define C2_PURE __attribute__((pure))

	#define DEFINE_OTHER_COMPARISON_OPERATORS(type) \
	inline bool operator!=(const type &other) const { return !(*this == other); } \
	inline bool operator<=(const type &other) const { return (this == other) \|\| (this < other); } \
	inline bool operator>=(const type &other) const { return !(*this < other); } \
	inline bool operator>(const type &other) const { return !(this < other) && !(this == other); }

	#define DEFINE_FIELD_BASED_COMPARISON_OPERATORS(type, field) \
	inline bool operator<(const type &other) const { return field < other.field; } \
	inline bool operator==(const type &other) const { return field == other.field; } \
	DEFINE_OTHER_COMPARISON_OPERATORS(type)

	#define DEFINE_FIELD_AND_MASK_BASED_COMPARISON_OPERATORS(type, field, mask) \
	inline bool operator<(const type &other) const { \
	return (field & mask) < (other.field & (mask)); \
	} \
	inline bool operator==(const type &other) const { \
	return (field & mask) == (other.field & (mask)); \
	} \
	DEFINE_OTHER_COMPARISON_OPERATORS(type)

	#define DEFINE_ENUM_OPERATORS(etype) \
	inline constexpr etype operator\|(etype a, etype b) { return (etype)(std::underlying_type<etype>::type(a) \| std::underlying_type<etype>::type(b)); } \
	inline constexpr etype &operator\|=(etype &a, etype b) { a = (etype)(std::underlying_type<etype>::type(a) \| std::underlying_type<etype>::type(b)); return a; } \
	inline constexpr etype operator&(etype a, etype b) { return (etype)(std::underlying_type<etype>::type(a) & std::underlying_type<etype>::type(b)); } \
	inline constexpr etype &operator&=(etype &a, etype b) { a = (etype)(std::underlying_type<etype>::type(a) & std::underlying_type<etype>::type(b)); return a; } \
	inline constexpr etype operator^(etype a, etype b) { return (etype)(std::underlying_type<etype>::type(a) ^ std::underlying_type<etype>::type(b)); } \
	inline constexpr etype &operator^=(etype &a, etype b) { a = (etype)(std::underlying_type<etype>::type(a) ^ std::underlying_type<etype>::type(b)); return a; } \
	inline constexpr etype operator~(etype a) { return (etype)(~std::underlying_type<etype>::type(a)); }

	template<typename T, typename B>
	class C2_HIDE c2_cntr_t;

	/// \cond INTERNAL

	/// \defgroup utils_internal
	/// @{

	template<typename T>
	struct C2_HIDE _c2_cntr_compat_helper {
	template<typename U, typename E=typename std::enable_if<std::is_integral<U>::value>::type>
	C2_ALLOW_OVERFLOW
	inline static constexpr T get(const U &value) {
	return T(value);
	}

	template<typename U, typename E=typename std::enable_if<(sizeof(U) >= sizeof(T))>::type>
	C2_ALLOW_OVERFLOW
	inline static constexpr T get(const c2_cntr_t<U, void> &value) {
	return T(value.mValue);
	}
	};

	/// @}

	/// \endcond

	/**
	* Integral counter type.
	*
	* This is basically an unsigned integral type that is NEVER checked for overflow/underflow - and
	* comparison operators are redefined.
	*
	* \note Comparison of counter types is not fully transitive, e.g.
	* it could be that a > b > c but a !> c.
	* std::less<>, greater<>, less_equal<> and greater_equal<> specializations yield total ordering,
	* but may not match semantic ordering of the values.
	*
	* Technically: counter types represent integer values: A * 2^N + value, where A can be arbitrary.
	* This makes addition, subtraction, multiplication (as well as bitwise operations) well defined.
	* However, division is in general not well defined, as the result may depend on A. This is also
	* true for logical operators and boolean conversion.
	*
	* Even though well defined, bitwise operators are not implemented for counter types as they are not
	* meaningful.
	*/
	template<typename T, typename B=typename std::enable_if<std::is_integral<T>::value && std::is_unsigned<T>::value>::type>
	class C2_HIDE c2_cntr_t {
	using compat = _c2_cntr_compat_helper<T>;

