mdbx.h++

/// \file mdbx.h++
/// \brief The libmdbx C++ API header file.
///
/// \author Copyright (c) 2020-2023, Leonid Yuriev <leo@yuriev.ru>.
/// \copyright SPDX-License-Identifier: Apache-2.0
///
/// Tested with:
///  - Elbrus LCC >= 1.23 (http://www.mcst.ru/lcc);
///  - GNU C++ >= 4.8;
///  - clang >= 3.9;
///  - MSVC >= 14.0 (Visual Studio 2015),
///    but 19.2x could hang due optimizer bug;
///  - AppleClang, but without C++20 concepts.
///

///
/// The origin has been migrated to https://gitflic.ru/project/erthink/libmdbx
/// since on 2022-04-15 the Github administration, without any warning nor
/// explanation, deleted libmdbx along with a lot of other projects,
/// simultaneously blocking access for many developers.
/// For the same reason Github is blacklisted forever.
///

#pragma once

/* Workaround for modern libstdc++ with CLANG < 4.x */
#if defined(__SIZEOF_INT128__) && !defined(__GLIBCXX_TYPE_INT_N_0) &&          \
    defined(__clang__) && __clang_major__ < 4
#define __GLIBCXX_BITSIZE_INT_N_0 128
#define __GLIBCXX_TYPE_INT_N_0 __int128
#endif /* Workaround for modern libstdc++ with CLANG < 4.x */

#if !defined(__cplusplus) || __cplusplus < 201103L
#if !defined(_MSC_VER) || _MSC_VER < 1900
#error "C++11 compiler or better is required"
#elif _MSC_VER >= 1910
#error                                                                         \
    "Please add `/Zc:__cplusplus` to MSVC compiler options to enforce it conform ISO C++"
#endif /* MSVC is mad and don't define __cplusplus properly */
#endif /* __cplusplus < 201103L */

#if (defined(_WIN32) || defined(_WIN64)) && MDBX_WITHOUT_MSVC_CRT
#error                                                                         \
    "CRT is required for C++ API, the MDBX_WITHOUT_MSVC_CRT option must be disabled"
#endif /* Windows */

#ifndef __has_include
#define __has_include(header) (0)
#endif /* __has_include */

#if __has_include(<version>)
#include <version>
#endif /* <version> */

/* Disable min/max macros from C' headers */
#ifndef NOMINMAX
#define NOMINMAX
#endif

#include <algorithm>   // for std::min/max
#include <cassert>     // for assert()
#include <climits>     // for CHAR_BIT
#include <cstring>     // for std::strlen, str:memcmp
#include <exception>   // for std::exception_ptr
#include <ostream>     // for std::ostream
#include <sstream>     // for std::ostringstream
#include <stdexcept>   // for std::invalid_argument
#include <string>      // for std::string
#include <type_traits> // for std::is_pod<>, etc.
#include <utility>     // for std::make_pair
#include <vector>      // for std::vector<> as template args

#if defined(__cpp_lib_memory_resource) && __cpp_lib_memory_resource >= 201603L
#include <memory_resource>
#endif

#if defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L
#include <string_view>
#endif

#if defined(__cpp_lib_filesystem) && __cpp_lib_filesystem >= 201703L
#include <filesystem>
#elif __has_include(<experimental/filesystem>)
#include <experimental/filesystem>
#endif

#include "mdbx.h"

#if (defined(__cpp_lib_bit_cast) && __cpp_lib_bit_cast >= 201806L) ||          \
    (defined(__cpp_lib_endian) && __cpp_lib_endian >= 201907L) ||              \
    (defined(__cpp_lib_bitops) && __cpp_lib_bitops >= 201907L) ||              \
    (defined(__cpp_lib_int_pow2) && __cpp_lib_int_pow2 >= 202002L)
#include <bit>
#elif !(defined(__BYTE_ORDER__) && defined(__ORDER_LITTLE_ENDIAN__) &&         \
        defined(__ORDER_BIG_ENDIAN__))
#if defined(__BYTE_ORDER) && defined(__LITTLE_ENDIAN) && defined(__BIG_ENDIAN)
#define __ORDER_LITTLE_ENDIAN__ __LITTLE_ENDIAN
#define __ORDER_BIG_ENDIAN__ __BIG_ENDIAN
#define __BYTE_ORDER__ __BYTE_ORDER
#elif defined(_BYTE_ORDER) && defined(_LITTLE_ENDIAN) && defined(_BIG_ENDIAN)
#define __ORDER_LITTLE_ENDIAN__ _LITTLE_ENDIAN
#define __ORDER_BIG_ENDIAN__ _BIG_ENDIAN
#define __BYTE_ORDER__ _BYTE_ORDER
#else
#define __ORDER_LITTLE_ENDIAN__ 1234
#define __ORDER_BIG_ENDIAN__ 4321
#if defined(__LITTLE_ENDIAN__) ||                                              \
    (defined(_LITTLE_ENDIAN) && !defined(_BIG_ENDIAN)) ||                      \
    defined(__ARMEL__) || defined(__THUMBEL__) || defined(__AARCH64EL__) ||    \
    defined(__MIPSEL__) || defined(_MIPSEL) || defined(__MIPSEL) ||            \
    defined(_M_ARM) || defined(_M_ARM64) || defined(__e2k__) ||                \
    defined(__elbrus_4c__) || defined(__elbrus_8c__) || defined(__bfin__) ||   \
    defined(__BFIN__) || defined(__ia64__) || defined(_IA64) ||                \
    defined(__IA64__) || defined(__ia64) || defined(_M_IA64) ||                \
    defined(__itanium__) || defined(__ia32__) || defined(__CYGWIN__) ||        \
    defined(_WIN64) || defined(_WIN32) || defined(__TOS_WIN__) ||              \
    defined(__WINDOWS__)
#define __BYTE_ORDER__ __ORDER_LITTLE_ENDIAN__
#elif defined(__BIG_ENDIAN__) ||                                               \
    (defined(_BIG_ENDIAN) && !defined(_LITTLE_ENDIAN)) ||                      \
    defined(__ARMEB__) || defined(__THUMBEB__) || defined(__AARCH64EB__) ||    \
    defined(__MIPSEB__) || defined(_MIPSEB) || defined(__MIPSEB) ||            \
    defined(__m68k__) || defined(M68000) || defined(__hppa__) ||               \
    defined(__hppa) || defined(__HPPA__) || defined(__sparc__) ||              \
    defined(__sparc) || defined(__370__) || defined(__THW_370__) ||            \
    defined(__s390__) || defined(__s390x__) || defined(__SYSC_ZARCH__)
#define __BYTE_ORDER__ __ORDER_BIG_ENDIAN__
#endif
#endif
#endif /* Byte Order */

/** Workaround for old compilers without properly support for `C++17 constexpr`.
 */
#if defined(DOXYGEN)
#define MDBX_CXX17_CONSTEXPR constexpr
#elif defined(__cpp_constexpr) && __cpp_constexpr >= 201603L &&                \
    ((defined(_MSC_VER) && _MSC_VER >= 1915) ||                                \
     (defined(__clang__) && __clang_major__ > 5) ||                            \
     (defined(__GNUC__) && __GNUC__ > 7) ||                                    \
     (!defined(__GNUC__) && !defined(__clang__) && !defined(_MSC_VER)))
#define MDBX_CXX17_CONSTEXPR constexpr
#else
#define MDBX_CXX17_CONSTEXPR inline
#endif /* MDBX_CXX17_CONSTEXPR */

/** Workaround for old compilers without properly support for C++20 `constexpr`.
 */
#if defined(DOXYGEN)
#define MDBX_CXX20_CONSTEXPR constexpr
#elif defined(__cpp_lib_is_constant_evaluated) &&                              \
    __cpp_lib_is_constant_evaluated >= 201811L &&                              \
    defined(__cpp_lib_constexpr_string) &&                                     \
    __cpp_lib_constexpr_string >= 201907L
#define MDBX_CXX20_CONSTEXPR constexpr
#else
#define MDBX_CXX20_CONSTEXPR inline
#endif /* MDBX_CXX20_CONSTEXPR */

/** Workaround for old compilers without support assertion inside `constexpr`
 * functions. */
#if defined(CONSTEXPR_ASSERT)
#define MDBX_CONSTEXPR_ASSERT(expr) CONSTEXPR_ASSERT(expr)
#elif defined NDEBUG
#define MDBX_CONSTEXPR_ASSERT(expr) void(0)
#else
#define MDBX_CONSTEXPR_ASSERT(expr)                                            \
  ((expr) ? void(0) : [] { assert(!#expr); }())
#endif /* MDBX_CONSTEXPR_ASSERT */

#ifndef MDBX_LIKELY
#if defined(DOXYGEN) ||                                                        \
    (defined(__GNUC__) || __has_builtin(__builtin_expect)) &&                  \
        !defined(__COVERITY__)
#define MDBX_LIKELY(cond) __builtin_expect(!!(cond), 1)
#else
#define MDBX_LIKELY(x) (x)
#endif
#endif /* MDBX_LIKELY */

#ifndef MDBX_UNLIKELY
#if defined(DOXYGEN) ||                                                        \
    (defined(__GNUC__) || __has_builtin(__builtin_expect)) &&                  \
        !defined(__COVERITY__)
#define MDBX_UNLIKELY(cond) __builtin_expect(!!(cond), 0)
#else
#define MDBX_UNLIKELY(x) (x)
#endif
#endif /* MDBX_UNLIKELY */

/** Workaround for old compilers without properly support for C++20 `if
 * constexpr`. */
#if defined(DOXYGEN)
#define MDBX_IF_CONSTEXPR constexpr
#elif defined(__cpp_if_constexpr) && __cpp_if_constexpr >= 201606L
#define MDBX_IF_CONSTEXPR constexpr
#else
#define MDBX_IF_CONSTEXPR
#endif /* MDBX_IF_CONSTEXPR */

#if defined(DOXYGEN) ||                                                        \
    (__has_cpp_attribute(fallthrough) &&                                       \
     (!defined(__clang__) || __clang__ > 4)) ||                                \
    __cplusplus >= 201703L
#define MDBX_CXX17_FALLTHROUGH [[fallthrough]]
#else
#define MDBX_CXX17_FALLTHROUGH
#endif /* MDBX_CXX17_FALLTHROUGH */

#if defined(DOXYGEN) || (__has_cpp_attribute(likely) >= 201803L &&             \
                         (!defined(__GNUC__) || __GNUC__ > 9))
#define MDBX_CXX20_LIKELY [[likely]]
#else
#define MDBX_CXX20_LIKELY
#endif /* MDBX_CXX20_LIKELY */

#ifndef MDBX_CXX20_UNLIKELY
#if defined(DOXYGEN) || (__has_cpp_attribute(unlikely) >= 201803L &&           \
                         (!defined(__GNUC__) || __GNUC__ > 9))
#define MDBX_CXX20_UNLIKELY [[unlikely]]
#else
#define MDBX_CXX20_UNLIKELY
#endif
#endif /* MDBX_CXX20_UNLIKELY */

#ifndef MDBX_HAVE_CXX20_CONCEPTS
#if defined(__cpp_lib_concepts) && __cpp_lib_concepts >= 202002L
#include <concepts>
#define MDBX_HAVE_CXX20_CONCEPTS 1
#elif defined(DOXYGEN)
#define MDBX_HAVE_CXX20_CONCEPTS 1
#else
#define MDBX_HAVE_CXX20_CONCEPTS 0
#endif /* <concepts> */
#endif /* MDBX_HAVE_CXX20_CONCEPTS */

#ifndef MDBX_CXX20_CONCEPT
#if MDBX_HAVE_CXX20_CONCEPTS || defined(DOXYGEN)
#define MDBX_CXX20_CONCEPT(CONCEPT, NAME) CONCEPT NAME
#else
#define MDBX_CXX20_CONCEPT(CONCEPT, NAME) typename NAME
#endif
#endif /* MDBX_CXX20_CONCEPT */

#ifndef MDBX_ASSERT_CXX20_CONCEPT_SATISFIED
#if MDBX_HAVE_CXX20_CONCEPTS || defined(DOXYGEN)
#define MDBX_ASSERT_CXX20_CONCEPT_SATISFIED(CONCEPT, TYPE)                     \
  static_assert(CONCEPT<TYPE>)
#else
#define MDBX_ASSERT_CXX20_CONCEPT_SATISFIED(CONCEPT, NAME)                     \
  static_assert(true, MDBX_STRINGIFY(CONCEPT) "<" MDBX_STRINGIFY(TYPE) ">")
#endif
#endif /* MDBX_ASSERT_CXX20_CONCEPT_SATISFIED */

#ifdef _MSC_VER
#pragma warning(push, 4)
#pragma warning(disable : 4127) /* conditional expression is constant */
#pragma warning(disable : 4251) /* 'std::FOO' needs to have dll-interface to   \
                                   be used by clients of 'mdbx::BAR' */
#pragma warning(disable : 4275) /* non dll-interface 'std::FOO' used as        \
                                   base for dll-interface 'mdbx::BAR' */
/* MSVC is mad and can generate this warning for its own intermediate
 * automatically generated code, which becomes unreachable after some kinds of
 * optimization (copy elision, etc). */
#pragma warning(disable : 4702) /* unreachable code */
#endif                          /* _MSC_VER (warnings) */

#if defined(__LCC__) && __LCC__ >= 126
#pragma diagnostic push
#if __LCC__ < 127
#pragma diag_suppress 3058 /* workaround: call to is_constant_evaluated()      \
                              appearing in a constant expression `true` */
#pragma diag_suppress 3060 /* workaround: call to is_constant_evaluated()      \
                              appearing in a constant expression `false` */
#endif
#endif /* E2K LCC (warnings) */

//------------------------------------------------------------------------------
/// \brief The libmdbx C++ API namespace
/// \ingroup cxx_api
namespace mdbx {

/// \defgroup cxx_api C++ API
/// @{

// Functions whose signature depends on the `mdbx::byte` type
// must be strictly defined as inline!
#if defined(DOXYGEN) || (defined(__cpp_char8_t) && __cpp_char8_t >= 201811)
// To enable all kinds of an compiler optimizations we use a byte-like type
// that don't presumes aliases for pointers as does the `char` type and its
// derivatives/typedefs.
// Please see https://libmdbx.dqdkfa.ru/dead-github/issues/263
// for reasoning of the use of `char8_t` type and switching to `__restrict__`.
using byte = char8_t;
#else
// Avoid `std::byte` since it doesn't add features but inconvenient
// restrictions.
using byte = unsigned char;
#endif /* __cpp_char8_t >= 201811*/

#if defined(__cpp_lib_endian) && __cpp_lib_endian >= 201907L
using endian = ::std::endian;
#elif defined(__BYTE_ORDER__) && defined(__ORDER_LITTLE_ENDIAN__) &&           \
    defined(__ORDER_BIG_ENDIAN__)
enum class endian {
  little = __ORDER_LITTLE_ENDIAN__,
  big = __ORDER_BIG_ENDIAN__,
  native = __BYTE_ORDER__
};
#else
#error                                                                         \
    "Please use a C++ compiler provides byte order information or C++20 support"
#endif /* Byte Order enum */

/// \copydoc MDBX_version_info
using version_info = ::MDBX_version_info;
/// \brief Returns libmdbx version information.
MDBX_CXX11_CONSTEXPR const version_info &get_version() noexcept;
/// \copydoc MDBX_build_info
using build_info = ::MDBX_build_info;
/// \brief Returns libmdbx build information.
MDBX_CXX11_CONSTEXPR const build_info &get_build() noexcept;

/// \brief constexpr-enabled strlen().
static MDBX_CXX17_CONSTEXPR size_t strlen(const char *c_str) noexcept;

/// \brief constexpr-enabled memcpy().
static MDBX_CXX20_CONSTEXPR void *memcpy(void *dest, const void *src,
                                         size_t bytes) noexcept;
/// \brief constexpr-enabled memcmp().
static MDBX_CXX20_CONSTEXPR int memcmp(const void *a, const void *b,
                                       size_t bytes) noexcept;

/// \brief Legacy default allocator
/// but it is recommended to use \ref polymorphic_allocator.
using legacy_allocator = ::std::string::allocator_type;

struct slice;
struct default_capacity_policy;
template <class ALLOCATOR = legacy_allocator,
          class CAPACITY_POLICY = default_capacity_policy>
class buffer;
class env;
class env_managed;
class txn;
class txn_managed;
class cursor;
class cursor_managed;

#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_memory_resource) &&                                     \
     __cpp_lib_memory_resource >= 201603L && _GLIBCXX_USE_CXX11_ABI)
/// \brief Default polymorphic allocator for modern code.
using polymorphic_allocator = ::std::pmr::string::allocator_type;
#endif /* __cpp_lib_memory_resource >= 201603L */

/// \brief Default singe-byte string.
template <class ALLOCATOR = legacy_allocator>
using string = ::std::basic_string<char, ::std::char_traits<char>, ALLOCATOR>;

using filehandle = ::mdbx_filehandle_t;
#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_filesystem) && __cpp_lib_filesystem >= 201703L &&       \
     (!defined(__MAC_OS_X_VERSION_MIN_REQUIRED) ||                             \
      __MAC_OS_X_VERSION_MIN_REQUIRED >= 101500) &&                            \
     (!defined(__IPHONE_OS_VERSION_MIN_REQUIRED) ||                            \
      __IPHONE_OS_VERSION_MIN_REQUIRED >= 130100))
namespace filesystem = ::std::filesystem;
/// \brief Defined if `mdbx::filesystem::path` is available.
/// \details If defined, it is always `mdbx::filesystem::path`,
/// which in turn can be refs to `std::filesystem::path`
/// or `std::experimental::filesystem::path`.
/// Nonetheless `MDBX_STD_FILESYSTEM_PATH` not defined if the `::mdbx::path`
/// is fallbacked to c `std::string` or `std::wstring`.
#define MDBX_STD_FILESYSTEM_PATH ::mdbx::filesystem::path
#elif defined(__cpp_lib_experimental_filesystem) &&                            \
    __cpp_lib_experimental_filesystem >= 201406L
namespace filesystem = ::std::experimental::filesystem;
#define MDBX_STD_FILESYSTEM_PATH ::mdbx::filesystem::path
#endif /* MDBX_STD_FILESYSTEM_PATH */

#ifdef MDBX_STD_FILESYSTEM_PATH
using path = MDBX_STD_FILESYSTEM_PATH;
#elif defined(_WIN32) || defined(_WIN64)
using path = ::std::wstring;
#else
using path = ::std::string;
#endif /* mdbx::path */

/// \defgroup cxx_exceptions exceptions and errors
/// @{

/// \brief Transfers C++ exceptions thru C callbacks.
/// \details Implements saving exceptions before returning
/// from an C++'s environment to the intermediate C code and re-throwing after
/// returning from C to the C++'s environment.
class LIBMDBX_API_TYPE exception_thunk {
  ::std::exception_ptr captured_;

public:
  exception_thunk() noexcept = default;
  exception_thunk(const exception_thunk &) = delete;
  exception_thunk(exception_thunk &&) = delete;
  exception_thunk &operator=(const exception_thunk &) = delete;
  exception_thunk &operator=(exception_thunk &&) = delete;
  inline bool is_clean() const noexcept;
  inline void capture() noexcept;
  inline void rethrow_captured() const;
};

/// \brief Implements error information and throwing corresponding exceptions.
class LIBMDBX_API_TYPE error {
  MDBX_error_t code_;
  inline error &operator=(MDBX_error_t error_code) noexcept;

public:
  MDBX_CXX11_CONSTEXPR error(MDBX_error_t error_code) noexcept;
  error(const error &) = default;
  error(error &&) = default;
  error &operator=(const error &) = default;
  error &operator=(error &&) = default;

  MDBX_CXX11_CONSTEXPR friend bool operator==(const error &a,
                                              const error &b) noexcept;
  MDBX_CXX11_CONSTEXPR friend bool operator!=(const error &a,
                                              const error &b) noexcept;

  MDBX_CXX11_CONSTEXPR bool is_success() const noexcept;
  MDBX_CXX11_CONSTEXPR bool is_result_true() const noexcept;
  MDBX_CXX11_CONSTEXPR bool is_result_false() const noexcept;
  MDBX_CXX11_CONSTEXPR bool is_failure() const noexcept;

  /// \brief Returns error code.
  MDBX_CXX11_CONSTEXPR MDBX_error_t code() const noexcept;

  /// \brief Returns message for MDBX's errors only and "SYSTEM" for others.
  const char *what() const noexcept;

  /// \brief Returns message for any errors.
  ::std::string message() const;

  /// \brief Returns true for MDBX's errors.
  MDBX_CXX11_CONSTEXPR bool is_mdbx_error() const noexcept;
  /// \brief Panics on unrecoverable errors inside destructors etc.
  [[noreturn]] void panic(const char *context_where_when,
                          const char *func_who_what) const noexcept;
  [[noreturn]] void throw_exception() const;
  [[noreturn]] static inline void throw_exception(int error_code);
  inline void throw_on_failure() const;
  inline void success_or_throw() const;
  inline void success_or_throw(const exception_thunk &) const;
  inline void panic_on_failure(const char *context_where,
                               const char *func_who) const noexcept;
  inline void success_or_panic(const char *context_where,
                               const char *func_who) const noexcept;
  static inline void throw_on_nullptr(const void *ptr, MDBX_error_t error_code);
  static inline void success_or_throw(MDBX_error_t error_code);
  static void success_or_throw(int error_code) {
    success_or_throw(static_cast<MDBX_error_t>(error_code));
  }
  static inline void throw_on_failure(int error_code);
  static inline bool boolean_or_throw(int error_code);
  static inline void success_or_throw(int error_code, const exception_thunk &);
  static inline void panic_on_failure(int error_code, const char *context_where,
                                      const char *func_who) noexcept;
  static inline void success_or_panic(int error_code, const char *context_where,
                                      const char *func_who) noexcept;
};

/// \brief Base class for all libmdbx's exceptions that are corresponds
/// to libmdbx errors.
///
/// \see MDBX_error_t
class LIBMDBX_API_TYPE exception : public ::std::runtime_error {
  using base = ::std::runtime_error;
  ::mdbx::error error_;

public:
  exception(const ::mdbx::error &) noexcept;
  exception(const exception &) = default;
  exception(exception &&) = default;
  exception &operator=(const exception &) = default;
  exception &operator=(exception &&) = default;
  virtual ~exception() noexcept;
  const ::mdbx::error error() const noexcept { return error_; }
};

/// \brief Fatal exception that lead termination anyway
/// in dangerous unrecoverable cases.
class LIBMDBX_API_TYPE fatal : public exception {
  using base = exception;

public:
  fatal(const ::mdbx::error &) noexcept;
  fatal(const exception &src) noexcept : fatal(src.error()) {}
  fatal(exception &&src) noexcept : fatal(src.error()) {}
  fatal(const fatal &src) noexcept : fatal(src.error()) {}
  fatal(fatal &&src) noexcept : fatal(src.error()) {}
  fatal &operator=(fatal &&) = default;
  fatal &operator=(const fatal &) = default;
  virtual ~fatal() noexcept;
};

#define MDBX_DECLARE_EXCEPTION(NAME)                                           \
  struct LIBMDBX_API_TYPE NAME : public exception {                            \
    NAME(const ::mdbx::error &);                                               \
    virtual ~NAME() noexcept;                                                  \
  }
MDBX_DECLARE_EXCEPTION(bad_map_id);
MDBX_DECLARE_EXCEPTION(bad_transaction);
MDBX_DECLARE_EXCEPTION(bad_value_size);
MDBX_DECLARE_EXCEPTION(db_corrupted);
MDBX_DECLARE_EXCEPTION(db_full);
MDBX_DECLARE_EXCEPTION(db_invalid);
MDBX_DECLARE_EXCEPTION(db_too_large);
MDBX_DECLARE_EXCEPTION(db_unable_extend);
MDBX_DECLARE_EXCEPTION(db_version_mismatch);
MDBX_DECLARE_EXCEPTION(db_wanna_write_for_recovery);
MDBX_DECLARE_EXCEPTION(incompatible_operation);
MDBX_DECLARE_EXCEPTION(internal_page_full);
MDBX_DECLARE_EXCEPTION(internal_problem);
MDBX_DECLARE_EXCEPTION(key_exists);
MDBX_DECLARE_EXCEPTION(key_mismatch);
MDBX_DECLARE_EXCEPTION(max_maps_reached);
MDBX_DECLARE_EXCEPTION(max_readers_reached);
MDBX_DECLARE_EXCEPTION(multivalue);
MDBX_DECLARE_EXCEPTION(no_data);
MDBX_DECLARE_EXCEPTION(not_found);
MDBX_DECLARE_EXCEPTION(operation_not_permitted);
MDBX_DECLARE_EXCEPTION(permission_denied_or_not_writeable);
MDBX_DECLARE_EXCEPTION(reader_slot_busy);
MDBX_DECLARE_EXCEPTION(remote_media);
MDBX_DECLARE_EXCEPTION(something_busy);
MDBX_DECLARE_EXCEPTION(thread_mismatch);
MDBX_DECLARE_EXCEPTION(transaction_full);
MDBX_DECLARE_EXCEPTION(transaction_overlapping);
#undef MDBX_DECLARE_EXCEPTION

[[noreturn]] LIBMDBX_API void throw_too_small_target_buffer();
[[noreturn]] LIBMDBX_API void throw_max_length_exceeded();
[[noreturn]] LIBMDBX_API void throw_out_range();
[[noreturn]] LIBMDBX_API void throw_allocators_mismatch();
static MDBX_CXX14_CONSTEXPR size_t check_length(size_t bytes);
static MDBX_CXX14_CONSTEXPR size_t check_length(size_t headroom,
                                                size_t payload);
static MDBX_CXX14_CONSTEXPR size_t check_length(size_t headroom, size_t payload,
                                                size_t tailroom);

/// end of cxx_exceptions @}

//------------------------------------------------------------------------------

/// \defgroup cxx_data slices and buffers
/// @{

#if MDBX_HAVE_CXX20_CONCEPTS || defined(DOXYGEN)

/** \concept MutableByteProducer
 *  \interface MutableByteProducer
 *  \brief MutableByteProducer C++20 concept */
template <typename T>
concept MutableByteProducer = requires(T a, char array[42]) {
  { a.is_empty() } -> std::same_as<bool>;
  { a.envisage_result_length() } -> std::same_as<size_t>;
  { a.write_bytes(&array[0], size_t(42)) } -> std::same_as<char *>;
};

/** \concept ImmutableByteProducer
 *  \interface ImmutableByteProducer
 *  \brief ImmutableByteProducer C++20 concept */
template <typename T>
concept ImmutableByteProducer = requires(const T &a, char array[42]) {
  { a.is_empty() } -> std::same_as<bool>;
  { a.envisage_result_length() } -> std::same_as<size_t>;
  { a.write_bytes(&array[0], size_t(42)) } -> std::same_as<char *>;
};

/** \concept SliceTranscoder
 *  \interface SliceTranscoder
 *  \brief SliceTranscoder C++20 concept */
template <typename T>
concept SliceTranscoder = ImmutableByteProducer<T> &&
    requires(const slice &source, const T &a) {
  T(source);
  { a.is_erroneous() } -> std::same_as<bool>;
};

#endif /* MDBX_HAVE_CXX20_CONCEPTS */

template <class ALLOCATOR = legacy_allocator,
          typename CAPACITY_POLICY = default_capacity_policy,
          MDBX_CXX20_CONCEPT(MutableByteProducer, PRODUCER)>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
make_buffer(PRODUCER &producer, const ALLOCATOR &allocator = ALLOCATOR());

template <class ALLOCATOR = legacy_allocator,
          typename CAPACITY_POLICY = default_capacity_policy,
          MDBX_CXX20_CONCEPT(ImmutableByteProducer, PRODUCER)>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
make_buffer(const PRODUCER &producer, const ALLOCATOR &allocator = ALLOCATOR());

template <class ALLOCATOR = legacy_allocator,
          MDBX_CXX20_CONCEPT(MutableByteProducer, PRODUCER)>
inline string<ALLOCATOR> make_string(PRODUCER &producer,
                                     const ALLOCATOR &allocator = ALLOCATOR());

template <class ALLOCATOR = legacy_allocator,
          MDBX_CXX20_CONCEPT(ImmutableByteProducer, PRODUCER)>
inline string<ALLOCATOR> make_string(const PRODUCER &producer,
                                     const ALLOCATOR &allocator = ALLOCATOR());

/// \brief References a data located outside the slice.
///
/// The `slice` is similar in many ways to `std::string_view`, but it
/// implements specific capabilities and manipulates with bytes but
/// not a characters.
///
/// \copydetails MDBX_val
struct LIBMDBX_API_TYPE slice : public ::MDBX_val {
  /// \todo slice& operator<<(slice&, ...) for reading
  /// \todo key-to-value (parse/unpack) functions
  /// \todo template<class X> key(X); for decoding keys while reading

  enum { max_length = MDBX_MAXDATASIZE };

  /// \brief Create an empty slice.
  MDBX_CXX11_CONSTEXPR slice() noexcept;

  /// \brief Create a slice that refers to [0,bytes-1] of memory bytes pointed
  /// by ptr.
  MDBX_CXX14_CONSTEXPR slice(const void *ptr, size_t bytes);

  /// \brief Create a slice that refers to [begin,end] of memory bytes.
  MDBX_CXX14_CONSTEXPR slice(const void *begin, const void *end);

  /// \brief Create a slice that refers to text[0,strlen(text)-1].
  template <size_t SIZE>
  MDBX_CXX14_CONSTEXPR slice(const char (&text)[SIZE]) : slice(text, SIZE - 1) {
    MDBX_CONSTEXPR_ASSERT(SIZE > 0 && text[SIZE - 1] == '\0');
  }
  /// \brief Create a slice that refers to c_str[0,strlen(c_str)-1].
  explicit MDBX_CXX17_CONSTEXPR slice(const char *c_str);

  /// \brief Create a slice that refers to the contents of "str".
  /// \note 'explicit' to avoid reference to the temporary std::string instance.
  template <class CHAR, class T, class A>
  explicit MDBX_CXX20_CONSTEXPR
  slice(const ::std::basic_string<CHAR, T, A> &str)
      : slice(str.data(), str.length() * sizeof(CHAR)) {}

  MDBX_CXX14_CONSTEXPR slice(const MDBX_val &src);
  MDBX_CXX11_CONSTEXPR slice(const slice &) noexcept = default;
  MDBX_CXX14_CONSTEXPR slice(MDBX_val &&src);
  MDBX_CXX14_CONSTEXPR slice(slice &&src) noexcept;

#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L)
  /// \brief Create a slice that refers to the same contents as "string_view"
  template <class CHAR, class T>
  MDBX_CXX14_CONSTEXPR slice(const ::std::basic_string_view<CHAR, T> &sv)
      : slice(sv.data(), sv.data() + sv.length()) {}

  template <class CHAR, class T>
  slice(::std::basic_string_view<CHAR, T> &&sv) : slice(sv) {
    sv = {};
  }
#endif /* __cpp_lib_string_view >= 201606L */

  template <size_t SIZE>
  static MDBX_CXX14_CONSTEXPR slice wrap(const char (&text)[SIZE]) {
    return slice(text);
  }

  template <typename POD>
  MDBX_CXX14_CONSTEXPR static slice wrap(const POD &pod) {
    static_assert(::std::is_standard_layout<POD>::value &&
                      !::std::is_pointer<POD>::value,
                  "Must be a standard layout type!");
    return slice(&pod, sizeof(pod));
  }

  inline slice &assign(const void *ptr, size_t bytes);
  inline slice &assign(const slice &src) noexcept;
  inline slice &assign(const ::MDBX_val &src);
  inline slice &assign(slice &&src) noexcept;
  inline slice &assign(::MDBX_val &&src);
  inline slice &assign(const void *begin, const void *end);
  template <class CHAR, class T, class ALLOCATOR>
  slice &assign(const ::std::basic_string<CHAR, T, ALLOCATOR> &str) {
    return assign(str.data(), str.length() * sizeof(CHAR));
  }
  inline slice &assign(const char *c_str);
#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L)
  template <class CHAR, class T>
  slice &assign(const ::std::basic_string_view<CHAR, T> &view) {
    return assign(view.begin(), view.end());
  }
  template <class CHAR, class T>
  slice &assign(::std::basic_string_view<CHAR, T> &&view) {
    assign(view);
    view = {};
    return *this;
  }
#endif /* __cpp_lib_string_view >= 201606L */

  slice &operator=(const slice &) noexcept = default;
  inline slice &operator=(slice &&src) noexcept;
  inline slice &operator=(::MDBX_val &&src);

#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L)
  template <class CHAR, class T>
  slice &operator=(const ::std::basic_string_view<CHAR, T> &view) {
    return assign(view);
  }

  template <class CHAR, class T>
  slice &operator=(::std::basic_string_view<CHAR, T> &&view) {
    return assign(view);
  }

  /// \brief Return a string_view that references the same data as this slice.
  template <class CHAR = char, class T = ::std::char_traits<CHAR>>
  MDBX_CXX11_CONSTEXPR ::std::basic_string_view<CHAR, T>
  string_view() const noexcept {
    static_assert(sizeof(CHAR) == 1, "Must be single byte characters");
    return ::std::basic_string_view<CHAR, T>(char_ptr(), length());
  }

  /// \brief Return a string_view that references the same data as this slice.
  template <class CHAR, class T>
  MDBX_CXX11_CONSTEXPR explicit
  operator ::std::basic_string_view<CHAR, T>() const noexcept {
    return this->string_view<CHAR, T>();
  }
#endif /* __cpp_lib_string_view >= 201606L */

  template <class CHAR = char, class T = ::std::char_traits<CHAR>,
            class ALLOCATOR = legacy_allocator>
  MDBX_CXX20_CONSTEXPR ::std::basic_string<CHAR, T, ALLOCATOR>
  as_string(const ALLOCATOR &allocator = ALLOCATOR()) const {
    static_assert(sizeof(CHAR) == 1, "Must be single byte characters");
    return ::std::basic_string<CHAR, T, ALLOCATOR>(char_ptr(), length(),
                                                   allocator);
  }

  template <class CHAR, class T, class ALLOCATOR>
  MDBX_CXX20_CONSTEXPR explicit
  operator ::std::basic_string<CHAR, T, ALLOCATOR>() const {
    return as_string<CHAR, T, ALLOCATOR>();
  }

  /// \brief Returns a string with a hexadecimal dump of the slice content.
  template <class ALLOCATOR = legacy_allocator>
  inline string<ALLOCATOR>
  as_hex_string(bool uppercase = false, unsigned wrap_width = 0,
                const ALLOCATOR &allocator = ALLOCATOR()) const;

  /// \brief Returns a string with a
  /// [Base58](https://en.wikipedia.org/wiki/Base58) dump of the slice content.
  template <class ALLOCATOR = legacy_allocator>
  inline string<ALLOCATOR>
  as_base58_string(unsigned wrap_width = 0,
                   const ALLOCATOR &allocator = ALLOCATOR()) const;

  /// \brief Returns a string with a
  /// [Base58](https://en.wikipedia.org/wiki/Base64) dump of the slice content.
  template <class ALLOCATOR = legacy_allocator>
  inline string<ALLOCATOR>
  as_base64_string(unsigned wrap_width = 0,
                   const ALLOCATOR &allocator = ALLOCATOR()) const;

  /// \brief Returns a buffer with a hexadecimal dump of the slice content.
  template <class ALLOCATOR = legacy_allocator,
            class CAPACITY_POLICY = default_capacity_policy>
  inline buffer<ALLOCATOR, CAPACITY_POLICY>
  encode_hex(bool uppercase = false, unsigned wrap_width = 0,
             const ALLOCATOR &allocator = ALLOCATOR()) const;

  /// \brief Returns a buffer with a
  /// [Base58](https://en.wikipedia.org/wiki/Base58) dump of the slice content.
  template <class ALLOCATOR = legacy_allocator,
            class CAPACITY_POLICY = default_capacity_policy>
  inline buffer<ALLOCATOR, CAPACITY_POLICY>
  encode_base58(unsigned wrap_width = 0,
                const ALLOCATOR &allocator = ALLOCATOR()) const;

  /// \brief Returns a buffer with a
  /// [Base64](https://en.wikipedia.org/wiki/Base64) dump of the slice content.
  template <class ALLOCATOR = legacy_allocator,
            class CAPACITY_POLICY = default_capacity_policy>
  inline buffer<ALLOCATOR, CAPACITY_POLICY>
  encode_base64(unsigned wrap_width = 0,
                const ALLOCATOR &allocator = ALLOCATOR()) const;

  /// \brief Decodes hexadecimal dump from the slice content to returned buffer.
  template <class ALLOCATOR = legacy_allocator,
            class CAPACITY_POLICY = default_capacity_policy>
  inline buffer<ALLOCATOR, CAPACITY_POLICY>
  hex_decode(bool ignore_spaces = false,
             const ALLOCATOR &allocator = ALLOCATOR()) const;

  /// \brief Decodes [Base58](https://en.wikipedia.org/wiki/Base58) dump
  /// from the slice content to returned buffer.
  template <class ALLOCATOR = legacy_allocator,
            class CAPACITY_POLICY = default_capacity_policy>
  inline buffer<ALLOCATOR, CAPACITY_POLICY>
  base58_decode(bool ignore_spaces = false,
                const ALLOCATOR &allocator = ALLOCATOR()) const;

  /// \brief Decodes [Base64](https://en.wikipedia.org/wiki/Base64) dump
  /// from the slice content to returned buffer.
  template <class ALLOCATOR = legacy_allocator,
            class CAPACITY_POLICY = default_capacity_policy>
  inline buffer<ALLOCATOR, CAPACITY_POLICY>
  base64_decode(bool ignore_spaces = false,
                const ALLOCATOR &allocator = ALLOCATOR()) const;

  /// \brief Checks whether the content of the slice is printable.
  /// \param [in] disable_utf8 By default if `disable_utf8` is `false` function
  /// checks that content bytes are printable ASCII-7 characters or a valid UTF8
  /// sequences. Otherwise, if if `disable_utf8` is `true` function checks that
  /// content bytes are printable extended 8-bit ASCII codes.
  MDBX_NOTHROW_PURE_FUNCTION bool
  is_printable(bool disable_utf8 = false) const noexcept;

  /// \brief Checks whether the content of the slice is a hexadecimal dump.
  /// \param [in] ignore_spaces If `true` function will skips spaces surrounding
  /// (before, between and after) a encoded bytes. However, spaces should not
  /// break a pair of characters encoding a single byte.
  inline MDBX_NOTHROW_PURE_FUNCTION bool
  is_hex(bool ignore_spaces = false) const noexcept;

  /// \brief Checks whether the content of the slice is a
  /// [Base58](https://en.wikipedia.org/wiki/Base58) dump.
  /// \param [in] ignore_spaces If `true` function will skips spaces surrounding
  /// (before, between and after) a encoded bytes. However, spaces should not
  /// break a code group of characters.
  inline MDBX_NOTHROW_PURE_FUNCTION bool
  is_base58(bool ignore_spaces = false) const noexcept;

  /// \brief Checks whether the content of the slice is a
  /// [Base64](https://en.wikipedia.org/wiki/Base64) dump.
  /// \param [in] ignore_spaces If `true` function will skips spaces surrounding
  /// (before, between and after) a encoded bytes. However, spaces should not
  /// break a code group of characters.
  inline MDBX_NOTHROW_PURE_FUNCTION bool
  is_base64(bool ignore_spaces = false) const noexcept;

  inline void swap(slice &other) noexcept;

#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L)
  template <class CHAR, class T>
  void swap(::std::basic_string_view<CHAR, T> &view) noexcept {
    static_assert(sizeof(CHAR) == 1, "Must be single byte characters");
    const auto temp = ::std::basic_string_view<CHAR, T>(*this);
    *this = view;
    view = temp;
  }
#endif /* __cpp_lib_string_view >= 201606L */

  /// \brief Returns casted to pointer to byte an address of data.
  MDBX_CXX11_CONSTEXPR const byte *byte_ptr() const noexcept;
  MDBX_CXX11_CONSTEXPR byte *byte_ptr() noexcept;

  /// \brief Returns casted to pointer to byte an end of data.
  MDBX_CXX11_CONSTEXPR const byte *end_byte_ptr() const noexcept;
  MDBX_CXX11_CONSTEXPR byte *end_byte_ptr() noexcept;

  /// \brief Returns casted to pointer to char an address of data.
  MDBX_CXX11_CONSTEXPR const char *char_ptr() const noexcept;
  MDBX_CXX11_CONSTEXPR char *char_ptr() noexcept;

  /// \brief Returns casted to pointer to char an end of data.
  MDBX_CXX11_CONSTEXPR const char *end_char_ptr() const noexcept;
  MDBX_CXX11_CONSTEXPR char *end_char_ptr() noexcept;

  /// \brief Return a pointer to the beginning of the referenced data.
  MDBX_CXX11_CONSTEXPR const void *data() const noexcept;
  MDBX_CXX11_CONSTEXPR void *data() noexcept;

  /// \brief Return a pointer to the ending of the referenced data.
  MDBX_CXX11_CONSTEXPR const void *end() const noexcept;
  MDBX_CXX11_CONSTEXPR void *end() noexcept;

  /// \brief Returns the number of bytes.
  MDBX_CXX11_CONSTEXPR size_t length() const noexcept;

  /// \brief Set slice length.
  MDBX_CXX14_CONSTEXPR slice &set_length(size_t bytes);

  /// \brief Sets the length by specifying the end of the slice data.
  MDBX_CXX14_CONSTEXPR slice &set_end(const void *ptr);

  /// \brief Checks whether the slice is empty.
  MDBX_CXX11_CONSTEXPR bool empty() const noexcept;

  /// \brief Checks whether the slice data pointer is nullptr.
  MDBX_CXX11_CONSTEXPR bool is_null() const noexcept;

  /// \brief Returns the number of bytes.
  MDBX_CXX11_CONSTEXPR size_t size() const noexcept;

  /// \brief Returns true if slice is not empty.
  MDBX_CXX11_CONSTEXPR operator bool() const noexcept;

  /// \brief Depletes content of slice and make it invalid.
  MDBX_CXX14_CONSTEXPR void invalidate() noexcept;

  /// \brief Makes the slice empty and referencing to nothing.
  MDBX_CXX14_CONSTEXPR void clear() noexcept;

  /// \brief Drops the first "n" bytes from this slice.
  /// \pre REQUIRES: `n <= size()`
  inline void remove_prefix(size_t n) noexcept;

  /// \brief Drops the last "n" bytes from this slice.
  /// \pre REQUIRES: `n <= size()`
  inline void remove_suffix(size_t n) noexcept;

  /// \brief Drops the first "n" bytes from this slice.
  /// \throws std::out_of_range if `n > size()`
  inline void safe_remove_prefix(size_t n);

  /// \brief Drops the last "n" bytes from this slice.
  /// \throws std::out_of_range if `n > size()`
  inline void safe_remove_suffix(size_t n);

  /// \brief Checks if the data starts with the given prefix.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR bool
  starts_with(const slice &prefix) const noexcept;

  /// \brief Checks if the data ends with the given suffix.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR bool
  ends_with(const slice &suffix) const noexcept;

  /// \brief Returns the nth byte in the referenced data.
  /// \pre REQUIRES: `n < size()`
  MDBX_CXX11_CONSTEXPR byte operator[](size_t n) const noexcept;

  /// \brief Returns the nth byte in the referenced data with bounds checking.
  /// \throws std::out_of_range if `n >= size()`
  MDBX_CXX11_CONSTEXPR byte at(size_t n) const;

  /// \brief Returns the first "n" bytes of the slice.
  /// \pre REQUIRES: `n <= size()`
  MDBX_CXX14_CONSTEXPR slice head(size_t n) const noexcept;