	T mValue;
	constexpr static T HALF_RANGE = T(~0) ^ (T(~0) >> 1);

	template<typename U>
	friend struct _c2_cntr_compat_helper;
	public:

	/**
	* Default constructor. Initialized counter to 0.
	*/
	inline constexpr c2_cntr_t() : mValue(T(0)) {}

	/**
	* Construct from a compatible type.
	*/
	template<typename U>
	inline constexpr c2_cntr_t(const U &value) : mValue(compat::get(value)) {}

	/**
	* Peek as underlying signed type.
	*/
	C2_ALLOW_OVERFLOW
	inline constexpr typename std::make_signed<T>::type peek() const {
	return static_cast<typename std::make_signed<T>::type>(mValue);
	}

	/**
	* Peek as underlying unsigned type.
	*/
	inline constexpr T peeku() const {
	return mValue;
	}

	/**
	* Peek as long long - e.g. for printing.
	*/
	C2_ALLOW_OVERFLOW
	inline constexpr long long peekll() const {
	return (long long)mValue;
	}

	/**
	* Peek as unsigned long long - e.g. for printing.
	*/
	C2_ALLOW_OVERFLOW
	inline constexpr unsigned long long peekull() const {
	return (unsigned long long)mValue;
	}

	/**
	* Convert to a smaller counter type. This is always safe.
	*/
	template<typename U, typename E=typename std::enable_if<(sizeof(U) < sizeof(T))>::type>
	inline constexpr operator c2_cntr_t<U>() {
	return c2_cntr_t<U>(mValue);
	}

	/**
	* Arithmetic operators
	*/

	#define DEFINE_C2_CNTR_BINARY_OP(attrib, op, op_assign) \
	template<typename U> \
	attrib inline c2_cntr_t<T>& operator op_assign(const U &value) { \
	mValue op_assign compat::get(value); \
	return *this; \
	} \
	\
	template<typename U, typename E=decltype(compat::get(U(0)))> \
	attrib inline constexpr c2_cntr_t<T> operator op(const U &value) const { \
	return c2_cntr_t<T>(mValue op compat::get(value)); \
	} \
	\
	template<typename U, typename E=typename std::enable_if<(sizeof(U) < sizeof(T))>::type> \
	attrib inline constexpr c2_cntr_t<U> operator op(const c2_cntr_t<U> &value) const { \
	return c2_cntr_t<U>(U(mValue) op value.peeku()); \
	}

	#define DEFINE_C2_CNTR_UNARY_OP(attrib, op) \
	attrib inline constexpr c2_cntr_t<T> operator op() const { \
	return c2_cntr_t<T>(op mValue); \
	}

	#define DEFINE_C2_CNTR_CREMENT_OP(attrib, op) \
	attrib inline c2_cntr_t<T> &operator op() { \
	op mValue; \
	return *this; \
	} \
	attrib inline c2_cntr_t<T> operator op(int) { \
	return c2_cntr_t<T, void>(mValue op); \
	}

	DEFINE_C2_CNTR_BINARY_OP(C2_ALLOW_OVERFLOW, +, +=)
	DEFINE_C2_CNTR_BINARY_OP(C2_ALLOW_OVERFLOW, -, -=)
	DEFINE_C2_CNTR_BINARY_OP(C2_ALLOW_OVERFLOW, , =)

	DEFINE_C2_CNTR_UNARY_OP(C2_ALLOW_OVERFLOW, -)
	DEFINE_C2_CNTR_UNARY_OP(C2_ALLOW_OVERFLOW, +)