  /// \brief Returns the last "n" bytes of the slice.
  /// \pre REQUIRES: `n <= size()`
  MDBX_CXX14_CONSTEXPR slice tail(size_t n) const noexcept;

  /// \brief Returns the middle "n" bytes of the slice.
  /// \pre REQUIRES: `from + n <= size()`
  MDBX_CXX14_CONSTEXPR slice middle(size_t from, size_t n) const noexcept;

  /// \brief Returns the first "n" bytes of the slice.
  /// \throws std::out_of_range if `n >= size()`
  MDBX_CXX14_CONSTEXPR slice safe_head(size_t n) const;

  /// \brief Returns the last "n" bytes of the slice.
  /// \throws std::out_of_range if `n >= size()`
  MDBX_CXX14_CONSTEXPR slice safe_tail(size_t n) const;

  /// \brief Returns the middle "n" bytes of the slice.
  /// \throws std::out_of_range if `from + n >= size()`
  MDBX_CXX14_CONSTEXPR slice safe_middle(size_t from, size_t n) const;

  /// \brief Returns the hash value of referenced data.
  /// \attention Function implementation and returned hash values may changed
  /// version to version, and in future the t1ha3 will be used here. Therefore
  /// values obtained from this function shouldn't be persisted anywhere.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR size_t
  hash_value() const noexcept;

  /// \brief Three-way fast non-lexicographically length-based comparison.
  /// \details Firstly compares length and if it equal then compare content
  /// lexicographically. \return value:
  ///  `== 0` if `a` the same as `b`;
  ///   `< 0` if `a` shorter than `b`,
  ///             or the same length and lexicographically less than `b`;
  ///   `> 0` if `a` longer than `b`,
  ///             or the same length and lexicographically great than `b`.
  MDBX_NOTHROW_PURE_FUNCTION static MDBX_CXX14_CONSTEXPR intptr_t
  compare_fast(const slice &a, const slice &b) noexcept;

  /// \brief Three-way lexicographically comparison.
  /// \return value:
  ///  `== 0` if `a` lexicographically equal `b`;
  ///   `< 0` if `a` lexicographically less than `b`;
  ///   `> 0` if `a` lexicographically great than `b`.
  MDBX_NOTHROW_PURE_FUNCTION static MDBX_CXX14_CONSTEXPR intptr_t
  compare_lexicographically(const slice &a, const slice &b) noexcept;
  friend MDBX_CXX14_CONSTEXPR bool operator==(const slice &a,
                                              const slice &b) noexcept;
  friend MDBX_CXX14_CONSTEXPR bool operator<(const slice &a,
                                             const slice &b) noexcept;
  friend MDBX_CXX14_CONSTEXPR bool operator>(const slice &a,
                                             const slice &b) noexcept;
  friend MDBX_CXX14_CONSTEXPR bool operator<=(const slice &a,
                                              const slice &b) noexcept;
  friend MDBX_CXX14_CONSTEXPR bool operator>=(const slice &a,
                                              const slice &b) noexcept;
  friend MDBX_CXX14_CONSTEXPR bool operator!=(const slice &a,
                                              const slice &b) noexcept;

  /// \brief Checks the slice is not refers to null address or has zero length.
  MDBX_CXX11_CONSTEXPR bool is_valid() const noexcept {
    return !(iov_base == nullptr && iov_len != 0);
  }

  /// \brief Build an invalid slice which non-zero length and refers to null
  /// address.
  MDBX_CXX14_CONSTEXPR static slice invalid() noexcept {
    return slice(size_t(-1));
  }

protected:
  MDBX_CXX11_CONSTEXPR slice(size_t invalid_length) noexcept
      : ::MDBX_val({nullptr, invalid_length}) {}
};

//------------------------------------------------------------------------------

namespace allocation_aware_details {

template <typename A> constexpr bool allocator_is_always_equal() noexcept {
#if defined(__cpp_lib_allocator_traits_is_always_equal) &&                     \
    __cpp_lib_allocator_traits_is_always_equal >= 201411L
  return ::std::allocator_traits<A>::is_always_equal::value;
#else
  return ::std::is_empty<A>::value;
#endif /* __cpp_lib_allocator_traits_is_always_equal */
}

template <typename T, typename A = typename T::allocator_type,
          bool PoCMA = ::std::allocator_traits<
              A>::propagate_on_container_move_assignment::value>
struct move_assign_alloc;

template <typename T, typename A> struct move_assign_alloc<T, A, false> {
  static constexpr bool is_nothrow() noexcept {
    return allocator_is_always_equal<A>();
  }
  static MDBX_CXX20_CONSTEXPR bool is_moveable(T *target, T &source) noexcept {
    return allocator_is_always_equal<A>() ||
           target->get_allocator() == source.get_allocator();
  }
  static MDBX_CXX20_CONSTEXPR void propagate(T *target, T &source) noexcept {
    assert(target->get_allocator() != source.get_allocator());
    (void)target;
    (void)source;
  }
};

template <typename T, typename A> struct move_assign_alloc<T, A, true> {
  static constexpr bool is_nothrow() noexcept {
    return allocator_is_always_equal<A>() ||
           ::std::is_nothrow_move_assignable<A>::value;
  }
  static constexpr bool is_moveable(T *, T &) noexcept { return true; }
  static MDBX_CXX20_CONSTEXPR void propagate(T *target, T &source) {
    assert(target->get_allocator() != source.get_allocator());
    target->get_allocator() = ::std::move(source.get_allocator());
  }
};

template <typename T, typename A = typename T::allocator_type,
          bool PoCCA = ::std::allocator_traits<
              A>::propagate_on_container_copy_assignment::value>
struct copy_assign_alloc;

template <typename T, typename A> struct copy_assign_alloc<T, A, false> {
  static constexpr bool is_nothrow() noexcept { return false; }
  static MDBX_CXX20_CONSTEXPR void propagate(T *target,
                                             const T &source) noexcept {
    assert(target->get_allocator() != source.get_allocator());
    (void)target;
    (void)source;
  }
};

template <typename T, typename A> struct copy_assign_alloc<T, A, true> {
  static constexpr bool is_nothrow() noexcept {
    return allocator_is_always_equal<A>() ||
           ::std::is_nothrow_copy_assignable<A>::value;
  }
  static MDBX_CXX20_CONSTEXPR void
  propagate(T *target, const T &source) noexcept(is_nothrow()) {
    if MDBX_IF_CONSTEXPR (!allocator_is_always_equal<A>()) {
      if (MDBX_UNLIKELY(target->get_allocator() != source.get_allocator()))
        MDBX_CXX20_UNLIKELY target->get_allocator() =
            ::std::allocator_traits<A>::select_on_container_copy_construction(
                source.get_allocator());
    } else {
      /* gag for buggy compilers */
      (void)target;
      (void)source;
    }
  }
};

template <typename T, typename A = typename T::allocator_type,
          bool PoCS =
              ::std::allocator_traits<A>::propagate_on_container_swap::value>
struct swap_alloc;

template <typename T, typename A> struct swap_alloc<T, A, false> {
  static constexpr bool is_nothrow() noexcept {
    return allocator_is_always_equal<A>();
  }
  static MDBX_CXX20_CONSTEXPR void propagate(T *target,
                                             T &source) noexcept(is_nothrow()) {
    if MDBX_IF_CONSTEXPR (!allocator_is_always_equal<A>()) {
      if (MDBX_UNLIKELY(target->get_allocator() != source.get_allocator()))
        MDBX_CXX20_UNLIKELY throw_allocators_mismatch();
    } else {
      /* gag for buggy compilers */
      (void)target;
      (void)source;
    }
  }
};

template <typename T, typename A> struct swap_alloc<T, A, true> {
  static constexpr bool is_nothrow() noexcept {
    return allocator_is_always_equal<A>() ||
#if defined(__cpp_lib_is_swappable) && __cpp_lib_is_swappable >= 201603L
           ::std::is_nothrow_swappable<A>() ||
#endif /* __cpp_lib_is_swappable >= 201603L */
           (::std::is_nothrow_move_constructible<A>::value &&
            ::std::is_nothrow_move_assignable<A>::value);
  }
  static MDBX_CXX20_CONSTEXPR void propagate(T *target,
                                             T &source) noexcept(is_nothrow()) {
    if MDBX_IF_CONSTEXPR (!allocator_is_always_equal<A>()) {
      if (MDBX_UNLIKELY(target->get_allocator() != source.get_allocator()))
        MDBX_CXX20_UNLIKELY ::std::swap(*target, source);
    } else {
      /* gag for buggy compilers */
      (void)target;
      (void)source;
    }
  }
};

} // namespace allocation_aware_details

struct default_capacity_policy {
  enum : size_t {
    extra_inplace_storage = 0,
    pettiness_threshold = 64,
    max_reserve = 65536
  };

  static MDBX_CXX11_CONSTEXPR size_t round(const size_t value) {
    static_assert((pettiness_threshold & (pettiness_threshold - 1)) == 0,
                  "pettiness_threshold must be a power of 2");
    static_assert(pettiness_threshold % 2 == 0,
                  "pettiness_threshold must be even");
    static_assert(pettiness_threshold >= sizeof(uint64_t),
                  "pettiness_threshold must be > 7");
    constexpr const auto pettiness_mask = ~size_t(pettiness_threshold - 1);
    return (value + pettiness_threshold - 1) & pettiness_mask;
  }

  static MDBX_CXX11_CONSTEXPR size_t advise(const size_t current,
                                            const size_t wanna) {
    static_assert(max_reserve % pettiness_threshold == 0,
                  "max_reserve must be a multiple of pettiness_threshold");
    static_assert(max_reserve / 3 > pettiness_threshold,
                  "max_reserve must be > pettiness_threshold * 3");
    if (wanna > current)
      /* doubling capacity, but don't made reserve more than max_reserve */
      return round(wanna + ::std::min(size_t(max_reserve), current));

    if (current - wanna >
        /* shrink if reserve will more than half of current or max_reserve,
         * but not less than pettiness_threshold */
        ::std::min(wanna + pettiness_threshold, size_t(max_reserve)))
      return round(wanna);

    /* keep unchanged */
    return current;
  }
};

/// \brief Hexadecimal encoder which satisfy \ref SliceTranscoder concept.
struct LIBMDBX_API to_hex {
  const slice source;
  const bool uppercase = false;
  const unsigned wrap_width = 0;
  MDBX_CXX11_CONSTEXPR to_hex(const slice &source, bool uppercase = false,
                              unsigned wrap_width = 0) noexcept
      : source(source), uppercase(uppercase), wrap_width(wrap_width) {
    MDBX_ASSERT_CXX20_CONCEPT_SATISFIED(SliceTranscoder, to_hex);
  }

  /// \brief Returns a string with a hexadecimal dump of a passed slice.
  template <class ALLOCATOR = legacy_allocator>
  string<ALLOCATOR> as_string(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_string<ALLOCATOR>(*this, allocator);
  }

  /// \brief Returns a buffer with a hexadecimal dump of a passed slice.
  template <class ALLOCATOR = legacy_allocator,
            typename CAPACITY_POLICY = default_capacity_policy>
  buffer<ALLOCATOR, CAPACITY_POLICY>
  as_buffer(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_buffer<ALLOCATOR>(*this, allocator);
  }

  /// \brief Returns the buffer size in bytes needed for hexadecimal
  /// dump of a passed slice.
  MDBX_CXX11_CONSTEXPR size_t envisage_result_length() const noexcept {
    const size_t bytes = source.length() << 1;
    return wrap_width ? bytes + bytes / wrap_width : bytes;
  }

  /// \brief Fills the buffer by hexadecimal dump of a passed slice.
  /// \throws std::length_error if given buffer is too small.
  char *write_bytes(char *dest, size_t dest_size) const;

  /// \brief Output hexadecimal dump of passed slice to the std::ostream.
  /// \throws std::ios_base::failure corresponding to std::ostream::write()
  /// behaviour.
  ::std::ostream &output(::std::ostream &out) const;

  /// \brief Checks whether a passed slice is empty,
  /// and therefore there will be no output bytes.
  bool is_empty() const noexcept { return source.empty(); }

  /// \brief Checks whether the content of a passed slice is a valid data
  /// and could be encoded or unexpectedly not.
  bool is_erroneous() const noexcept { return false; }
};

/// \brief [Base58](https://en.wikipedia.org/wiki/Base58) encoder which satisfy
/// \ref SliceTranscoder concept.
struct LIBMDBX_API to_base58 {
  const slice source;
  const unsigned wrap_width = 0;
  MDBX_CXX11_CONSTEXPR
  to_base58(const slice &source, unsigned wrap_width = 0) noexcept
      : source(source), wrap_width(wrap_width) {
    MDBX_ASSERT_CXX20_CONCEPT_SATISFIED(SliceTranscoder, to_base58);
  }

  /// \brief Returns a string with a
  /// [Base58](https://en.wikipedia.org/wiki/Base58) dump of a passed slice.
  template <class ALLOCATOR = legacy_allocator>
  string<ALLOCATOR> as_string(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_string<ALLOCATOR>(*this, allocator);
  }

  /// \brief Returns a buffer with a
  /// [Base58](https://en.wikipedia.org/wiki/Base58) dump of a passed slice.
  template <class ALLOCATOR = legacy_allocator,
            typename CAPACITY_POLICY = default_capacity_policy>
  buffer<ALLOCATOR, CAPACITY_POLICY>
  as_buffer(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_buffer<ALLOCATOR>(*this, allocator);
  }

  /// \brief Returns the buffer size in bytes needed for
  /// [Base58](https://en.wikipedia.org/wiki/Base58) dump of passed slice.
  MDBX_CXX11_CONSTEXPR size_t envisage_result_length() const noexcept {
    const size_t bytes =
        source.length() / 8 * 11 + (source.length() % 8 * 43 + 31) / 32;
    return wrap_width ? bytes + bytes / wrap_width : bytes;
  }

  /// \brief Fills the buffer by [Base58](https://en.wikipedia.org/wiki/Base58)
  /// dump of passed slice.
  /// \throws std::length_error if given buffer is too small.
  char *write_bytes(char *dest, size_t dest_size) const;

  /// \brief Output [Base58](https://en.wikipedia.org/wiki/Base58)
  /// dump of passed slice to the std::ostream.
  /// \throws std::ios_base::failure corresponding to std::ostream::write()
  /// behaviour.
  ::std::ostream &output(::std::ostream &out) const;

  /// \brief Checks whether a passed slice is empty,
  /// and therefore there will be no output bytes.
  bool is_empty() const noexcept { return source.empty(); }

  /// \brief Checks whether the content of a passed slice is a valid data
  /// and could be encoded or unexpectedly not.
  bool is_erroneous() const noexcept { return false; }
};

/// \brief [Base64](https://en.wikipedia.org/wiki/Base64) encoder which satisfy
/// \ref SliceTranscoder concept.
struct LIBMDBX_API to_base64 {
  const slice source;
  const unsigned wrap_width = 0;
  MDBX_CXX11_CONSTEXPR
  to_base64(const slice &source, unsigned wrap_width = 0) noexcept
      : source(source), wrap_width(wrap_width) {
    MDBX_ASSERT_CXX20_CONCEPT_SATISFIED(SliceTranscoder, to_base64);
  }

  /// \brief Returns a string with a
  /// [Base64](https://en.wikipedia.org/wiki/Base64) dump of a passed slice.
  template <class ALLOCATOR = legacy_allocator>
  string<ALLOCATOR> as_string(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_string<ALLOCATOR>(*this, allocator);
  }

  /// \brief Returns a buffer with a
  /// [Base64](https://en.wikipedia.org/wiki/Base64) dump of a passed slice.
  template <class ALLOCATOR = legacy_allocator,
            typename CAPACITY_POLICY = default_capacity_policy>
  buffer<ALLOCATOR, CAPACITY_POLICY>
  as_buffer(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_buffer<ALLOCATOR>(*this, allocator);
  }

  /// \brief Returns the buffer size in bytes needed for
  /// [Base64](https://en.wikipedia.org/wiki/Base64) dump of passed slice.
  MDBX_CXX11_CONSTEXPR size_t envisage_result_length() const noexcept {
    const size_t bytes = (source.length() + 2) / 3 * 4;
    return wrap_width ? bytes + bytes / wrap_width : bytes;
  }

  /// \brief Fills the buffer by [Base64](https://en.wikipedia.org/wiki/Base64)
  /// dump of passed slice.
  /// \throws std::length_error if given buffer is too small.
  char *write_bytes(char *dest, size_t dest_size) const;

  /// \brief Output [Base64](https://en.wikipedia.org/wiki/Base64)
  /// dump of passed slice to the std::ostream.
  /// \throws std::ios_base::failure corresponding to std::ostream::write()
  /// behaviour.
  ::std::ostream &output(::std::ostream &out) const;

  /// \brief Checks whether a passed slice is empty,
  /// and therefore there will be no output bytes.
  bool is_empty() const noexcept { return source.empty(); }

  /// \brief Checks whether the content of a passed slice is a valid data
  /// and could be encoded or unexpectedly not.
  bool is_erroneous() const noexcept { return false; }
};

inline ::std::ostream &operator<<(::std::ostream &out, const to_hex &wrapper) {
  return wrapper.output(out);
}
inline ::std::ostream &operator<<(::std::ostream &out,
                                  const to_base58 &wrapper) {
  return wrapper.output(out);
}
inline ::std::ostream &operator<<(::std::ostream &out,
                                  const to_base64 &wrapper) {
  return wrapper.output(out);
}

/// \brief Hexadecimal decoder which satisfy \ref SliceTranscoder concept.
struct LIBMDBX_API from_hex {
  const slice source;
  const bool ignore_spaces = false;
  MDBX_CXX11_CONSTEXPR from_hex(const slice &source,
                                bool ignore_spaces = false) noexcept
      : source(source), ignore_spaces(ignore_spaces) {
    MDBX_ASSERT_CXX20_CONCEPT_SATISFIED(SliceTranscoder, from_hex);
  }

  /// \brief Decodes hexadecimal dump from a passed slice to returned string.
  template <class ALLOCATOR = legacy_allocator>
  string<ALLOCATOR> as_string(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_string<ALLOCATOR>(*this, allocator);
  }

  /// \brief Decodes hexadecimal dump from a passed slice to returned buffer.
  template <class ALLOCATOR = legacy_allocator,
            typename CAPACITY_POLICY = default_capacity_policy>
  buffer<ALLOCATOR, CAPACITY_POLICY>
  as_buffer(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_buffer<ALLOCATOR>(*this, allocator);
  }

  /// \brief Returns the number of bytes needed for conversion
  /// hexadecimal dump from a passed slice to decoded data.
  MDBX_CXX11_CONSTEXPR size_t envisage_result_length() const noexcept {
    return source.length() >> 1;
  }

  /// \brief Fills the destination with data decoded from hexadecimal dump
  /// from a passed slice.
  /// \throws std::length_error if given buffer is too small.
  char *write_bytes(char *dest, size_t dest_size) const;

  /// \brief Checks whether a passed slice is empty,
  /// and therefore there will be no output bytes.
  bool is_empty() const noexcept { return source.empty(); }

  /// \brief Checks whether the content of a passed slice is a valid hexadecimal
  /// dump, and therefore there could be decoded or not.
  bool is_erroneous() const noexcept;
};

/// \brief [Base58](https://en.wikipedia.org/wiki/Base58) decoder which satisfy
/// \ref SliceTranscoder concept.
struct LIBMDBX_API from_base58 {
  const slice source;
  const bool ignore_spaces = false;
  MDBX_CXX11_CONSTEXPR from_base58(const slice &source,
                                   bool ignore_spaces = false) noexcept
      : source(source), ignore_spaces(ignore_spaces) {
    MDBX_ASSERT_CXX20_CONCEPT_SATISFIED(SliceTranscoder, from_base58);
  }

  /// \brief Decodes [Base58](https://en.wikipedia.org/wiki/Base58) dump from a
  /// passed slice to returned string.
  template <class ALLOCATOR = legacy_allocator>
  string<ALLOCATOR> as_string(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_string<ALLOCATOR>(*this, allocator);
  }

  /// \brief Decodes [Base58](https://en.wikipedia.org/wiki/Base58) dump from a
  /// passed slice to returned buffer.
  template <class ALLOCATOR = legacy_allocator,
            typename CAPACITY_POLICY = default_capacity_policy>
  buffer<ALLOCATOR, CAPACITY_POLICY>
  as_buffer(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_buffer<ALLOCATOR>(*this, allocator);
  }

  /// \brief Returns the number of bytes needed for conversion
  /// [Base58](https://en.wikipedia.org/wiki/Base58) dump from a passed slice to
  /// decoded data.
  MDBX_CXX11_CONSTEXPR size_t envisage_result_length() const noexcept {
    return source.length() / 11 * 8 + source.length() % 11 * 32 / 43;
  }

  /// \brief Fills the destination with data decoded from
  /// [Base58](https://en.wikipedia.org/wiki/Base58) dump from a passed slice.
  /// \throws std::length_error if given buffer is too small.
  char *write_bytes(char *dest, size_t dest_size) const;

  /// \brief Checks whether a passed slice is empty,
  /// and therefore there will be no output bytes.
  bool is_empty() const noexcept { return source.empty(); }

  /// \brief Checks whether the content of a passed slice is a valid
  /// [Base58](https://en.wikipedia.org/wiki/Base58) dump, and therefore there
  /// could be decoded or not.
  bool is_erroneous() const noexcept;
};

/// \brief [Base64](https://en.wikipedia.org/wiki/Base64) decoder which satisfy
/// \ref SliceTranscoder concept.
struct LIBMDBX_API from_base64 {
  const slice source;
  const bool ignore_spaces = false;
  MDBX_CXX11_CONSTEXPR from_base64(const slice &source,
                                   bool ignore_spaces = false) noexcept
      : source(source), ignore_spaces(ignore_spaces) {
    MDBX_ASSERT_CXX20_CONCEPT_SATISFIED(SliceTranscoder, from_base64);
  }

  /// \brief Decodes [Base64](https://en.wikipedia.org/wiki/Base64) dump from a
  /// passed slice to returned string.
  template <class ALLOCATOR = legacy_allocator>
  string<ALLOCATOR> as_string(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_string<ALLOCATOR>(*this, allocator);
  }

  /// \brief Decodes [Base64](https://en.wikipedia.org/wiki/Base64) dump from a
  /// passed slice to returned buffer.
  template <class ALLOCATOR = legacy_allocator,
            typename CAPACITY_POLICY = default_capacity_policy>
  buffer<ALLOCATOR, CAPACITY_POLICY>
  as_buffer(const ALLOCATOR &allocator = ALLOCATOR()) const {
    return make_buffer<ALLOCATOR>(*this, allocator);
  }

  /// \brief Returns the number of bytes needed for conversion
  /// [Base64](https://en.wikipedia.org/wiki/Base64) dump from a passed slice to
  /// decoded data.
  MDBX_CXX11_CONSTEXPR size_t envisage_result_length() const noexcept {
    return (source.length() + 3) / 4 * 3;
  }

  /// \brief Fills the destination with data decoded from
  /// [Base64](https://en.wikipedia.org/wiki/Base64) dump from a passed slice.
  /// \throws std::length_error if given buffer is too small.
  char *write_bytes(char *dest, size_t dest_size) const;

  /// \brief Checks whether a passed slice is empty,
  /// and therefore there will be no output bytes.
  bool is_empty() const noexcept { return source.empty(); }

  /// \brief Checks whether the content of a passed slice is a valid
  /// [Base64](https://en.wikipedia.org/wiki/Base64) dump, and therefore there
  /// could be decoded or not.
  bool is_erroneous() const noexcept;
};

/// \brief The chunk of data stored inside the buffer or located outside it.
template <class ALLOCATOR, typename CAPACITY_POLICY> class buffer {
public:
#if !defined(_MSC_VER) || _MSC_VER > 1900
  using allocator_type = typename ::std::allocator_traits<
      ALLOCATOR>::template rebind_alloc<uint64_t>;
#else
  using allocator_type = typename ALLOCATOR::template rebind<uint64_t>::other;
#endif /* MSVC is mad */
  using allocator_traits = ::std::allocator_traits<allocator_type>;
  using reservation_policy = CAPACITY_POLICY;
  enum : size_t {
    max_length = MDBX_MAXDATASIZE,
    max_capacity = (max_length / 3u * 4u + 1023u) & ~size_t(1023),
    extra_inplace_storage = reservation_policy::extra_inplace_storage,
    pettiness_threshold = reservation_policy::pettiness_threshold
  };

private:
  friend class txn;
  struct silo;
  using move_assign_alloc =
      allocation_aware_details::move_assign_alloc<silo, allocator_type>;
  using copy_assign_alloc =
      allocation_aware_details::copy_assign_alloc<silo, allocator_type>;
  using swap_alloc = allocation_aware_details::swap_alloc<silo, allocator_type>;
  struct silo /* Empty Base Class Optimization */ : public allocator_type {
    MDBX_CXX20_CONSTEXPR const allocator_type &get_allocator() const noexcept {
      return *this;
    }
    MDBX_CXX20_CONSTEXPR allocator_type &get_allocator() noexcept {
      return *this;
    }

    using allocator_pointer = typename allocator_traits::pointer;
    using allocator_const_pointer = typename allocator_traits::const_pointer;

    MDBX_CXX20_CONSTEXPR ::std::pair<allocator_pointer, size_t>
    allocate_storage(size_t bytes) {
      assert(bytes >= sizeof(bin));
      constexpr size_t unit = sizeof(typename allocator_type::value_type);
      static_assert((unit & (unit - 1)) == 0,
                    "size of ALLOCATOR::value_type should be a power of 2");
      static_assert(unit > 0, "size of ALLOCATOR::value_type must be > 0");
      const size_t n = (bytes + unit - 1) / unit;
      return ::std::make_pair(allocator_traits::allocate(get_allocator(), n),
                              n * unit);
    }
    MDBX_CXX20_CONSTEXPR void deallocate_storage(allocator_pointer ptr,
                                                 size_t bytes) {
      constexpr size_t unit = sizeof(typename allocator_type::value_type);
      assert(ptr && bytes >= sizeof(bin) && bytes >= unit && bytes % unit == 0);
      allocator_traits::deallocate(get_allocator(), ptr, bytes / unit);
    }

    static MDBX_CXX17_CONSTEXPR void *
    to_address(allocator_pointer ptr) noexcept {
#if defined(__cpp_lib_to_address) && __cpp_lib_to_address >= 201711L
      return static_cast<void *>(::std::to_address(ptr));
#else
      return static_cast<void *>(::std::addressof(*ptr));
#endif /* __cpp_lib_to_address */
    }
    static MDBX_CXX17_CONSTEXPR const void *
    to_address(allocator_const_pointer ptr) noexcept {
#if defined(__cpp_lib_to_address) && __cpp_lib_to_address >= 201711L
      return static_cast<const void *>(::std::to_address(ptr));
#else
      return static_cast<const void *>(::std::addressof(*ptr));
#endif /* __cpp_lib_to_address */
    }

    union bin {
      struct allocated {
        allocator_pointer ptr_;
        size_t capacity_bytes_;
        constexpr allocated(allocator_pointer ptr, size_t bytes) noexcept
            : ptr_(ptr), capacity_bytes_(bytes) {}
        constexpr allocated(const allocated &) noexcept = default;
        constexpr allocated(allocated &&) noexcept = default;
        MDBX_CXX17_CONSTEXPR allocated &
        operator=(const allocated &) noexcept = default;
        MDBX_CXX17_CONSTEXPR allocated &
        operator=(allocated &&) noexcept = default;
      };

      allocated allocated_;
      uint64_t align_hint_;
      byte inplace_[(sizeof(allocated) + extra_inplace_storage + 7u) &
                    ~size_t(7)];

      static constexpr bool
      is_suitable_for_inplace(size_t capacity_bytes) noexcept {
        static_assert(sizeof(bin) == sizeof(inplace_), "WTF?");
        return capacity_bytes < sizeof(bin);
      }

      enum : byte {
        /* Little Endian:
         *   last byte is the most significant byte of u_.allocated.cap,
         *   so use higher bit of capacity as the inplace-flag */
        le_lastbyte_mask = 0x80,
        /* Big Endian:
         *   last byte is the least significant byte of u_.allocated.cap,
         *   so use lower bit of capacity as the inplace-flag. */
        be_lastbyte_mask = 0x01
      };

      static constexpr byte inplace_lastbyte_mask() noexcept {
        static_assert(
            endian::native == endian::little || endian::native == endian::big,
            "Only the little-endian or big-endian bytes order are supported");
        return (endian::native == endian::little) ? le_lastbyte_mask
                                                  : be_lastbyte_mask;
      }
      constexpr byte lastbyte() const noexcept {
        return inplace_[sizeof(bin) - 1];
      }
      MDBX_CXX17_CONSTEXPR byte &lastbyte() noexcept {
        return inplace_[sizeof(bin) - 1];
      }

      constexpr bool is_inplace() const noexcept {
        return (lastbyte() & inplace_lastbyte_mask()) != 0;
      }
      constexpr bool is_allocated() const noexcept { return !is_inplace(); }

      template <bool destroy_ptr>
      MDBX_CXX17_CONSTEXPR byte *make_inplace() noexcept {
        if (destroy_ptr) {
          MDBX_CONSTEXPR_ASSERT(is_allocated());
          /* properly destroy allocator::pointer */
          allocated_.~allocated();
        }
        if (::std::is_trivial<allocator_pointer>::value)
          /* workaround for "uninitialized" warning from some compilers */
          ::std::memset(&allocated_.ptr_, 0, sizeof(allocated_.ptr_));
        lastbyte() = inplace_lastbyte_mask();
        MDBX_CONSTEXPR_ASSERT(is_inplace() && address() == inplace_ &&
                              is_suitable_for_inplace(capacity()));
        return address();
      }

      template <bool construct_ptr>
      MDBX_CXX17_CONSTEXPR byte *
      make_allocated(allocator_pointer ptr, size_t capacity_bytes) noexcept {
        MDBX_CONSTEXPR_ASSERT(
            (capacity_bytes & be_lastbyte_mask) == 0 &&
            ((capacity_bytes >>
              (sizeof(allocated_.capacity_bytes_) - 1) * CHAR_BIT) &
             le_lastbyte_mask) == 0);
        if (construct_ptr)
          /* properly construct allocator::pointer */
          new (&allocated_) allocated(ptr, capacity_bytes);
        else {
          MDBX_CONSTEXPR_ASSERT(is_allocated());
          allocated_.ptr_ = ptr;
          allocated_.capacity_bytes_ = capacity_bytes;
        }
        MDBX_CONSTEXPR_ASSERT(is_allocated() && address() == to_address(ptr) &&
                              capacity() == capacity_bytes);
        return address();
      }

      MDBX_CXX20_CONSTEXPR bin(size_t capacity_bytes = 0) noexcept {
        MDBX_CONSTEXPR_ASSERT(is_suitable_for_inplace(capacity_bytes));
        make_inplace<false>();
        (void)capacity_bytes;
      }
      MDBX_CXX20_CONSTEXPR bin(allocator_pointer ptr,
                               size_t capacity_bytes) noexcept {
        MDBX_CONSTEXPR_ASSERT(!is_suitable_for_inplace(capacity_bytes));
        make_allocated<true>(ptr, capacity_bytes);
      }
      MDBX_CXX20_CONSTEXPR ~bin() {
        if (is_allocated())
          /* properly destroy allocator::pointer */
          allocated_.~allocated();
      }
      MDBX_CXX20_CONSTEXPR bin(bin &&ditto) noexcept {
        if (ditto.is_inplace()) {
          // micro-optimization: don't use make_inplace<> here
          //                     since memcpy() will copy the flag.
          memcpy(inplace_, ditto.inplace_, sizeof(inplace_));
          MDBX_CONSTEXPR_ASSERT(is_inplace());
        } else {
          new (&allocated_) allocated(::std::move(ditto.allocated_));
          ditto.make_inplace<true>();
          MDBX_CONSTEXPR_ASSERT(is_allocated());
        }
      }

      MDBX_CXX17_CONSTEXPR bin &operator=(const bin &ditto) noexcept {
        if (ditto.is_inplace()) {
          // micro-optimization: don't use make_inplace<> here
          //                     since memcpy() will copy the flag.
          if (is_allocated())
            /* properly destroy allocator::pointer */
            allocated_.~allocated();
          memcpy(inplace_, ditto.inplace_, sizeof(inplace_));
          MDBX_CONSTEXPR_ASSERT(is_inplace());
        } else if (is_inplace())
          make_allocated<true>(ditto.allocated_.ptr_,
                               ditto.allocated_.capacity_bytes_);
        else
          make_allocated<false>(ditto.allocated_.ptr_,
                                ditto.allocated_.capacity_bytes_);
        return *this;
      }

      MDBX_CXX17_CONSTEXPR bin &operator=(bin &&ditto) noexcept {
        operator=(const_cast<const bin &>(ditto));
        if (ditto.is_allocated())
          ditto.make_inplace<true>();
        return *this;
      }

      static MDBX_CXX20_CONSTEXPR size_t advise_capacity(const size_t current,
                                                         const size_t wanna) {
        if (MDBX_UNLIKELY(wanna > max_capacity))
          MDBX_CXX20_UNLIKELY throw_max_length_exceeded();

        const size_t advised = reservation_policy::advise(current, wanna);
        assert(advised >= wanna);
        return ::std::min(size_t(max_capacity),
                          ::std::max(sizeof(bin) - 1, advised));
      }

      constexpr const byte *address() const noexcept {
        return is_inplace()
                   ? inplace_
                   : static_cast<const byte *>(to_address(allocated_.ptr_));
      }
      MDBX_CXX17_CONSTEXPR byte *address() noexcept {
        return is_inplace() ? inplace_
                            : static_cast<byte *>(to_address(allocated_.ptr_));
      }
      constexpr size_t capacity() const noexcept {
        return is_inplace() ? sizeof(bin) - 1 : allocated_.capacity_bytes_;
      }
    } bin_;

    MDBX_CXX20_CONSTEXPR void *init(size_t capacity) {
      capacity = bin::advise_capacity(0, capacity);
      if (bin_.is_suitable_for_inplace(capacity))
        new (&bin_) bin();
      else {
        const auto pair = allocate_storage(capacity);
        assert(pair.second >= capacity);
        new (&bin_) bin(pair.first, pair.second);
      }
      return bin_.address();
    }

    MDBX_CXX20_CONSTEXPR void release() noexcept {
      if (bin_.is_allocated()) {
        deallocate_storage(bin_.allocated_.ptr_,
                           bin_.allocated_.capacity_bytes_);
        bin_.template make_inplace<true>();
      }
    }

    template <bool external_content>
    MDBX_CXX20_CONSTEXPR void *
    reshape(const size_t wanna_capacity, const size_t wanna_headroom,
            const void *const content, const size_t length) {
      assert(wanna_capacity >= wanna_headroom + length);
      const size_t old_capacity = bin_.capacity();
      const size_t new_capacity =
          bin::advise_capacity(old_capacity, wanna_capacity);
      assert(new_capacity >= wanna_capacity);
      if (MDBX_LIKELY(new_capacity == old_capacity))
        MDBX_CXX20_LIKELY {
          assert(bin_.is_inplace() ==
                 bin::is_suitable_for_inplace(new_capacity));
          byte *const new_place = bin_.address() + wanna_headroom;
          if (MDBX_LIKELY(length))
            MDBX_CXX20_LIKELY {
              if (external_content)
                memcpy(new_place, content, length);
              else {
                const size_t old_headroom =
                    bin_.address() - static_cast<const byte *>(content);
                assert(old_capacity >= old_headroom + length);
                if (MDBX_UNLIKELY(old_headroom != wanna_headroom))
                  MDBX_CXX20_UNLIKELY ::std::memmove(new_place, content,
                                                     length);
              }
            }
          return new_place;
        }

      if (bin::is_suitable_for_inplace(new_capacity)) {
        assert(bin_.is_allocated());
        const auto old_allocated = ::std::move(bin_.allocated_.ptr_);
        byte *const new_place =
            bin_.template make_inplace<true>() + wanna_headroom;
        if (MDBX_LIKELY(length))
          MDBX_CXX20_LIKELY memcpy(new_place, content, length);
        deallocate_storage(old_allocated, old_capacity);
        return new_place;
      }

      if (!bin_.is_allocated()) {
        const auto pair = allocate_storage(new_capacity);
        assert(pair.second >= new_capacity);
        byte *const new_place =
            static_cast<byte *>(to_address(pair.first)) + wanna_headroom;
        if (MDBX_LIKELY(length))
          MDBX_CXX20_LIKELY memcpy(new_place, content, length);
        bin_.template make_allocated<true>(pair.first, pair.second);
        return new_place;
      }

      const auto old_allocated = ::std::move(bin_.allocated_.ptr_);
      if (external_content)
        deallocate_storage(old_allocated, old_capacity);
      const auto pair = allocate_storage(new_capacity);
      assert(pair.second >= new_capacity);
      byte *const new_place =
          bin_.template make_allocated<false>(pair.first, pair.second) +
          wanna_headroom;
      if (MDBX_LIKELY(length))
        MDBX_CXX20_LIKELY memcpy(new_place, content, length);
      if (!external_content)
        deallocate_storage(old_allocated, old_capacity);
      return new_place;
    }

    MDBX_CXX20_CONSTEXPR const byte *get(size_t offset = 0) const noexcept {
      assert(capacity() >= offset);
      return bin_.address() + offset;
    }
    MDBX_CXX20_CONSTEXPR byte *get(size_t offset = 0) noexcept {
      assert(capacity() >= offset);
      return bin_.address() + offset;
    }
    MDBX_CXX20_CONSTEXPR byte *put(size_t offset, const void *ptr,
                                   size_t length) {
      assert(capacity() >= offset + length);
      return static_cast<byte *>(memcpy(get(offset), ptr, length));
    }

    //--------------------------------------------------------------------------

    MDBX_CXX20_CONSTEXPR
    silo() noexcept : allocator_type() { init(0); }
    MDBX_CXX20_CONSTEXPR
    silo(const allocator_type &alloc) noexcept : allocator_type(alloc) {
      init(0);
    }
    MDBX_CXX20_CONSTEXPR silo(size_t capacity) { init(capacity); }
    MDBX_CXX20_CONSTEXPR silo(size_t capacity, const allocator_type &alloc)
        : silo(alloc) {
      init(capacity);
    }

    MDBX_CXX20_CONSTEXPR silo(silo &&ditto) noexcept(
        ::std::is_nothrow_move_constructible<allocator_type>::value)
        : allocator_type(::std::move(ditto.get_allocator())),
          bin_(::std::move(ditto.bin_)) {}

    MDBX_CXX20_CONSTEXPR silo(size_t capacity, size_t headroom, const void *ptr,
                              size_t length)
        : silo(capacity) {
      assert(capacity >= headroom + length);
      if (length)
        put(headroom, ptr, length);
    }

    // select_on_container_copy_construction()
    MDBX_CXX20_CONSTEXPR silo(size_t capacity, size_t headroom, const void *ptr,
                              size_t length, const allocator_type &alloc)
        : silo(capacity, alloc) {
      assert(capacity >= headroom + length);
      if (length)
        put(headroom, ptr, length);
    }

    MDBX_CXX20_CONSTEXPR silo(const void *ptr, size_t length)
        : silo(length, 0, ptr, length) {}
    MDBX_CXX20_CONSTEXPR silo(const void *ptr, size_t length,
                              const allocator_type &alloc)
        : silo(length, 0, ptr, length, alloc) {}

    ~silo() { release(); }

    //--------------------------------------------------------------------------

    MDBX_CXX20_CONSTEXPR void *assign(size_t headroom, const void *ptr,
                                      size_t length, size_t tailroom) {
      return reshape<true>(headroom + length + tailroom, headroom, ptr, length);
    }
    MDBX_CXX20_CONSTEXPR void *assign(const void *ptr, size_t length) {
      return assign(0, ptr, length, 0);
    }

    MDBX_CXX20_CONSTEXPR silo &assign(const silo &ditto, size_t headroom,
                                      slice &content) {
      assert(ditto.get() + headroom == content.byte_ptr());
      if MDBX_IF_CONSTEXPR (!allocation_aware_details::
                                allocator_is_always_equal<allocator_type>()) {
        if (MDBX_UNLIKELY(get_allocator() != ditto.get_allocator()))
          MDBX_CXX20_UNLIKELY {
            release();
            allocation_aware_details::copy_assign_alloc<
                silo, allocator_type>::propagate(this, ditto);
          }
      }
      content.iov_base = reshape<true>(ditto.capacity(), headroom,
                                       content.data(), content.length());
      return *this;
    }

    MDBX_CXX20_CONSTEXPR silo &
    assign(silo &&ditto, size_t headroom, slice &content) noexcept(
        allocation_aware_details::move_assign_alloc<
            silo, allocator_type>::is_nothrow()) {
      assert(ditto.get() + headroom == content.byte_ptr());
      if (allocation_aware_details::move_assign_alloc<
              silo, allocator_type>::is_moveable(this, ditto)) {
        release();
        allocation_aware_details::move_assign_alloc<
            silo, allocator_type>::propagate(this, ditto);
        /* no reallocation nor copying required */
        bin_ = ::std::move(ditto.bin_);
        assert(get() + headroom == content.byte_ptr());
      } else {
        /* copy content since allocators are different */
        content.iov_base = reshape<true>(ditto.capacity(), headroom,
                                         content.data(), content.length());
        ditto.release();
      }
      return *this;
    }

    MDBX_CXX20_CONSTEXPR void clear() { reshape<true>(0, 0, nullptr, 0); }
    MDBX_CXX20_CONSTEXPR void resize(size_t capacity, size_t headroom,
                                     slice &content) {
      content.iov_base =
          reshape<false>(capacity, headroom, content.iov_base, content.iov_len);
    }
    MDBX_CXX20_CONSTEXPR void swap(silo &ditto) noexcept(
        allocation_aware_details::swap_alloc<silo,
                                             allocator_type>::is_nothrow()) {
      allocation_aware_details::swap_alloc<silo, allocator_type>::propagate(
          this, ditto);
      ::std::swap(bin_, ditto.bin_);
    }

    /* MDBX_CXX20_CONSTEXPR void shrink_to_fit() { TODO } */

    MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX11_CONSTEXPR size_t
    capacity() const noexcept {
      return bin_.capacity();
    }
    MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX11_CONSTEXPR const void *
    data(size_t offset = 0) const noexcept {
      return get(offset);
    }
    MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX11_CONSTEXPR void *
    data(size_t offset = 0) noexcept {
      return get(offset);
    }
  };

  silo silo_;
  ::mdbx::slice slice_;

  void insulate() {
    assert(is_reference());
    silo_.assign(slice_.char_ptr(), slice_.length());
    slice_.iov_base = silo_.data();
  }

  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX20_CONSTEXPR const byte *
  silo_begin() const noexcept {
    return static_cast<const byte *>(silo_.data());
  }

  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX20_CONSTEXPR const byte *
  silo_end() const noexcept {
    return silo_begin() + silo_.capacity();
  }

  struct data_preserver : public exception_thunk {
    buffer data;
    data_preserver(allocator_type &allocator) : data(allocator) {}
    static int callback(void *context, MDBX_val *target, const void *src,
                        size_t bytes) noexcept {
      auto self = static_cast<data_preserver *>(context);
      assert(self->is_clean());
      assert(&self->data.slice_ == target);
      (void)target;
      try {
        self->data.assign(src, bytes, false);
        return MDBX_RESULT_FALSE;
      } catch (... /* capture any exception to rethrow it over C code */) {
        self->capture();
        return MDBX_RESULT_TRUE;
      }
    }
    MDBX_CXX11_CONSTEXPR operator MDBX_preserve_func() const noexcept {
      return callback;
    }
    MDBX_CXX11_CONSTEXPR operator const buffer &() const noexcept {
      return data;
    }
    MDBX_CXX11_CONSTEXPR operator buffer &() noexcept { return data; }
  };

public:
  /// \todo buffer& operator<<(buffer&, ...) for writing
  /// \todo buffer& operator>>(buffer&, ...) for reading (delegated to slice)
  /// \todo template<class X> key(X) for encoding keys while writing