	DEFINE_C2_CNTR_CREMENT_OP(C2_ALLOW_OVERFLOW, ++)
	DEFINE_C2_CNTR_CREMENT_OP(C2_ALLOW_OVERFLOW, --)

	template<typename U, typename E=typename std::enable_if<std::is_unsigned<U>::value>::type>
	C2_ALLOW_OVERFLOW
	inline constexpr c2_cntr_t<T> operator<<(const U &value) const {
	return c2_cntr_t<T>(mValue << value);
	}

	template<typename U, typename E=typename std::enable_if<std::is_unsigned<U>::value>::type>
	C2_ALLOW_OVERFLOW
	inline c2_cntr_t<T> &operator<<=(const U &value) {
	mValue <<= value;
	return *this;
	}

	/**
	* Comparison operators
	*/
	C2_ALLOW_OVERFLOW
	inline constexpr bool operator<=(const c2_cntr_t<T> &other) const {
	return T(other.mValue - mValue) < HALF_RANGE;
	}

	C2_ALLOW_OVERFLOW
	inline constexpr bool operator>=(const c2_cntr_t<T> &other) const {
	return T(mValue - other.mValue) < HALF_RANGE;
	}

	inline constexpr bool operator==(const c2_cntr_t<T> &other) const {
	return mValue == other.mValue;
	}

	inline constexpr bool operator!=(const c2_cntr_t<T> &other) const {
	return !(*this == other);
	}

	inline constexpr bool operator<(const c2_cntr_t<T> &other) const {
	return this <= other && this != other;
	}

	inline constexpr bool operator>(const c2_cntr_t<T> &other) const {
	return this >= other && this != other;
	}
	};

	template<typename U, typename T, typename E=typename std::enable_if<std::is_integral<U>::value>::type>
	inline constexpr c2_cntr_t<T> operator+(const U &a, const c2_cntr_t<T> &b) {
	return b + a;
	}

	template<typename U, typename T, typename E=typename std::enable_if<std::is_integral<U>::value>::type>
	inline constexpr c2_cntr_t<T> operator-(const U &a, const c2_cntr_t<T> &b) {
	return c2_cntr_t<T>(a) - b;
	}

	template<typename U, typename T, typename E=typename std::enable_if<std::is_integral<U>::value>::type>
	inline constexpr c2_cntr_t<T> operator*(const U &a, const c2_cntr_t<T> &b) {
	return b * a;
	}

	typedef c2_cntr_t<uint32_t> c2_cntr32_t; /** 32-bit counter type */
	typedef c2_cntr_t<uint64_t> c2_cntr64_t; /** 64-bit counter type */

	/// \cond INTERNAL

	/// \defgroup utils_internal
	/// @{

	template<typename... T> struct c2_types;

	/** specialization for a single type */
	template<typename T>
	struct c2_types<T> {
	typedef typename std::decay<T>::type wide_type;
	typedef wide_type narrow_type;
	typedef wide_type min_type; // type for min(T...)
	};

	/** specialization for two types */
	template<typename T, typename U>
	struct c2_types<T, U> {
	static_assert(std::is_floating_point<T>::value == std::is_floating_point<U>::value,
	"mixing floating point and non-floating point types is disallowed");
	static_assert(std::is_signed<T>::value == std::is_signed<U>::value,
	"mixing signed and unsigned types is disallowed");

	typedef typename std::decay<
	decltype(true ? std::declval<T>() : std::declval<U>())>::type wide_type;
	typedef typename std::decay<
	typename std::conditional<sizeof(T) < sizeof(U), T, U>::type>::type narrow_type;
	typedef typename std::conditional<
	std::is_signed<T>::value, wide_type, narrow_type>::type min_type;
	};

	/// @}

	/// \endcond

	/**
	* Type support utility class. Only supports similar classes, such as:
	* - all floating point
	* - all unsigned/all signed
	* - all pointer
	*/
	template<typename T, typename U, typename... V>
	struct c2_types<T, U, V...> {
	/** Common type that accommodates all template parameter types. */
	typedef typename c2_types<typename c2_types<T, U>::wide_type, V...>::wide_type wide_type;
	/** Narrowest type of the template parameter types. */
	typedef typename c2_types<typename c2_types<T, U>::narrow_type, V...>::narrow_type narrow_type;
	/** Type that accommodates the minimum value for any input for the template parameter types. */
	typedef typename c2_types<typename c2_types<T, U>::min_type, V...>::min_type min_type;
	};