  /// \brief Returns the associated allocator.
  MDBX_CXX20_CONSTEXPR allocator_type get_allocator() const {
    return silo_.get_allocator();
  }

  /// \brief Checks whether data chunk stored inside the buffer, otherwise
  /// buffer just refers to data located outside the buffer.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX20_CONSTEXPR bool
  is_freestanding() const noexcept {
    static_assert(size_t(-long(max_length)) > max_length, "WTF?");
    return size_t(byte_ptr() - silo_begin()) < silo_.capacity();
  }

  /// \brief Checks whether the buffer just refers to data located outside
  /// the buffer, rather than stores it.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX20_CONSTEXPR bool
  is_reference() const noexcept {
    return !is_freestanding();
  }

  /// \brief Returns the number of bytes that can be held in currently allocated
  /// storage.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX20_CONSTEXPR size_t
  capacity() const noexcept {
    return is_freestanding() ? silo_.capacity() : 0;
  }

  /// \brief Returns the number of bytes that available in currently allocated
  /// storage ahead the currently beginning of data.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX20_CONSTEXPR size_t
  headroom() const noexcept {
    return is_freestanding() ? slice_.byte_ptr() - silo_begin() : 0;
  }

  /// \brief Returns the number of bytes that available in currently allocated
  /// storage after the currently data end.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX20_CONSTEXPR size_t
  tailroom() const noexcept {
    return is_freestanding() ? capacity() - headroom() - slice_.length() : 0;
  }

  /// \brief Returns casted to const pointer to byte an address of data.
  MDBX_CXX11_CONSTEXPR const byte *byte_ptr() const noexcept {
    return slice_.byte_ptr();
  }

  /// \brief Returns casted to const pointer to byte an end of data.
  MDBX_CXX11_CONSTEXPR const byte *end_byte_ptr() const noexcept {
    return slice_.end_byte_ptr();
  }

  /// \brief Returns casted to pointer to byte an address of data.
  /// \pre REQUIRES: The buffer should store data chunk, but not referenced to
  /// an external one.
  MDBX_CXX11_CONSTEXPR byte *byte_ptr() noexcept {
    MDBX_CONSTEXPR_ASSERT(is_freestanding());
    return const_cast<byte *>(slice_.byte_ptr());
  }

  /// \brief Returns casted to pointer to byte an end of data.
  /// \pre REQUIRES: The buffer should store data chunk, but not referenced to
  /// an external one.
  MDBX_CXX11_CONSTEXPR byte *end_byte_ptr() noexcept {
    MDBX_CONSTEXPR_ASSERT(is_freestanding());
    return const_cast<byte *>(slice_.end_byte_ptr());
  }

  /// \brief Returns casted to const pointer to char an address of data.
  MDBX_CXX11_CONSTEXPR const char *char_ptr() const noexcept {
    return slice_.char_ptr();
  }

  /// \brief Returns casted to const pointer to char an end of data.
  MDBX_CXX11_CONSTEXPR const char *end_char_ptr() const noexcept {
    return slice_.end_char_ptr();
  }

  /// \brief Returns casted to pointer to char an address of data.
  /// \pre REQUIRES: The buffer should store data chunk, but not referenced to
  /// an external one.
  MDBX_CXX11_CONSTEXPR char *char_ptr() noexcept {
    MDBX_CONSTEXPR_ASSERT(is_freestanding());
    return const_cast<char *>(slice_.char_ptr());
  }

  /// \brief Returns casted to pointer to char an end of data.
  /// \pre REQUIRES: The buffer should store data chunk, but not referenced to
  /// an external one.
  MDBX_CXX11_CONSTEXPR char *end_char_ptr() noexcept {
    MDBX_CONSTEXPR_ASSERT(is_freestanding());
    return const_cast<char *>(slice_.end_char_ptr());
  }

  /// \brief Return a const pointer to the beginning of the referenced data.
  MDBX_CXX11_CONSTEXPR const void *data() const noexcept {
    return slice_.data();
  }

  /// \brief Return a const pointer to the end of the referenced data.
  MDBX_CXX11_CONSTEXPR const void *end() const noexcept { return slice_.end(); }

  /// \brief Return a pointer to the beginning of the referenced data.
  /// \pre REQUIRES: The buffer should store data chunk, but not referenced to
  /// an external one.
  MDBX_CXX11_CONSTEXPR void *data() noexcept {
    MDBX_CONSTEXPR_ASSERT(is_freestanding());
    return const_cast<void *>(slice_.data());
  }

  /// \brief Return a pointer to the end of the referenced data.
  /// \pre REQUIRES: The buffer should store data chunk, but not referenced to
  /// an external one.
  MDBX_CXX11_CONSTEXPR void *end() noexcept {
    MDBX_CONSTEXPR_ASSERT(is_freestanding());
    return const_cast<void *>(slice_.end());
  }

  /// \brief Returns the number of bytes.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR size_t
  length() const noexcept {
    return MDBX_CONSTEXPR_ASSERT(is_reference() ||
                                 slice_.length() + headroom() <=
                                     silo_.capacity()),
           slice_.length();
  }

  /// \brief Set length of data.
  MDBX_CXX14_CONSTEXPR buffer &set_length(size_t bytes) {
    MDBX_CONSTEXPR_ASSERT(is_reference() ||
                          bytes + headroom() <= silo_.capacity());
    slice_.set_length(bytes);
    return *this;
  }

  /// \brief Sets the length by specifying the end of the data.
  MDBX_CXX14_CONSTEXPR buffer &set_end(const void *ptr) {
    MDBX_CONSTEXPR_ASSERT(static_cast<const char *>(ptr) >= char_ptr());
    return set_length(static_cast<const char *>(ptr) - char_ptr());
  }

  /// \brief Makes buffer owning the data.
  /// \details If buffer refers to an external data, then makes it the owner
  /// of clone by allocating storage and copying the data.
  void make_freestanding() {
    if (is_reference())
      insulate();
  }

  MDBX_CXX20_CONSTEXPR buffer() noexcept = default;
  MDBX_CXX20_CONSTEXPR buffer(const allocator_type &allocator) noexcept
      : silo_(allocator) {}

  buffer(const struct slice &src, bool make_reference,
         const allocator_type &allocator = allocator_type())
      : silo_(allocator), slice_(src) {
    if (!make_reference)
      insulate();
  }

  buffer(const buffer &src, bool make_reference,
         const allocator_type &allocator = allocator_type())
      : buffer(src.slice_, make_reference, allocator) {}

  buffer(const void *ptr, size_t bytes, bool make_reference,
         const allocator_type &allocator = allocator_type())
      : buffer(::mdbx::slice(ptr, bytes), make_reference, allocator) {}

  template <class CHAR, class T, class A>
  buffer(const ::std::basic_string<CHAR, T, A> &) = delete;
  template <class CHAR, class T, class A>
  buffer(const ::std::basic_string<CHAR, T, A> &&) = delete;

  buffer(const char *c_str, bool make_reference,
         const allocator_type &allocator = allocator_type())
      : buffer(::mdbx::slice(c_str), make_reference, allocator) {}

#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L)
  template <class CHAR, class T>
  buffer(const ::std::basic_string_view<CHAR, T> &view, bool make_reference,
         const allocator_type &allocator = allocator_type())
      : buffer(::mdbx::slice(view), make_reference, allocator) {}
#endif /* __cpp_lib_string_view >= 201606L */

  MDBX_CXX20_CONSTEXPR
  buffer(const struct slice &src,
         const allocator_type &allocator = allocator_type())
      : silo_(src.data(), src.length(), allocator),
        slice_(silo_.data(), src.length()) {}

  MDBX_CXX20_CONSTEXPR
  buffer(const buffer &src, const allocator_type &allocator = allocator_type())
      : buffer(src.slice_, allocator) {}

  MDBX_CXX20_CONSTEXPR
  buffer(const void *ptr, size_t bytes,
         const allocator_type &allocator = allocator_type())
      : buffer(::mdbx::slice(ptr, bytes), allocator) {}

  template <class CHAR, class T, class A>
  MDBX_CXX20_CONSTEXPR
  buffer(const ::std::basic_string<CHAR, T, A> &str,
         const allocator_type &allocator = allocator_type())
      : buffer(::mdbx::slice(str), allocator) {}

  MDBX_CXX20_CONSTEXPR
  buffer(const char *c_str, const allocator_type &allocator = allocator_type())
      : buffer(::mdbx::slice(c_str), allocator) {}

#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L)
  template <class CHAR, class T>
  MDBX_CXX20_CONSTEXPR
  buffer(const ::std::basic_string_view<CHAR, T> &view,
         const allocator_type &allocator = allocator_type())
      : buffer(::mdbx::slice(view), allocator) {}
#endif /* __cpp_lib_string_view >= 201606L */

  buffer(size_t head_room, size_t tail_room,
         const allocator_type &allocator = allocator_type())
      : silo_(allocator) {
    slice_.iov_base = silo_.init(check_length(head_room, tail_room));
    assert(slice_.iov_len == 0);
  }

  buffer(size_t capacity, const allocator_type &allocator = allocator_type())
      : silo_(allocator) {
    slice_.iov_base = silo_.init(check_length(capacity));
    assert(slice_.iov_len == 0);
  }

  buffer(size_t head_room, const struct slice &src, size_t tail_room,
         const allocator_type &allocator = allocator_type())
      : silo_(allocator) {
    slice_.iov_base =
        silo_.init(check_length(head_room, src.length(), tail_room));
    slice_.iov_len = src.length();
    memcpy(slice_.iov_base, src.data(), src.length());
  }

  buffer(size_t head_room, const buffer &src, size_t tail_room,
         const allocator_type &allocator = allocator_type())
      : buffer(head_room, src.slice_, tail_room, allocator) {}

  inline buffer(const ::mdbx::txn &txn, const struct slice &src,
                const allocator_type &allocator = allocator_type());

  buffer(buffer &&src) noexcept(move_assign_alloc::is_nothrow())
      : silo_(::std::move(src.silo_)), slice_(::std::move(src.slice_)) {}

  MDBX_CXX11_CONSTEXPR const struct slice &slice() const noexcept {
    return slice_;
  }

  MDBX_CXX11_CONSTEXPR operator const struct slice &() const noexcept {
    return slice_;
  }

  template <typename POD>
  static buffer wrap(const POD &pod, bool make_reference = false,
                     const allocator_type &allocator = allocator_type()) {
    return buffer(::mdbx::slice::wrap(pod), make_reference, allocator);
  }

  /// \brief Reserves storage space.
  void reserve(size_t wanna_headroom, size_t wanna_tailroom) {
    wanna_headroom = ::std::min(::std::max(headroom(), wanna_headroom),
                                wanna_headroom + pettiness_threshold);
    wanna_tailroom = ::std::min(::std::max(tailroom(), wanna_tailroom),
                                wanna_tailroom + pettiness_threshold);
    const size_t wanna_capacity =
        check_length(wanna_headroom, slice_.length(), wanna_tailroom);
    silo_.resize(wanna_capacity, wanna_headroom, slice_);
    assert(headroom() >= wanna_headroom &&
           headroom() <= wanna_headroom + pettiness_threshold);
    assert(tailroom() >= wanna_tailroom &&
           tailroom() <= wanna_tailroom + pettiness_threshold);
  }

  /// \brief Reserves space before the payload.
  void reserve_headroom(size_t wanna_headroom) { reserve(wanna_headroom, 0); }

  /// \brief Reserves space after the payload.
  void reserve_tailroom(size_t wanna_tailroom) { reserve(0, wanna_tailroom); }

  buffer &assign_reference(const void *ptr, size_t bytes) {
    silo_.clear();
    slice_.assign(ptr, bytes);
    return *this;
  }

  buffer &assign_freestanding(const void *ptr, size_t bytes) {
    silo_.assign(static_cast<const typename silo::value_type *>(ptr),
                 check_length(bytes));
    slice_.assign(silo_.data(), bytes);
    return *this;
  }

  MDBX_CXX20_CONSTEXPR void
  swap(buffer &other) noexcept(swap_alloc::is_nothrow()) {
    silo_.swap(other.silo_);
    slice_.swap(other.slice_);
  }

  static buffer clone(const buffer &src,
                      const allocator_type &allocator = allocator_type()) {
    return buffer(src.headroom(), src.slice_, src.tailroom(), allocator);
  }

  buffer &assign(const buffer &src, bool make_reference = false) {
    return assign(src.slice_, make_reference);
  }

  buffer &assign(const void *ptr, size_t bytes, bool make_reference = false) {
    return make_reference ? assign_reference(ptr, bytes)
                          : assign_freestanding(ptr, bytes);
  }

  buffer &assign(const struct slice &src, bool make_reference = false) {
    return assign(src.data(), src.length(), make_reference);
  }

  buffer &assign(const ::MDBX_val &src, bool make_reference = false) {
    return assign(src.iov_base, src.iov_len, make_reference);
  }

  buffer &assign(struct slice &&src, bool make_reference = false) {
    assign(src.data(), src.length(), make_reference);
    src.invalidate();
    return *this;
  }

  buffer &assign(::MDBX_val &&src, bool make_reference = false) {
    assign(src.iov_base, src.iov_len, make_reference);
    src.iov_base = nullptr;
    return *this;
  }

  buffer &assign(const void *begin, const void *end,
                 bool make_reference = false) {
    return assign(begin,
                  static_cast<const byte *>(end) -
                      static_cast<const byte *>(begin),
                  make_reference);
  }

  template <class CHAR, class T, class A>
  buffer &assign(const ::std::basic_string<CHAR, T, A> &str,
                 bool make_reference = false) {
    return assign(str.data(), str.length(), make_reference);
  }

  buffer &assign(const char *c_str, bool make_reference = false) {
    return assign(c_str, ::mdbx::strlen(c_str), make_reference);
  }

#if defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L
  template <class CHAR, class T>
  buffer &assign(const ::std::basic_string_view<CHAR, T> &view,
                 bool make_reference = false) {
    return assign(view.data(), view.length(), make_reference);
  }

  template <class CHAR, class T>
  buffer &assign(::std::basic_string_view<CHAR, T> &&view,
                 bool make_reference = false) {
    assign(view.data(), view.length(), make_reference);
    view = {};
    return *this;
  }
#endif /* __cpp_lib_string_view >= 201606L */

  buffer &operator=(const buffer &src) { return assign(src); }

  buffer &operator=(buffer &&src) noexcept(move_assign_alloc::is_nothrow()) {
    return assign(::std::move(src));
  }

  buffer &operator=(const struct slice &src) { return assign(src); }

  buffer &operator=(struct slice &&src) { return assign(::std::move(src)); }

#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L)
  template <class CHAR, class T>
  buffer &operator=(const ::std::basic_string_view<CHAR, T> &view) noexcept {
    return assign(view);
  }

  /// \brief Return a string_view that references the data of this buffer.
  template <class CHAR = char, class T = ::std::char_traits<CHAR>>
  ::std::basic_string_view<CHAR, T> string_view() const noexcept {
    return slice_.string_view<CHAR, T>();
  }

  /// \brief Return a string_view that references the data of this buffer.
  template <class CHAR, class T>
  operator ::std::basic_string_view<CHAR, T>() const noexcept {
    return string_view<CHAR, T>();
  }
#endif /* __cpp_lib_string_view >= 201606L */

  /// \brief Checks whether the string is empty.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX20_CONSTEXPR bool empty() const noexcept {
    return length() == 0;
  }

  /// \brief Checks whether the data pointer of the buffer is nullptr.
  MDBX_CXX11_CONSTEXPR bool is_null() const noexcept {
    return data() == nullptr;
  }

  /// \brief Returns the number of bytes.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX20_CONSTEXPR size_t size() const noexcept {
    return length();
  }

  /// \brief Returns the hash value of the data.
  /// \attention Function implementation and returned hash values may changed
  /// version to version, and in future the t1ha3 will be used here. Therefore
  /// values obtained from this function shouldn't be persisted anywhere.
  MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR size_t
  hash_value() const noexcept {
    return slice_.hash_value();
  }

  template <class CHAR = char, class T = ::std::char_traits<CHAR>,
            class A = legacy_allocator>
  MDBX_CXX20_CONSTEXPR ::std::basic_string<CHAR, T, A>
  as_string(const A &allocator = A()) const {
    return slice_.as_string<CHAR, T, A>(allocator);
  }

  template <class CHAR, class T, class A>
  MDBX_CXX20_CONSTEXPR explicit
  operator ::std::basic_string<CHAR, T, A>() const {
    return as_string<CHAR, T, A>();
  }

  /// \brief Checks if the data starts with the given prefix.
  MDBX_NOTHROW_PURE_FUNCTION bool
  starts_with(const struct slice &prefix) const noexcept {
    return slice_.starts_with(prefix);
  }

  /// \brief Checks if the data ends with the given suffix.
  MDBX_NOTHROW_PURE_FUNCTION bool
  ends_with(const struct slice &suffix) const noexcept {
    return slice_.ends_with(suffix);
  }

  /// \brief Clears the contents and storage.
  void clear() noexcept {
    slice_.clear();
    silo_.clear();
  }

  /// \brief Reduces memory usage by freeing unused storage space.
  void shrink_to_fit() { reserve(0, 0); }

  /// \brief Drops the first "n" bytes from the data chunk.
  /// \pre REQUIRES: `n <= size()`
  void remove_prefix(size_t n) noexcept { slice_.remove_prefix(n); }

  /// \brief Drops the last "n" bytes from the data chunk.
  /// \pre REQUIRES: `n <= size()`
  void remove_suffix(size_t n) noexcept { slice_.remove_suffix(n); }

  /// \brief Drops the first "n" bytes from the data chunk.
  /// \throws std::out_of_range if `n > size()`
  void safe_remove_prefix(size_t n) { slice_.safe_remove_prefix(n); }

  /// \brief Drops the last "n" bytes from the data chunk.
  /// \throws std::out_of_range if `n > size()`
  void safe_remove_suffix(size_t n) { slice_.safe_remove_suffix(n); }

  /// \brief Accesses the specified byte of data chunk.
  /// \pre REQUIRES: `n < size()`
  MDBX_CXX11_CONSTEXPR byte operator[](size_t n) const noexcept {
    MDBX_CONSTEXPR_ASSERT(n < size());
    return slice_[n];
  }

  /// \brief Accesses the specified byte of data chunk.
  /// \pre REQUIRES: `n < size()`
  MDBX_CXX11_CONSTEXPR byte &operator[](size_t n) noexcept {
    MDBX_CONSTEXPR_ASSERT(n < size());
    return byte_ptr()[n];
  }

  /// \brief Accesses the specified byte of data chunk with bounds checking.
  /// \throws std::out_of_range if `n >= size()`
  MDBX_CXX14_CONSTEXPR byte at(size_t n) const { return slice_.at(n); }

  /// \brief Accesses the specified byte of data chunk with bounds checking.
  /// \throws std::out_of_range if `n >= size()`
  MDBX_CXX14_CONSTEXPR byte &at(size_t n) {
    if (MDBX_UNLIKELY(n >= size()))
      MDBX_CXX20_UNLIKELY throw_out_range();
    return byte_ptr()[n];
  }

  /// \brief Returns the first "n" bytes of the data chunk.
  /// \pre REQUIRES: `n <= size()`
  MDBX_CXX14_CONSTEXPR struct slice head(size_t n) const noexcept {
    return slice_.head(n);
  }

  /// \brief Returns the last "n" bytes of the data chunk.
  /// \pre REQUIRES: `n <= size()`
  MDBX_CXX14_CONSTEXPR struct slice tail(size_t n) const noexcept {
    return slice_.tail(n);
  }

  /// \brief Returns the middle "n" bytes of the data chunk.
  /// \pre REQUIRES: `from + n <= size()`
  MDBX_CXX14_CONSTEXPR struct slice middle(size_t from,
                                           size_t n) const noexcept {
    return slice_.middle(from, n);
  }

  /// \brief Returns the first "n" bytes of the data chunk.
  /// \throws std::out_of_range if `n >= size()`
  MDBX_CXX14_CONSTEXPR struct slice safe_head(size_t n) const {
    return slice_.safe_head(n);
  }

  /// \brief Returns the last "n" bytes of the data chunk.
  /// \throws std::out_of_range if `n >= size()`
  MDBX_CXX14_CONSTEXPR struct slice safe_tail(size_t n) const {
    return slice_.safe_tail(n);
  }

  /// \brief Returns the middle "n" bytes of the data chunk.
  /// \throws std::out_of_range if `from + n >= size()`
  MDBX_CXX14_CONSTEXPR struct slice safe_middle(size_t from, size_t n) const {
    return slice_.safe_middle(from, n);
  }

  buffer &append(const void *src, size_t bytes) {
    if (MDBX_UNLIKELY(tailroom() < check_length(bytes)))
      MDBX_CXX20_UNLIKELY reserve_tailroom(bytes);
    memcpy(slice_.byte_ptr() + size(), src, bytes);
    slice_.iov_len += bytes;
    return *this;
  }

  buffer &append(const struct slice &chunk) {
    return append(chunk.data(), chunk.size());
  }

  buffer &add_header(const void *src, size_t bytes) {
    if (MDBX_UNLIKELY(headroom() < check_length(bytes)))
      MDBX_CXX20_UNLIKELY reserve_headroom(bytes);
    slice_.iov_base =
        memcpy(static_cast<char *>(slice_.iov_base) - bytes, src, bytes);
    slice_.iov_len += bytes;
    return *this;
  }

  buffer &add_header(const struct slice &chunk) {
    return add_header(chunk.data(), chunk.size());
  }

  template <MDBX_CXX20_CONCEPT(MutableByteProducer, PRODUCER)>
  buffer &append_producer(PRODUCER &producer) {
    const size_t wanna_bytes = producer.envisage_result_length();
    if (MDBX_UNLIKELY(tailroom() < check_length(wanna_bytes)))
      MDBX_CXX20_UNLIKELY reserve_tailroom(wanna_bytes);
    return set_end(producer.write_bytes(end_char_ptr(), tailroom()));
  }

  template <MDBX_CXX20_CONCEPT(ImmutableByteProducer, PRODUCER)>
  buffer &append_producer(const PRODUCER &producer) {
    const size_t wanna_bytes = producer.envisage_result_length();
    if (MDBX_UNLIKELY(tailroom() < check_length(wanna_bytes)))
      MDBX_CXX20_UNLIKELY reserve_tailroom(wanna_bytes);
    return set_end(producer.write_bytes(end_char_ptr(), tailroom()));
  }

  buffer &append_hex(const struct slice &data, bool uppercase = false,
                     unsigned wrap_width = 0) {
    return append_producer(to_hex(data, uppercase, wrap_width));
  }

  buffer &append_base58(const struct slice &data, unsigned wrap_width = 0) {
    return append_producer(to_base58(data, wrap_width));
  }

  buffer &append_base64(const struct slice &data, unsigned wrap_width = 0) {
    return append_producer(to_base64(data, wrap_width));
  }

  buffer &append_decoded_hex(const struct slice &data,
                             bool ignore_spaces = false) {
    return append_producer(from_hex(data, ignore_spaces));
  }

  buffer &append_decoded_base58(const struct slice &data,
                                bool ignore_spaces = false) {
    return append_producer(from_base58(data, ignore_spaces));
  }

  buffer &append_decoded_base64(const struct slice &data,
                                bool ignore_spaces = false) {
    return append_producer(from_base64(data, ignore_spaces));
  }

  //----------------------------------------------------------------------------

  template <size_t SIZE>
  static buffer key_from(const char (&text)[SIZE], bool make_reference = true) {
    return buffer(::mdbx::slice(text), make_reference);
  }

#if defined(DOXYGEN) ||                                                        \
    (defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L)
  template <class CHAR, class T>
  static buffer key_from(const ::std::basic_string_view<CHAR, T> &src,
                         bool make_reference = false) {
    return buffer(src, make_reference);
  }
#endif /* __cpp_lib_string_view >= 201606L */

  static buffer key_from(const char *src, bool make_reference = false) {
    return buffer(src, make_reference);
  }

  template <class CHAR, class T, class A>
  static buffer key_from(const ::std::basic_string<CHAR, T, A> &src,
                         bool make_reference = false) {
    return buffer(src, make_reference);
  }

  static buffer key_from(silo &&src) noexcept {
    return buffer(::std::move(src));
  }

  static buffer key_from(const double ieee754_64bit) {
    return wrap(::mdbx_key_from_double(ieee754_64bit));
  }

  static buffer key_from(const double *ieee754_64bit) {
    return wrap(::mdbx_key_from_ptrdouble(ieee754_64bit));
  }

  static buffer key_from(const uint64_t unsigned_int64) {
    return wrap(unsigned_int64);
  }

  static buffer key_from(const int64_t signed_int64) {
    return wrap(::mdbx_key_from_int64(signed_int64));
  }

  static buffer key_from_jsonInteger(const int64_t json_integer) {
    return wrap(::mdbx_key_from_jsonInteger(json_integer));
  }

  static buffer key_from(const float ieee754_32bit) {
    return wrap(::mdbx_key_from_float(ieee754_32bit));
  }

  static buffer key_from(const float *ieee754_32bit) {
    return wrap(::mdbx_key_from_ptrfloat(ieee754_32bit));
  }

  static buffer key_from(const uint32_t unsigned_int32) {
    return wrap(unsigned_int32);
  }

  static buffer key_from(const int32_t signed_int32) {
    return wrap(::mdbx_key_from_int32(signed_int32));
  }
};

template <class ALLOCATOR, class CAPACITY_POLICY,
          MDBX_CXX20_CONCEPT(MutableByteProducer, PRODUCER)>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
make_buffer(PRODUCER &producer, const ALLOCATOR &allocator) {
  if (MDBX_LIKELY(!producer.is_empty()))
    MDBX_CXX20_LIKELY {
      buffer<ALLOCATOR, CAPACITY_POLICY> result(
          producer.envisage_result_length(), allocator);
      result.set_end(
          producer.write_bytes(result.end_char_ptr(), result.tailroom()));
      return result;
    }
  return buffer<ALLOCATOR, CAPACITY_POLICY>(allocator);
}

template <class ALLOCATOR, class CAPACITY_POLICY,
          MDBX_CXX20_CONCEPT(ImmutableByteProducer, PRODUCER)>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
make_buffer(const PRODUCER &producer, const ALLOCATOR &allocator) {
  if (MDBX_LIKELY(!producer.is_empty()))
    MDBX_CXX20_LIKELY {
      buffer<ALLOCATOR, CAPACITY_POLICY> result(
          producer.envisage_result_length(), allocator);
      result.set_end(
          producer.write_bytes(result.end_char_ptr(), result.tailroom()));
      return result;
    }
  return buffer<ALLOCATOR, CAPACITY_POLICY>(allocator);
}

template <class ALLOCATOR, MDBX_CXX20_CONCEPT(MutableByteProducer, PRODUCER)>
inline string<ALLOCATOR> make_string(PRODUCER &producer,
                                     const ALLOCATOR &allocator) {
  string<ALLOCATOR> result(allocator);
  if (MDBX_LIKELY(!producer.is_empty()))
    MDBX_CXX20_LIKELY {
      result.resize(producer.envisage_result_length());
      result.resize(producer.write_bytes(const_cast<char *>(result.data()),
                                         result.capacity()) -
                    result.data());
    }
  return result;
}

template <class ALLOCATOR, MDBX_CXX20_CONCEPT(ImmutableByteProducer, PRODUCER)>
inline string<ALLOCATOR> make_string(const PRODUCER &producer,
                                     const ALLOCATOR &allocator) {
  string<ALLOCATOR> result(allocator);
  if (MDBX_LIKELY(!producer.is_empty()))
    MDBX_CXX20_LIKELY {
      result.resize(producer.envisage_result_length());
      result.resize(producer.write_bytes(const_cast<char *>(result.data()),
                                         result.capacity()) -
                    result.data());
    }
  return result;
}

/// \brief Combines data slice with boolean flag to represent result of certain
/// operations.
struct value_result {
  slice value;
  bool done;
  value_result(const slice &value, bool done) noexcept
      : value(value), done(done) {}
  value_result(const value_result &) noexcept = default;
  value_result &operator=(const value_result &) noexcept = default;
  MDBX_CXX14_CONSTEXPR operator bool() const noexcept {
    assert(!done || bool(value));
    return done;
  }
};

/// \brief Combines pair of slices for key and value to represent result of
/// certain operations.
struct pair {
  slice key, value;
  pair(const slice &key, const slice &value) noexcept
      : key(key), value(value) {}
  pair(const pair &) noexcept = default;
  pair &operator=(const pair &) noexcept = default;
  MDBX_CXX14_CONSTEXPR operator bool() const noexcept {
    assert(bool(key) == bool(value));
    return key;
  }
};

/// \brief Combines pair of slices for key and value with boolean flag to
/// represent result of certain operations.
struct pair_result : public pair {
  bool done;
  pair_result(const slice &key, const slice &value, bool done) noexcept
      : pair(key, value), done(done) {}
  pair_result(const pair_result &) noexcept = default;
  pair_result &operator=(const pair_result &) noexcept = default;
  MDBX_CXX14_CONSTEXPR operator bool() const noexcept {
    assert(!done || (bool(key) && bool(value)));
    return done;
  }
};

/// end of cxx_data @}

//------------------------------------------------------------------------------

/// \brief Loop control constants for readers enumeration functor and other
/// cases. \see env::enumerate_readers()
enum loop_control { continue_loop = 0, exit_loop = INT32_MIN };

/// \brief Kinds of the keys and corresponding modes of comparing it.
enum class key_mode {
  usual = MDBX_DB_DEFAULTS,  ///< Usual variable length keys with byte-by-byte
                             ///< lexicographic comparison like `std::memcmp()`.
  reverse = MDBX_REVERSEKEY, ///< Variable length keys with byte-by-byte
                             ///< lexicographic comparison in reverse order,
                             ///< from the end of the keys to the beginning.
  ordinal = MDBX_INTEGERKEY, ///< Keys are binary integers in native byte order,
                             ///< either `uint32_t` or `uint64_t`, and will be
                             ///< sorted as such. The keys must all be of the
                             ///< same size and must be aligned while passing
                             ///< as arguments.
  msgpack = -1 ///< Keys are in [MessagePack](https://msgpack.org/)
               ///< format with appropriate comparison.
               ///< \note Not yet implemented and PRs are welcome.
};

/// \brief Kind of the values and sorted multi-values with corresponding
/// comparison.
enum class value_mode {
  single = MDBX_DB_DEFAULTS, ///< Usual single value for each key. In terms of
                             ///< keys, they are unique.
  multi =
      MDBX_DUPSORT, ///< A more than one data value could be associated with
                    ///< each key. Internally each key is stored once, and the
                    ///< corresponding data values are sorted by byte-by-byte
                    ///< lexicographic comparison like `std::memcmp()`.
                    ///< In terms of keys, they are not unique, i.e. has
                    ///< duplicates which are sorted by associated data values.
#if CONSTEXPR_ENUM_FLAGS_OPERATIONS || defined(DOXYGEN)
  multi_reverse =
      MDBX_DUPSORT |
      MDBX_REVERSEDUP, ///< A more than one data value could be associated with
                       ///< each key. Internally each key is stored once, and
                       ///< the corresponding data values are sorted by
                       ///< byte-by-byte lexicographic comparison in reverse
                       ///< order, from the end of the keys to the beginning.
                       ///< In terms of keys, they are not unique, i.e. has
                       ///< duplicates which are sorted by associated data
                       ///< values.
  multi_samelength =
      MDBX_DUPSORT |
      MDBX_DUPFIXED, ///< A more than one data value could be associated with
                     ///< each key, and all data values must be same length.
                     ///< Internally each key is stored once, and the
                     ///< corresponding data values are sorted by byte-by-byte
                     ///< lexicographic comparison like `std::memcmp()`. In
                     ///< terms of keys, they are not unique, i.e. has
                     ///< duplicates which are sorted by associated data values.
  multi_ordinal =
      MDBX_DUPSORT | MDBX_DUPFIXED |
      MDBX_INTEGERDUP, ///< A more than one data value could be associated with
                       ///< each key, and all data values are binary integers in
                       ///< native byte order, either `uint32_t` or `uint64_t`,
                       ///< and will be sorted as such. Internally each key is
                       ///< stored once, and the corresponding data values are
                       ///< sorted. In terms of keys, they are not unique, i.e.
                       ///< has duplicates which are sorted by associated data
                       ///< values.
  multi_reverse_samelength =
      MDBX_DUPSORT | MDBX_REVERSEDUP |
      MDBX_DUPFIXED, ///< A more than one data value could be associated with
                     ///< each key, and all data values must be same length.
                     ///< Internally each key is stored once, and the
                     ///< corresponding data values are sorted by byte-by-byte
                     ///< lexicographic comparison in reverse order, from the
                     ///< end of the keys to the beginning. In terms of keys,
                     ///< they are not unique, i.e. has duplicates which are
                     ///< sorted by associated data values.
  msgpack = -1 ///< A more than one data value could be associated with each
               ///< key. Values are in [MessagePack](https://msgpack.org/)
               ///< format with appropriate comparison. Internally each key is
               ///< stored once, and the corresponding data values are sorted.
               ///< In terms of keys, they are not unique, i.e. has duplicates
               ///< which are sorted by associated data values.
               ///< \note Not yet implemented and PRs are welcome.
#else
  multi_reverse = uint32_t(MDBX_DUPSORT) | uint32_t(MDBX_REVERSEDUP),
  multi_samelength = uint32_t(MDBX_DUPSORT) | uint32_t(MDBX_DUPFIXED),
  multi_ordinal = uint32_t(MDBX_DUPSORT) | uint32_t(MDBX_DUPFIXED) |
                  uint32_t(MDBX_INTEGERDUP),
  multi_reverse_samelength = uint32_t(MDBX_DUPSORT) |
                             uint32_t(MDBX_REVERSEDUP) | uint32_t(MDBX_DUPFIXED)
#endif
};

/// \brief A handle for an individual database (key-value spaces) in the
/// environment.
/// \see txn::open_map() \see txn::create_map()
/// \see txn::clear_map() \see txn::drop_map()
/// \see txn::get_handle_info() \see txn::get_map_stat()
/// \see env::close_map()
/// \see cursor::map()
struct LIBMDBX_API_TYPE map_handle {
  MDBX_dbi dbi{0};
  MDBX_CXX11_CONSTEXPR map_handle() noexcept {}
  MDBX_CXX11_CONSTEXPR map_handle(MDBX_dbi dbi) noexcept : dbi(dbi) {}
  map_handle(const map_handle &) noexcept = default;
  map_handle &operator=(const map_handle &) noexcept = default;
  operator bool() const noexcept { return dbi != 0; }

  using flags = ::MDBX_db_flags_t;
  using state = ::MDBX_dbi_state_t;
  struct LIBMDBX_API_TYPE info {
    map_handle::flags flags;
    map_handle::state state;
    MDBX_CXX11_CONSTEXPR info(map_handle::flags flags,
                              map_handle::state state) noexcept;
    info(const info &) noexcept = default;
    info &operator=(const info &) noexcept = default;
#if CONSTEXPR_ENUM_FLAGS_OPERATIONS
    MDBX_CXX11_CONSTEXPR
#else
    inline
#endif
    ::mdbx::key_mode key_mode() const noexcept;
#if CONSTEXPR_ENUM_FLAGS_OPERATIONS
    MDBX_CXX11_CONSTEXPR
#else
    inline
#endif
    ::mdbx::value_mode value_mode() const noexcept;
  };
};

/// \brief Key-value pairs put mode.
enum put_mode {
  insert_unique = MDBX_NOOVERWRITE, ///< Insert only unique keys.
  upsert = MDBX_UPSERT,             ///< Insert or update.
  update = MDBX_CURRENT,            ///< Update existing, don't insert new.
};

/// \brief Unmanaged database environment.
///
/// Like other unmanaged classes, `env` allows copying and assignment for
/// instances, but does not destroys the represented underlying object from the
/// own class destructor.
///
/// An environment supports multiple key-value sub-databases (aka key-value
/// spaces or tables), all residing in the same shared-memory map.
class LIBMDBX_API_TYPE env {
  friend class txn;

protected:
  MDBX_env *handle_{nullptr};
  MDBX_CXX11_CONSTEXPR env(MDBX_env *ptr) noexcept;

public:
  MDBX_CXX11_CONSTEXPR env() noexcept = default;
  env(const env &) noexcept = default;
  inline env &operator=(env &&other) noexcept;
  inline env(env &&other) noexcept;
  inline ~env() noexcept;

  MDBX_CXX14_CONSTEXPR operator bool() const noexcept;
  MDBX_CXX14_CONSTEXPR operator const MDBX_env *() const;
  MDBX_CXX14_CONSTEXPR operator MDBX_env *();
  friend MDBX_CXX11_CONSTEXPR bool operator==(const env &a,
                                              const env &b) noexcept;
  friend MDBX_CXX11_CONSTEXPR bool operator!=(const env &a,
                                              const env &b) noexcept;

  //----------------------------------------------------------------------------

  /// Database geometry for size management.
  struct LIBMDBX_API_TYPE geometry {
    enum : int64_t {
      default_value = -1,         ///< Means "keep current or use default"
      minimal_value = 0,          ///< Means "minimal acceptable"
      maximal_value = INTPTR_MAX, ///< Means "maximal acceptable"
      kB = 1000,                  ///< \f$10^{3}\f$ bytes
      MB = kB * 1000,             ///< \f$10^{6}\f$ bytes
      GB = MB * 1000,             ///< \f$10^{9}\f$ bytes
      TB = GB * 1000,             ///< \f$10^{12}\f$ bytes
      PB = TB * 1000,             ///< \f$10^{15}\f$ bytes
      EB = PB * 1000,             ///< \f$10^{18}\f$ bytes
      KiB = 1024,                 ///< \f$2^{10}\f$ bytes
      MiB = KiB << 10,            ///< \f$2^{20}\f$ bytes
      GiB = MiB << 10,            ///< \f$2^{30}\f$ bytes
      TiB = GiB << 10,            ///< \f$2^{40}\f$ bytes
      PiB = TiB << 10,            ///< \f$2^{50}\f$ bytes
      EiB = PiB << 10,            ///< \f$2^{60}\f$ bytes
    };

    /// \brief Tagged type for output to std::ostream
    struct size {
      intptr_t bytes;
      MDBX_CXX11_CONSTEXPR size(intptr_t bytes) noexcept : bytes(bytes) {}
      MDBX_CXX11_CONSTEXPR operator intptr_t() const noexcept { return bytes; }
    };

    /// \brief The lower bound of database size in bytes.
    intptr_t size_lower{minimal_value};

    /// \brief The size in bytes to setup the database size for now.
    /// \details It is recommended always pass \ref default_value in this
    /// argument except some special cases.
    intptr_t size_now{default_value};

    /// \brief The upper bound of database size in bytes.
    /// \details It is recommended to avoid change upper bound while database is
    /// used by other processes or threaded (i.e. just pass \ref default_value
    /// in this argument except absolutely necessary). Otherwise you must be
    /// ready for \ref MDBX_UNABLE_EXTEND_MAPSIZE error(s), unexpected pauses
    /// during remapping and/or system errors like "address busy", and so on. In
    /// other words, there is no way to handle a growth of the upper bound
    /// robustly because there may be a lack of appropriate system resources
    /// (which are extremely volatile in a multi-process multi-threaded
    /// environment).
    intptr_t size_upper{maximal_value};

    /// \brief The growth step in bytes, must be greater than zero to allow the
    /// database to grow.
    intptr_t growth_step{default_value};

    /// \brief The shrink threshold in bytes, must be greater than zero to allow
    /// the database to shrink.
    intptr_t shrink_threshold{default_value};

    /// \brief The database page size for new database creation
    /// or \ref default_value otherwise.
    /// \details Must be power of 2 in the range between \ref MDBX_MIN_PAGESIZE
    /// and \ref MDBX_MAX_PAGESIZE.
    intptr_t pagesize{default_value};

    inline geometry &make_fixed(intptr_t size) noexcept;
    inline geometry &make_dynamic(intptr_t lower = minimal_value,
                                  intptr_t upper = maximal_value) noexcept;
    MDBX_CXX11_CONSTEXPR geometry() noexcept {}
    MDBX_CXX11_CONSTEXPR
    geometry(const geometry &) noexcept = default;
    MDBX_CXX11_CONSTEXPR geometry(intptr_t size_lower,
                                  intptr_t size_now = default_value,
                                  intptr_t size_upper = maximal_value,
                                  intptr_t growth_step = default_value,
                                  intptr_t shrink_threshold = default_value,
                                  intptr_t pagesize = default_value) noexcept
        : size_lower(size_lower), size_now(size_now), size_upper(size_upper),
          growth_step(growth_step), shrink_threshold(shrink_threshold),
          pagesize(pagesize) {}
  };

  /// \brief Operation mode.
  enum mode {
    readonly,       ///< \copydoc MDBX_RDONLY
    write_file_io,  // don't available on OpenBSD
    write_mapped_io ///< \copydoc MDBX_WRITEMAP
  };

  /// \brief Durability level.
  enum durability {
    robust_synchronous,         ///< \copydoc MDBX_SYNC_DURABLE
    half_synchronous_weak_last, ///< \copydoc MDBX_NOMETASYNC
    lazy_weak_tail,             ///< \copydoc MDBX_SAFE_NOSYNC
    whole_fragile               ///< \copydoc MDBX_UTTERLY_NOSYNC
  };

  /// \brief Garbage reclaiming options.
  struct LIBMDBX_API_TYPE reclaiming_options {
    /// \copydoc MDBX_LIFORECLAIM
    bool lifo{false};
    /// \copydoc MDBX_COALESCE
    bool coalesce{false};
    MDBX_CXX11_CONSTEXPR reclaiming_options() noexcept {}
    MDBX_CXX11_CONSTEXPR
    reclaiming_options(const reclaiming_options &) noexcept = default;
    MDBX_CXX14_CONSTEXPR reclaiming_options &
    operator=(const reclaiming_options &) noexcept = default;
    reclaiming_options(MDBX_env_flags_t) noexcept;
  };

  /// \brief Operate options.
  struct LIBMDBX_API_TYPE operate_options {
    /// \copydoc MDBX_NOTLS
    bool orphan_read_transactions{false};
    bool nested_write_transactions{false};
    /// \copydoc MDBX_EXCLUSIVE
    bool exclusive{false};
    /// \copydoc MDBX_NORDAHEAD
    bool disable_readahead{false};
    /// \copydoc MDBX_NOMEMINIT
    bool disable_clear_memory{false};
    MDBX_CXX11_CONSTEXPR operate_options() noexcept {}
    MDBX_CXX11_CONSTEXPR
    operate_options(const operate_options &) noexcept = default;
    MDBX_CXX14_CONSTEXPR operate_options &
    operator=(const operate_options &) noexcept = default;
    operate_options(MDBX_env_flags_t) noexcept;
  };

  /// \brief Operate parameters.
  struct LIBMDBX_API_TYPE operate_parameters {
    /// \brief The maximum number of named databases for the environment.
    /// Zero means default value.
    unsigned max_maps{0};
    /// \brief The maximum number of threads/reader slots for the environment.
    /// Zero means default value.
    unsigned max_readers{0};
    env::mode mode{write_mapped_io};
    env::durability durability{robust_synchronous};
    env::reclaiming_options reclaiming;
    env::operate_options options;