	/**
	* \ingroup utils_internal
	* specialization for two values */
	template<typename T, typename U>
	inline constexpr typename c2_types<T, U>::wide_type c2_max(const T a, const U b) {
	typedef typename c2_types<T, U>::wide_type wide_type;
	return ({ wide_type a_(a), b_(b); a_ > b_ ? a_ : b_; });
	}

	/**
	* Finds the maximum value of a list of "similarly typed" values.
	*
	* This is an extension to std::max where the types do not have to be identical, and the smallest
	* resulting type is used that accommodates the argument types.
	*
	* \note Value types must be similar, e.g. all floating point, all pointers, all signed, or all
	* unsigned.
	*
	* @return the largest of the input arguments.
	*/
	template<typename T, typename U, typename... V>
	constexpr typename c2_types<T, U, V...>::wide_type c2_max(const T a, const U b, const V ... c) {
	typedef typename c2_types<T, U, V...>::wide_type wide_type;
	return ({ wide_type a_(a), b_(c2_max(b, c...)); a_ > b_ ? a_ : b_; });
	}

	/**
	* \ingroup utils_internal
	* specialization for two values */
	template<typename T, typename U>
	inline constexpr typename c2_types<T, U>::min_type c2_min(const T a, const U b) {
	typedef typename c2_types<T, U>::wide_type wide_type;
	return ({
	wide_type a_(a), b_(b);
	static_cast<typename c2_types<T, U>::min_type>(a_ < b_ ? a_ : b_);
	});
	}

	/**
	* Finds the minimum value of a list of "similarly typed" values.
	*
	* This is an extension to std::min where the types do not have to be identical, and the smallest
	* resulting type is used that accommodates the argument types.
	*
	* \note Value types must be similar, e.g. all floating point, all pointers, all signed, or all
	* unsigned.
	*
	* @return the smallest of the input arguments.
	*/
	template<typename T, typename U, typename... V>
	constexpr typename c2_types<T, U, V...>::min_type c2_min(const T a, const U b, const V ... c) {
	typedef typename c2_types<U, V...>::min_type rest_type;
	typedef typename c2_types<T, rest_type>::wide_type wide_type;
	return ({
	wide_type a_(a), b_(c2_min(b, c...));
	static_cast<typename c2_types<T, rest_type>::min_type>(a_ < b_ ? a_ : b_);
	});
	}

	/**
	* \ingroup utils_internal
	*/
	template<typename T, typename U, typename V>
	inline constexpr typename c2_types<T, V>::wide_type c2_clamp(const T a, const U b, const V c) {
	typedef typename c2_types<T, U, V>::wide_type wide_type;
	return ({
	wide_type a_(a), b_(b), c_(c);
	static_cast<typename c2_types<T, V>::wide_type>(b_ < a_ ? a_ : b_ > c_ ? c_ : b_);
	});
	}

	/// @}

	#include <functional>
	template<typename T>
	struct std::less<::c2_cntr_t<T>> {
	constexpr bool operator()(const ::c2_cntr_t<T> &lh, const ::c2_cntr_t<T> &rh) const {
	return lh.peeku() < rh.peeku();
	}
	};
	template<typename T>
	struct std::less_equal<::c2_cntr_t<T>> {
	constexpr bool operator()(const ::c2_cntr_t<T> &lh, const ::c2_cntr_t<T> &rh) const {
	return lh.peeku() <= rh.peeku();
	}
	};
	template<typename T>
	struct std::greater<::c2_cntr_t<T>> {
	constexpr bool operator()(const ::c2_cntr_t<T> &lh, const ::c2_cntr_t<T> &rh) const {
	return lh.peeku() > rh.peeku();
	}
	};
	template<typename T>
	struct std::greater_equal<::c2_cntr_t<T>> {
	constexpr bool operator()(const ::c2_cntr_t<T> &lh, const ::c2_cntr_t<T> &rh) const {
	return lh.peeku() >= rh.peeku();
	}
	};

	#endif // C2_H_