    MDBX_CXX11_CONSTEXPR operate_parameters() noexcept {}
    MDBX_CXX11_CONSTEXPR
    operate_parameters(
        const unsigned max_maps, const unsigned max_readers = 0,
        const env::mode mode = env::mode::write_mapped_io,
        env::durability durability = env::durability::robust_synchronous,
        const env::reclaiming_options &reclaiming = env::reclaiming_options(),
        const env::operate_options &options = env::operate_options()) noexcept
        : max_maps(max_maps), max_readers(max_readers), mode(mode),
          durability(durability), reclaiming(reclaiming), options(options) {}
    MDBX_CXX11_CONSTEXPR
    operate_parameters(const operate_parameters &) noexcept = default;
    MDBX_CXX14_CONSTEXPR operate_parameters &
    operator=(const operate_parameters &) noexcept = default;
    MDBX_env_flags_t make_flags(
        bool accede = true, ///< Allows accepting incompatible operating options
                            ///< in case the database is already being used by
                            ///< another process(es) \see MDBX_ACCEDE
        bool use_subdirectory =
            false ///< use subdirectory to place the DB files
    ) const;
    static env::mode mode_from_flags(MDBX_env_flags_t) noexcept;
    static env::durability durability_from_flags(MDBX_env_flags_t) noexcept;
    inline static env::reclaiming_options
    reclaiming_from_flags(MDBX_env_flags_t flags) noexcept;
    inline static env::operate_options
    options_from_flags(MDBX_env_flags_t flags) noexcept;
  };

  /// \brief Returns current operation parameters.
  inline env::operate_parameters get_operation_parameters() const;
  /// \brief Returns current operation mode.
  inline env::mode get_mode() const;
  /// \brief Returns current durability mode.
  inline env::durability get_durability() const;
  /// \brief Returns current reclaiming options.
  inline env::reclaiming_options get_reclaiming() const;
  /// \brief Returns current operate options.
  inline env::operate_options get_options() const;

  /// \brief Returns `true` for a freshly created database,
  /// but `false` if at least one transaction was committed.
  bool is_pristine() const;

  /// \brief Checks whether the database is empty.
  bool is_empty() const;

  /// \brief Returns default page size for current system/platform.
  static size_t default_pagesize() noexcept {
    return ::mdbx_default_pagesize();
  }

  struct limits {
    limits() = delete;
    /// \brief Returns the minimal database page size in bytes.
    static inline size_t pagesize_min() noexcept;
    /// \brief Returns the maximal database page size in bytes.
    static inline size_t pagesize_max() noexcept;
    /// \brief Returns the minimal database size in bytes for specified page
    /// size.
    static inline size_t dbsize_min(intptr_t pagesize);
    /// \brief Returns the maximal database size in bytes for specified page
    /// size.
    static inline size_t dbsize_max(intptr_t pagesize);
    /// \brief Returns the minimal key size in bytes for specified database
    /// flags.
    static inline size_t key_min(MDBX_db_flags_t flags) noexcept;
    /// \brief Returns the minimal key size in bytes for specified keys mode.
    static inline size_t key_min(key_mode mode) noexcept;
    /// \brief Returns the maximal key size in bytes for specified page size and
    /// database flags.
    static inline size_t key_max(intptr_t pagesize, MDBX_db_flags_t flags);
    /// \brief Returns the maximal key size in bytes for specified page size and
    /// keys mode.
    static inline size_t key_max(intptr_t pagesize, key_mode mode);
    /// \brief Returns the maximal key size in bytes for given environment and
    /// database flags.
    static inline size_t key_max(const env &, MDBX_db_flags_t flags);
    /// \brief Returns the maximal key size in bytes for given environment and
    /// keys mode.
    static inline size_t key_max(const env &, key_mode mode);
    /// \brief Returns the minimal values size in bytes for specified database
    /// flags.
    static inline size_t value_min(MDBX_db_flags_t flags) noexcept;
    /// \brief Returns the minimal values size in bytes for specified values
    /// mode.
    static inline size_t value_min(value_mode) noexcept;

    /// \brief Returns the maximal value size in bytes for specified page size
    /// and database flags.
    static inline size_t value_max(intptr_t pagesize, MDBX_db_flags_t flags);
    /// \brief Returns the maximal value size in bytes for specified page size
    /// and values mode.
    static inline size_t value_max(intptr_t pagesize, value_mode);
    /// \brief Returns the maximal value size in bytes for given environment and
    /// database flags.
    static inline size_t value_max(const env &, MDBX_db_flags_t flags);
    /// \brief Returns the maximal value size in bytes for specified page size
    /// and values mode.
    static inline size_t value_max(const env &, value_mode);

    /// \brief Returns maximal size of key-value pair to fit in a single page
    /// for specified size and database flags.
    static inline size_t pairsize4page_max(intptr_t pagesize,
                                           MDBX_db_flags_t flags);
    /// \brief Returns maximal size of key-value pair to fit in a single page
    /// for specified page size and values mode.
    static inline size_t pairsize4page_max(intptr_t pagesize, value_mode);
    /// \brief Returns maximal size of key-value pair to fit in a single page
    /// for given environment and database flags.
    static inline size_t pairsize4page_max(const env &, MDBX_db_flags_t flags);
    /// \brief Returns maximal size of key-value pair to fit in a single page
    /// for specified page size and values mode.
    static inline size_t pairsize4page_max(const env &, value_mode);

    /// \brief Returns maximal data size in bytes to fit in a leaf-page or
    /// single overflow/large-page for specified size and database flags.
    static inline size_t valsize4page_max(intptr_t pagesize,
                                          MDBX_db_flags_t flags);
    /// \brief Returns maximal data size in bytes to fit in a leaf-page or
    /// single overflow/large-page for specified page size and values mode.
    static inline size_t valsize4page_max(intptr_t pagesize, value_mode);
    /// \brief Returns maximal data size in bytes to fit in a leaf-page or
    /// single overflow/large-page for given environment and database flags.
    static inline size_t valsize4page_max(const env &, MDBX_db_flags_t flags);
    /// \brief Returns maximal data size in bytes to fit in a leaf-page or
    /// single overflow/large-page for specified page size and values mode.
    static inline size_t valsize4page_max(const env &, value_mode);

    /// \brief Returns the maximal write transaction size (i.e. limit for
    /// summary volume of dirty pages) in bytes for specified page size.
    static inline size_t transaction_size_max(intptr_t pagesize);
  };

  /// \brief Returns the minimal database size in bytes for the environment.
  size_t dbsize_min() const { return limits::dbsize_min(this->get_pagesize()); }
  /// \brief Returns the maximal database size in bytes for the environment.
  size_t dbsize_max() const { return limits::dbsize_max(this->get_pagesize()); }
  /// \brief Returns the minimal key size in bytes for specified keys mode.
  size_t key_min(key_mode mode) const noexcept { return limits::key_min(mode); }
  /// \brief Returns the maximal key size in bytes for specified keys mode.
  size_t key_max(key_mode mode) const { return limits::key_max(*this, mode); }
  /// \brief Returns the minimal value size in bytes for specified values mode.
  size_t value_min(value_mode mode) const noexcept {
    return limits::value_min(mode);
  }
  /// \brief Returns the maximal value size in bytes for specified values mode.
  size_t value_max(value_mode mode) const {
    return limits::value_max(*this, mode);
  }
  /// \brief Returns the maximal write transaction size (i.e. limit for summary
  /// volume of dirty pages) in bytes.
  size_t transaction_size_max() const {
    return limits::transaction_size_max(this->get_pagesize());
  }

  /// \brief Make a copy (backup) of an existing environment to the specified
  /// path.
#ifdef MDBX_STD_FILESYSTEM_PATH
  env &copy(const MDBX_STD_FILESYSTEM_PATH &destination, bool compactify,
            bool force_dynamic_size = false);
#endif /* MDBX_STD_FILESYSTEM_PATH */
#if defined(_WIN32) || defined(_WIN64) || defined(DOXYGEN)
  env &copy(const ::std::wstring &destination, bool compactify,
            bool force_dynamic_size = false);
  env &copy(const wchar_t *destination, bool compactify,
            bool force_dynamic_size = false);
#endif /* Windows */
  env &copy(const ::std::string &destination, bool compactify,
            bool force_dynamic_size = false);
  env &copy(const char *destination, bool compactify,
            bool force_dynamic_size = false);

  /// \brief Copy an environment to the specified file descriptor.
  env &copy(filehandle fd, bool compactify, bool force_dynamic_size = false);

  /// \brief Deletion modes for \ref remove().
  enum remove_mode {
    /// \brief Just delete the environment's files and directory if any.
    /// \note On POSIX systems, processes already working with the database will
    /// continue to work without interference until it close the environment.
    /// \note On Windows, the behavior of `just_remove` is different
    /// because the system does not support deleting files that are currently
    /// memory mapped.
    just_remove = MDBX_ENV_JUST_DELETE,
    /// \brief Make sure that the environment is not being used by other
    /// processes, or return an error otherwise.
    ensure_unused = MDBX_ENV_ENSURE_UNUSED,
    /// \brief Wait until other processes closes the environment before
    /// deletion.
    wait_for_unused = MDBX_ENV_WAIT_FOR_UNUSED
  };

  /// \brief Removes the environment's files in a proper and multiprocess-safe
  /// way.
#ifdef MDBX_STD_FILESYSTEM_PATH
  static bool remove(const MDBX_STD_FILESYSTEM_PATH &pathname,
                     const remove_mode mode = just_remove);
#endif /* MDBX_STD_FILESYSTEM_PATH */
#if defined(_WIN32) || defined(_WIN64) || defined(DOXYGEN)
  static bool remove(const ::std::wstring &pathname,
                     const remove_mode mode = just_remove);
  static bool remove(const wchar_t *pathname,
                     const remove_mode mode = just_remove);
#endif /* Windows */
  static bool remove(const ::std::string &pathname,
                     const remove_mode mode = just_remove);
  static bool remove(const char *pathname,
                     const remove_mode mode = just_remove);

  /// \brief Statistics for a database in the MDBX environment.
  using stat = ::MDBX_stat;

  /// \brief Information about the environment.
  using info = ::MDBX_envinfo;

  /// \brief Returns snapshot statistics about the MDBX environment.
  inline stat get_stat() const;

  /// \brief Returns pagesize of this MDBX environment.
  size_t get_pagesize() const { return get_stat().ms_psize; }

  /// \brief Return snapshot information about the MDBX environment.
  inline info get_info() const;

  /// \brief Return statistics about the MDBX environment accordingly to the
  /// specified transaction.
  inline stat get_stat(const txn &) const;

  /// \brief Return information about the MDBX environment accordingly to the
  /// specified transaction.
  inline info get_info(const txn &) const;

  /// \brief Returns the file descriptor for the DXB file of MDBX environment.
  inline filehandle get_filehandle() const;

  /// \brief Return the path that was used for opening the environment.
  path get_path() const;

  /// Returns environment flags.
  inline MDBX_env_flags_t get_flags() const;

  /// \brief Returns the maximum number of threads/reader slots for the
  /// environment.
  inline unsigned max_readers() const;

  /// \brief Returns the maximum number of named databases for the environment.
  inline unsigned max_maps() const;

  /// \brief Returns the application context associated with the environment.
  inline void *get_context() const noexcept;

  /// \brief Sets the application context associated with the environment.
  inline env &set_context(void *);

  /// \brief Sets threshold to force flush the data buffers to disk, for
  /// non-sync durability modes.
  ///
  /// The threshold value affects all processes which operates with given
  /// environment until the last process close environment or a new value will
  /// be settled.
  /// Data is always written to disk when \ref txn_managed::commit() is called,
  /// but the operating system may keep it buffered. MDBX always flushes the OS
  /// buffers upon commit as well, unless the environment was opened with \ref
  /// whole_fragile, \ref lazy_weak_tail or in part \ref
  /// half_synchronous_weak_last. The default is 0, than mean no any threshold
  /// checked, and no additional flush will be made.
  ///
  inline env &set_sync_threshold(size_t bytes);

  /// \brief Sets relative period since the last unsteady commit to force flush
  /// the data buffers to disk, for non-sync durability modes.
  ///
  /// The relative period value affects all processes which operates with given
  /// environment until the last process close environment or a new value will
  /// be settled.
  /// Data is always written to disk when \ref txn_managed::commit() is called,
  /// but the operating system may keep it buffered. MDBX always flushes the OS
  /// buffers upon commit as well, unless the environment was opened with \ref
  /// whole_fragile, \ref lazy_weak_tail or in part \ref
  /// half_synchronous_weak_last. Settled period don't checked asynchronously,
  /// but only by the \ref txn_managed::commit() and \ref env::sync_to_disk()
  /// functions. Therefore, in cases where transactions are committed
  /// infrequently and/or irregularly, polling by \ref env::poll_sync_to_disk()
  /// may be a reasonable solution to timeout enforcement. The default is 0,
  /// than mean no any timeout checked, and no additional flush will be made.
  ///
  /// \param [in] seconds_16dot16  The period in 1/65536 of second when a
  /// synchronous flush would be made since the last unsteady commit.
  inline env &set_sync_period(unsigned seconds_16dot16);

  /// \brief Sets relative period since the last unsteady commit to force flush
  /// the data buffers to disk, for non-sync durability modes.
  ///
  /// The relative period value affects all processes which operates with given
  /// environment until the last process close environment or a new value will
  /// be settled.
  /// Data is always written to disk when \ref txn_managed::commit() is called,
  /// but the operating system may keep it buffered. MDBX always flushes the OS
  /// buffers upon commit as well, unless the environment was opened with \ref
  /// whole_fragile, \ref lazy_weak_tail or in part \ref
  /// half_synchronous_weak_last. Settled period don't checked asynchronously,
  /// but only by the \ref txn_managed::commit() and \ref env::sync_to_disk()
  /// functions. Therefore, in cases where transactions are committed
  /// infrequently and/or irregularly, polling by \ref env::poll_sync_to_disk()
  /// may be a reasonable solution to timeout enforcement. The default is 0,
  /// than mean no any timeout checked, and no additional flush will be made.
  ///
  /// \param [in] seconds  The period in second when a synchronous flush would
  /// be made since the last unsteady commit.
  inline env &set_sync_period(double seconds);

  /// \brief Alter environment flags.
  inline env &alter_flags(MDBX_env_flags_t flags, bool on_off);

  /// \brief Set all size-related parameters of environment.
  inline env &set_geometry(const geometry &size);

  /// \brief Flush the environment data buffers.
  /// \return `True` if sync done or no data to sync, or `false` if the
  /// environment is busy by other thread or none of the thresholds are reached.
  inline bool sync_to_disk(bool force = true, bool nonblock = false);

  /// \brief Performs non-blocking polling of sync-to-disk thresholds.
  /// \return `True` if sync done or no data to sync, or `false` if the
  /// environment is busy by other thread or none of the thresholds are reached.
  bool poll_sync_to_disk() { return sync_to_disk(false, true); }

  /// \brief Close a key-value map (aka sub-database) handle. Normally
  /// unnecessary.
  ///
  /// Closing a database handle is not necessary, but lets \ref txn::open_map()
  /// reuse the handle value. Usually it's better to set a bigger
  /// \ref env::operate_parameters::max_maps, unless that value would be
  /// large.
  ///
  /// \note Use with care.
  /// This call is synchronized via mutex with other calls \ref close_map(), but
  /// NOT with other transactions running by other threads. The "next" version
  /// of libmdbx (\ref MithrilDB) will solve this issue.
  ///
  /// Handles should only be closed if no other threads are going to reference
  /// the database handle or one of its cursors any further. Do not close a
  /// handle if an existing transaction has modified its database. Doing so can
  /// cause misbehavior from database corruption to errors like
  /// \ref MDBX_BAD_DBI (since the DB name is gone).
  inline void close_map(const map_handle &);

  /// \brief Reader information
  struct reader_info {
    int slot;                 ///< The reader lock table slot number.
    mdbx_pid_t pid;           ///< The reader process ID.
    mdbx_tid_t thread;        ///< The reader thread ID.
    uint64_t transaction_id;  ///< The ID of the transaction being read,
                              ///< i.e. the MVCC-snapshot number.
    uint64_t transaction_lag; ///< The lag from a recent MVCC-snapshot,
                              ///< i.e. the number of committed write
                              /// transactions since the current read
                              /// transaction started.
    size_t bytes_used; ///< The number of last used page in the MVCC-snapshot
                       ///< which being read, i.e. database file can't be shrunk
                       ///< beyond this.
    size_t bytes_retained; ///< The total size of the database pages that
                           ///< were retired by committed write transactions
                           ///< after the reader's MVCC-snapshot, i.e. the space
                           ///< which would be freed after the Reader releases
                           ///< the MVCC-snapshot for reuse by completion read
                           ///< transaction.

    MDBX_CXX11_CONSTEXPR reader_info(int slot, mdbx_pid_t pid,
                                     mdbx_tid_t thread, uint64_t txnid,
                                     uint64_t lag, size_t used,
                                     size_t retained) noexcept;
  };

  /// \brief Enumerate readers.
  ///
  /// The VISITOR class must have `int operator(const reader_info&, int serial)`
  /// which should return \ref continue_loop (zero) to continue enumeration,
  /// or any non-zero value to exit.
  ///
  /// \returns The last value returned from visitor' functor.
  template <typename VISITOR> inline int enumerate_readers(VISITOR &visitor);

  /// \brief Checks for stale readers in the lock table and
  /// return number of cleared slots.
  inline unsigned check_readers();

  /// \brief Sets a Handle-Slow-Readers callback to resolve database
  /// full/overflow issue due to a reader(s) which prevents the old data from
  /// being recycled.
  ///
  /// Such callback will be triggered in a case where there is not enough free
  /// space in the database due to long read transaction(s) which impedes
  /// reusing the pages of an old MVCC snapshot(s).
  ///
  /// Using this callback you can choose how to resolve the situation:
  ///  - abort the write transaction with an error;
  ///  - wait for the read transaction(s) to complete;
  ///  - notify a thread performing a long-lived read transaction
  ///    and wait for an effect;
  ///  - kill the thread or whole process that performs the long-lived read
  ///    transaction;
  ///
  /// \see long-lived-read
  inline env &set_HandleSlowReaders(MDBX_hsr_func *);

  /// \brief Returns the current Handle-Slow-Readers callback used to resolve
  /// database full/overflow issue due to a reader(s) which prevents the old
  /// data from being recycled.
  /// \see set_HandleSlowReaders()
  inline MDBX_hsr_func *get_HandleSlowReaders() const noexcept;

  /// \brief Starts read (read-only) transaction.
  inline txn_managed start_read() const;

  /// \brief Creates but not start read transaction.
  inline txn_managed prepare_read() const;

  /// \brief Starts write (read-write) transaction.
  inline txn_managed start_write(bool dont_wait = false);

  /// \brief Tries to start write (read-write) transaction without blocking.
  inline txn_managed try_start_write();
};

/// \brief Managed database environment.
///
/// As other managed classes, `env_managed` destroys the represented underlying
/// object from the own class destructor, but disallows copying and assignment
/// for instances.
///
/// An environment supports multiple key-value databases (aka key-value spaces
/// or tables), all residing in the same shared-memory map.
class LIBMDBX_API_TYPE env_managed : public env {
  using inherited = env;
  /// delegated constructor for RAII
  MDBX_CXX11_CONSTEXPR env_managed(MDBX_env *ptr) noexcept : inherited(ptr) {}
  void setup(unsigned max_maps, unsigned max_readers = 0);

public:
  MDBX_CXX11_CONSTEXPR env_managed() noexcept = default;

  /// \brief Open existing database.
#ifdef MDBX_STD_FILESYSTEM_PATH
  env_managed(const MDBX_STD_FILESYSTEM_PATH &pathname,
              const operate_parameters &, bool accede = true);
#endif /* MDBX_STD_FILESYSTEM_PATH */
#if defined(_WIN32) || defined(_WIN64) || defined(DOXYGEN)
  env_managed(const ::std::wstring &pathname, const operate_parameters &,
              bool accede = true);
  explicit env_managed(const wchar_t *pathname, const operate_parameters &,
                       bool accede = true);
#endif /* Windows */
  env_managed(const ::std::string &pathname, const operate_parameters &,
              bool accede = true);
  explicit env_managed(const char *pathname, const operate_parameters &,
                       bool accede = true);

  /// \brief Additional parameters for creating a new database.
  struct create_parameters {
    env::geometry geometry;
    mdbx_mode_t file_mode_bits{0640};
    bool use_subdirectory{false};
    MDBX_CXX11_CONSTEXPR create_parameters() noexcept = default;
    create_parameters(const create_parameters &) noexcept = default;
  };

  /// \brief Create new or open existing database.
#ifdef MDBX_STD_FILESYSTEM_PATH
  env_managed(const MDBX_STD_FILESYSTEM_PATH &pathname,
              const create_parameters &, const operate_parameters &,
              bool accede = true);
#endif /* MDBX_STD_FILESYSTEM_PATH */
#if defined(_WIN32) || defined(_WIN64) || defined(DOXYGEN)
  env_managed(const ::std::wstring &pathname, const create_parameters &,
              const operate_parameters &, bool accede = true);
  explicit env_managed(const wchar_t *pathname, const create_parameters &,
                       const operate_parameters &, bool accede = true);
#endif /* Windows */
  env_managed(const ::std::string &pathname, const create_parameters &,
              const operate_parameters &, bool accede = true);
  explicit env_managed(const char *pathname, const create_parameters &,
                       const operate_parameters &, bool accede = true);

  /// \brief Explicitly closes the environment and release the memory map.
  ///
  /// Only a single thread may call this function. All transactions, databases,
  /// and cursors must already be closed before calling this function. Attempts
  /// to use any such handles after calling this function will cause a
  /// `SIGSEGV`. The environment handle will be freed and must not be used again
  /// after this call.
  ///
  /// \param [in] dont_sync  A dont'sync flag, if non-zero the last checkpoint
  /// will be kept "as is" and may be still "weak" in the \ref lazy_weak_tail
  /// or \ref whole_fragile modes. Such "weak" checkpoint will be ignored
  /// on opening next time, and transactions since the last non-weak checkpoint
  /// (meta-page update) will rolledback for consistency guarantee.
  void close(bool dont_sync = false);

  env_managed(env_managed &&) = default;
  env_managed &operator=(env_managed &&other) noexcept {
    if (MDBX_UNLIKELY(handle_))
      MDBX_CXX20_UNLIKELY {
        assert(handle_ != other.handle_);
        close();
      }
    inherited::operator=(std::move(other));
    return *this;
  }
  env_managed(const env_managed &) = delete;
  env_managed &operator=(const env_managed &) = delete;
  virtual ~env_managed() noexcept;
};

/// \brief Unmanaged database transaction.
///
/// Like other unmanaged classes, `txn` allows copying and assignment for
/// instances, but does not destroys the represented underlying object from the
/// own class destructor.
///
/// All database operations require a transaction handle. Transactions may be
/// read-only or read-write.
class LIBMDBX_API_TYPE txn {
protected:
  friend class cursor;
  MDBX_txn *handle_{nullptr};
  MDBX_CXX11_CONSTEXPR txn(MDBX_txn *ptr) noexcept;

public:
  MDBX_CXX11_CONSTEXPR txn() noexcept = default;
  txn(const txn &) noexcept = default;
  inline txn &operator=(txn &&other) noexcept;
  inline txn(txn &&other) noexcept;
  inline ~txn() noexcept;

  MDBX_CXX14_CONSTEXPR operator bool() const noexcept;
  MDBX_CXX14_CONSTEXPR operator const MDBX_txn *() const;
  MDBX_CXX14_CONSTEXPR operator MDBX_txn *();
  friend MDBX_CXX11_CONSTEXPR bool operator==(const txn &a,
                                              const txn &b) noexcept;
  friend MDBX_CXX11_CONSTEXPR bool operator!=(const txn &a,
                                              const txn &b) noexcept;

  /// \brief Returns the transaction's environment.
  inline ::mdbx::env env() const noexcept;
  /// \brief Returns transaction's flags.
  inline MDBX_txn_flags_t flags() const;
  /// \brief Return the transaction's ID.
  inline uint64_t id() const;

  /// \brief Checks whether the given data is on a dirty page.
  inline bool is_dirty(const void *ptr) const;

  /// \brief Checks whether the transaction is read-only.
  bool is_readonly() const { return (flags() & MDBX_TXN_RDONLY) != 0; }

  /// \brief Checks whether the transaction is read-write.
  bool is_readwrite() const { return (flags() & MDBX_TXN_RDONLY) == 0; }

  using info = ::MDBX_txn_info;
  /// \brief Returns information about the MDBX transaction.
  inline info get_info(bool scan_reader_lock_table = false) const;

  /// \brief Returns maximal write transaction size (i.e. limit for summary
  /// volume of dirty pages) in bytes.
  size_t size_max() const { return env().transaction_size_max(); }

  /// \brief Returns current write transaction size (i.e.summary volume of dirty
  /// pages) in bytes.
  size_t size_current() const {
    assert(is_readwrite());
    return size_t(get_info().txn_space_dirty);
  }

  //----------------------------------------------------------------------------

  /// \brief Reset a read-only transaction.
  inline void reset_reading();

  /// \brief Renew a read-only transaction.
  inline void renew_reading();

  /// \brief Start nested write transaction.
  txn_managed start_nested();

  /// \brief Opens cursor for specified key-value map handle.
  inline cursor_managed open_cursor(map_handle map);

  /// \brief Open existing key-value map.
  inline map_handle open_map(
      const char *name,
      const ::mdbx::key_mode key_mode = ::mdbx::key_mode::usual,
      const ::mdbx::value_mode value_mode = ::mdbx::value_mode::single) const;
  /// \brief Open existing key-value map.
  inline map_handle open_map(
      const ::std::string &name,
      const ::mdbx::key_mode key_mode = ::mdbx::key_mode::usual,
      const ::mdbx::value_mode value_mode = ::mdbx::value_mode::single) const;

  /// \brief Create new or open existing key-value map.
  inline map_handle
  create_map(const char *name,
             const ::mdbx::key_mode key_mode = ::mdbx::key_mode::usual,
             const ::mdbx::value_mode value_mode = ::mdbx::value_mode::single);
  /// \brief Create new or open existing key-value map.
  inline map_handle
  create_map(const ::std::string &name,
             const ::mdbx::key_mode key_mode = ::mdbx::key_mode::usual,
             const ::mdbx::value_mode value_mode = ::mdbx::value_mode::single);

  /// \brief Drops key-value map using handle.
  inline void drop_map(map_handle map);
  /// \brief Drops key-value map using name.
  /// \return `True` if the key-value map existed and was deleted, either
  /// `false` if the key-value map did not exist and there is nothing to delete.
  bool drop_map(const char *name, bool throw_if_absent = false);
  /// \brief Drop key-value map.
  /// \return `True` if the key-value map existed and was deleted, either
  /// `false` if the key-value map did not exist and there is nothing to delete.
  inline bool drop_map(const ::std::string &name, bool throw_if_absent = false);

  /// \brief Clear key-value map.
  inline void clear_map(map_handle map);
  /// \return `True` if the key-value map existed and was cleared, either
  /// `false` if the key-value map did not exist and there is nothing to clear.
  bool clear_map(const char *name, bool throw_if_absent = false);
  /// \return `True` if the key-value map existed and was cleared, either
  /// `false` if the key-value map did not exist and there is nothing to clear.
  inline bool clear_map(const ::std::string &name,
                        bool throw_if_absent = false);

  using map_stat = ::MDBX_stat;
  /// \brief Returns statistics for a sub-database.
  inline map_stat get_map_stat(map_handle map) const;
  /// \brief Returns depth (bitmask) information of nested dupsort (multi-value)
  /// B+trees for given database.
  inline uint32_t get_tree_deepmask(map_handle map) const;
  /// \brief Returns information about key-value map (aka sub-database) handle.
  inline map_handle::info get_handle_info(map_handle map) const;

  using canary = ::MDBX_canary;
  /// \brief Set integers markers (aka "canary") associated with the
  /// environment.
  inline txn &put_canary(const canary &);
  /// \brief Returns fours integers markers (aka "canary") associated with the
  /// environment.
  inline canary get_canary() const;

  /// Reads sequence generator associated with a key-value map (aka
  /// sub-database).
  inline uint64_t sequence(map_handle map) const;
  /// \brief Reads and increment sequence generator associated with a key-value
  /// map (aka sub-database).
  inline uint64_t sequence(map_handle map, uint64_t increment);

  /// \brief Compare two keys according to a particular key-value map (aka
  /// sub-database).
  inline int compare_keys(map_handle map, const slice &a,
                          const slice &b) const noexcept;
  /// \brief Compare two values according to a particular key-value map (aka
  /// sub-database).
  inline int compare_values(map_handle map, const slice &a,
                            const slice &b) const noexcept;
  /// \brief Compare keys of two pairs according to a particular key-value map
  /// (aka sub-database).
  inline int compare_keys(map_handle map, const pair &a,
                          const pair &b) const noexcept;
  /// \brief Compare values of two pairs according to a particular key-value map
  /// (aka sub-database).
  inline int compare_values(map_handle map, const pair &a,
                            const pair &b) const noexcept;

  /// \brief Get value by key from a key-value map (aka sub-database).
  inline slice get(map_handle map, const slice &key) const;
  /// \brief Get first of multi-value and values count by key from a key-value
  /// multimap (aka sub-database).
  inline slice get(map_handle map, slice key, size_t &values_count) const;
  /// \brief Get value by key from a key-value map (aka sub-database).
  inline slice get(map_handle map, const slice &key,
                   const slice &value_at_absence) const;
  /// \brief Get first of multi-value and values count by key from a key-value
  /// multimap (aka sub-database).
  inline slice get(map_handle map, slice key, size_t &values_count,
                   const slice &value_at_absence) const;
  /// \brief Get value for equal or great key from a database.
  /// \return Bundle of key-value pair and boolean flag,
  /// which will be `true` if the exact key was found and `false` otherwise.
  inline pair_result get_equal_or_great(map_handle map, const slice &key) const;
  /// \brief Get value for equal or great key from a database.
  /// \return Bundle of key-value pair and boolean flag,
  /// which will be `true` if the exact key was found and `false` otherwise.
  inline pair_result get_equal_or_great(map_handle map, const slice &key,
                                        const slice &value_at_absence) const;

  inline MDBX_error_t put(map_handle map, const slice &key, slice *value,
                          MDBX_put_flags_t flags) noexcept;
  inline void put(map_handle map, const slice &key, slice value, put_mode mode);
  inline void insert(map_handle map, const slice &key, slice value);
  inline value_result try_insert(map_handle map, const slice &key, slice value);
  inline slice insert_reserve(map_handle map, const slice &key,
                              size_t value_length);
  inline value_result try_insert_reserve(map_handle map, const slice &key,
                                         size_t value_length);

  inline void upsert(map_handle map, const slice &key, const slice &value);
  inline slice upsert_reserve(map_handle map, const slice &key,
                              size_t value_length);

  inline void update(map_handle map, const slice &key, const slice &value);
  inline bool try_update(map_handle map, const slice &key, const slice &value);
  inline slice update_reserve(map_handle map, const slice &key,
                              size_t value_length);
  inline value_result try_update_reserve(map_handle map, const slice &key,
                                         size_t value_length);

  /// \brief Removes all values for given key.
  inline bool erase(map_handle map, const slice &key);

  /// \brief Removes the particular multi-value entry of the key.
  inline bool erase(map_handle map, const slice &key, const slice &value);

  /// \brief Replaces the particular multi-value of the key with a new value.
  inline void replace(map_handle map, const slice &key, slice old_value,
                      const slice &new_value);

  /// \brief Removes and return a value of the key.
  template <class ALLOCATOR, typename CAPACITY_POLICY>
  inline buffer<ALLOCATOR, CAPACITY_POLICY>
  extract(map_handle map, const slice &key,
          const typename buffer<ALLOCATOR, CAPACITY_POLICY>::allocator_type &
              allocator = buffer<ALLOCATOR, CAPACITY_POLICY>::allocator_type());

  /// \brief Replaces and returns a value of the key with new one.
  template <class ALLOCATOR, typename CAPACITY_POLICY>
  inline buffer<ALLOCATOR, CAPACITY_POLICY>
  replace(map_handle map, const slice &key, const slice &new_value,
          const typename buffer<ALLOCATOR, CAPACITY_POLICY>::allocator_type &
              allocator = buffer<ALLOCATOR, CAPACITY_POLICY>::allocator_type());

  template <class ALLOCATOR, typename CAPACITY_POLICY>
  inline buffer<ALLOCATOR, CAPACITY_POLICY> replace_reserve(
      map_handle map, const slice &key, slice &new_value,
      const typename buffer<ALLOCATOR, CAPACITY_POLICY>::allocator_type
          &allocator = buffer<ALLOCATOR, CAPACITY_POLICY>::allocator_type());

  /// \brief Adding a key-value pair, provided that ascending order of the keys
  /// and (optionally) values are preserved.
  ///
  /// Instead of splitting the full b+tree pages, the data will be placed on new
  /// ones. Thus appending is about two times faster than insertion, and the
  /// pages will be filled in completely mostly but not half as after splitting
  /// ones. On the other hand, any subsequent insertion or update with an
  /// increase in the length of the value will be twice as slow, since it will
  /// require splitting already filled pages.
  ///
  /// \param [in] map   A map handle to append
  /// \param [in] key   A key to be append
  /// \param [in] value A value to store with the key
  /// \param [in] multivalue_order_preserved
  /// If `multivalue_order_preserved == true` then the same rules applied for
  /// to pages of nested b+tree of multimap's values.
  inline void append(map_handle map, const slice &key, const slice &value,
                     bool multivalue_order_preserved = true);

  size_t put_multiple(map_handle map, const slice &key,
                      const size_t value_length, const void *values_array,
                      size_t values_count, put_mode mode,
                      bool allow_partial = false);
  template <typename VALUE>
  void put_multiple(map_handle map, const slice &key,
                    const ::std::vector<VALUE> &vector, put_mode mode) {
    put_multiple(map, key, sizeof(VALUE), vector.data(), vector.size(), mode,
                 false);
  }

  inline ptrdiff_t estimate(map_handle map, pair from, pair to) const;
  inline ptrdiff_t estimate(map_handle map, slice from, slice to) const;
  inline ptrdiff_t estimate_from_first(map_handle map, slice to) const;
  inline ptrdiff_t estimate_to_last(map_handle map, slice from) const;
};

/// \brief Managed database transaction.
///
/// As other managed classes, `txn_managed` destroys the represented underlying
/// object from the own class destructor, but disallows copying and assignment
/// for instances.
///
/// All database operations require a transaction handle. Transactions may be
/// read-only or read-write.
class LIBMDBX_API_TYPE txn_managed : public txn {
  using inherited = txn;
  friend class env;
  friend class txn;
  /// delegated constructor for RAII
  MDBX_CXX11_CONSTEXPR txn_managed(MDBX_txn *ptr) noexcept : inherited(ptr) {}

public:
  MDBX_CXX11_CONSTEXPR txn_managed() noexcept = default;
  txn_managed(txn_managed &&) = default;
  txn_managed &operator=(txn_managed &&other) noexcept {
    if (MDBX_UNLIKELY(handle_))
      MDBX_CXX20_UNLIKELY {
        assert(handle_ != other.handle_);
        abort();
      }
    inherited::operator=(std::move(other));
    return *this;
  }
  txn_managed(const txn_managed &) = delete;
  txn_managed &operator=(const txn_managed &) = delete;
  ~txn_managed() noexcept;

  //----------------------------------------------------------------------------

  /// \brief Abandon all the operations of the transaction
  /// instead of saving ones.
  void abort();

  /// \brief Commit all the operations of a transaction into the database.
  void commit();

  using commit_latency = MDBX_commit_latency;

  /// \brief Commit all the operations of a transaction into the database
  /// and collect latency information.
  void commit(commit_latency *);

  /// \brief Commit all the operations of a transaction into the database
  /// and collect latency information.
  void commit(commit_latency &latency) { return commit(&latency); }

  /// \brief Commit all the operations of a transaction into the database
  /// and return latency information.
  /// \returns latency information of commit stages.
  commit_latency commit_get_latency() {
    commit_latency result;
    commit(&result);
    return result;
  }
};

/// \brief Unmanaged cursor.
///
/// Like other unmanaged classes, `cursor` allows copying and assignment for
/// instances, but does not destroys the represented underlying object from the
/// own class destructor.
///
/// \copydetails MDBX_cursor
class LIBMDBX_API_TYPE cursor {
protected:
  MDBX_cursor *handle_{nullptr};
  MDBX_CXX11_CONSTEXPR cursor(MDBX_cursor *ptr) noexcept;

public:
  MDBX_CXX11_CONSTEXPR cursor() noexcept = default;
  cursor(const cursor &) noexcept = default;
  inline cursor &operator=(cursor &&other) noexcept;
  inline cursor(cursor &&other) noexcept;
  inline ~cursor() noexcept;
  MDBX_CXX14_CONSTEXPR operator bool() const noexcept;
  MDBX_CXX14_CONSTEXPR operator const MDBX_cursor *() const;
  MDBX_CXX14_CONSTEXPR operator MDBX_cursor *();
  friend MDBX_CXX11_CONSTEXPR bool operator==(const cursor &a,
                                              const cursor &b) noexcept;
  friend MDBX_CXX11_CONSTEXPR bool operator!=(const cursor &a,
                                              const cursor &b) noexcept;

  enum move_operation {
    first = MDBX_FIRST,
    last = MDBX_LAST,
    next = MDBX_NEXT,
    previous = MDBX_PREV,
    get_current = MDBX_GET_CURRENT,

    multi_prevkey_lastvalue = MDBX_PREV_NODUP,
    multi_currentkey_firstvalue = MDBX_FIRST_DUP,
    multi_currentkey_prevvalue = MDBX_PREV_DUP,
    multi_currentkey_nextvalue = MDBX_NEXT_DUP,
    multi_currentkey_lastvalue = MDBX_LAST_DUP,
    multi_nextkey_firstvalue = MDBX_NEXT_NODUP,

    multi_find_pair = MDBX_GET_BOTH,
    multi_exactkey_lowerboundvalue = MDBX_GET_BOTH_RANGE,

    find_key = MDBX_SET,
    key_exact = MDBX_SET_KEY,
    key_lowerbound = MDBX_SET_RANGE
  };

  struct move_result : public pair_result {
    inline move_result(const cursor &cursor, bool throw_notfound);
    inline move_result(cursor &cursor, move_operation operation,
                       bool throw_notfound);
    inline move_result(cursor &cursor, move_operation operation,
                       const slice &key, bool throw_notfound);
    inline move_result(cursor &cursor, move_operation operation,
                       const slice &key, const slice &value,
                       bool throw_notfound);
    move_result(const move_result &) noexcept = default;
    move_result &operator=(const move_result &) noexcept = default;
  };

protected:
  inline bool move(move_operation operation, MDBX_val *key, MDBX_val *value,
                   bool throw_notfound) const
      /* fake const, i.e. for some operations */;
  inline ptrdiff_t estimate(move_operation operation, MDBX_val *key,
                            MDBX_val *value) const;

public:
  inline move_result move(move_operation operation, bool throw_notfound);
  inline move_result to_first(bool throw_notfound = true);
  inline move_result to_previous(bool throw_notfound = true);
  inline move_result to_previous_last_multi(bool throw_notfound = true);
  inline move_result to_current_first_multi(bool throw_notfound = true);
  inline move_result to_current_prev_multi(bool throw_notfound = true);
  inline move_result current(bool throw_notfound = true) const;
  inline move_result to_current_next_multi(bool throw_notfound = true);
  inline move_result to_current_last_multi(bool throw_notfound = true);
  inline move_result to_next_first_multi(bool throw_notfound = true);
  inline move_result to_next(bool throw_notfound = true);
  inline move_result to_last(bool throw_notfound = true);

  inline move_result move(move_operation operation, const slice &key,
                          bool throw_notfound);
  inline move_result find(const slice &key, bool throw_notfound = true);
  inline move_result lower_bound(const slice &key, bool throw_notfound = true);

  inline move_result move(move_operation operation, const slice &key,
                          const slice &value, bool throw_notfound);
  inline move_result find_multivalue(const slice &key, const slice &value,
                                     bool throw_notfound = true);
  inline move_result lower_bound_multivalue(const slice &key,
                                            const slice &value,
                                            bool throw_notfound = false);

  inline bool seek(const slice &key);
  inline bool move(move_operation operation, slice &key, slice &value,
                   bool throw_notfound);

  /// \brief Return count of duplicates for current key.
  inline size_t count_multivalue() const;

  inline bool eof() const;
  inline bool on_first() const;
  inline bool on_last() const;
  inline ptrdiff_t estimate(slice key, slice value) const;
  inline ptrdiff_t estimate(slice key) const;
  inline ptrdiff_t estimate(move_operation operation) const;

  //----------------------------------------------------------------------------

  /// \brief Renew/bind a cursor with a new transaction and previously used
  /// key-value map handle.
  inline void renew(::mdbx::txn &txn);

  /// \brief Bind/renew a cursor with a new transaction and specified key-value
  /// map handle.
  inline void bind(::mdbx::txn &txn, ::mdbx::map_handle map_handle);

  /// \brief Returns the cursor's transaction.
  inline ::mdbx::txn txn() const;
  inline map_handle map() const;

  inline operator ::mdbx::txn() const { return txn(); }
  inline operator ::mdbx::map_handle() const { return map(); }

  inline MDBX_error_t put(const slice &key, slice *value,
                          MDBX_put_flags_t flags) noexcept;
  inline void insert(const slice &key, slice value);
  inline value_result try_insert(const slice &key, slice value);
  inline slice insert_reserve(const slice &key, size_t value_length);
  inline value_result try_insert_reserve(const slice &key, size_t value_length);

  inline void upsert(const slice &key, const slice &value);
  inline slice upsert_reserve(const slice &key, size_t value_length);

  inline void update(const slice &key, const slice &value);
  inline bool try_update(const slice &key, const slice &value);
  inline slice update_reserve(const slice &key, size_t value_length);
  inline value_result try_update_reserve(const slice &key, size_t value_length);

  /// \brief Removes single key-value pair or all multi-values at the current
  /// cursor position.
  inline bool erase(bool whole_multivalue = false);

  /// \brief Seeks and removes first value or whole multi-value of the given
  /// key.
  /// \return `True` if the key is found and a value(s) is removed.
  inline bool erase(const slice &key, bool whole_multivalue = true);

  /// \brief Seeks and removes the particular multi-value entry of the key.
  /// \return `True` if the given key-value pair is found and removed.
  inline bool erase(const slice &key, const slice &value);
};

/// \brief Managed cursor.
///
/// As other managed classes, `cursor_managed` destroys the represented
/// underlying object from the own class destructor, but disallows copying and
/// assignment for instances.
///
/// \copydetails MDBX_cursor
class LIBMDBX_API_TYPE cursor_managed : public cursor {
  using inherited = cursor;
  friend class txn;
  /// delegated constructor for RAII
  MDBX_CXX11_CONSTEXPR cursor_managed(MDBX_cursor *ptr) noexcept
      : inherited(ptr) {}

public:
  /// \brief Creates a new managed cursor with underlying object.
  cursor_managed() : cursor_managed(::mdbx_cursor_create(nullptr)) {
    if (MDBX_UNLIKELY(!handle_))
      MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_ENOMEM);
  }

  /// \brief Explicitly closes the cursor.
  void close();

  cursor_managed(cursor_managed &&) = default;
  cursor_managed &operator=(cursor_managed &&other) noexcept {
    if (MDBX_UNLIKELY(handle_))
      MDBX_CXX20_UNLIKELY {
        assert(handle_ != other.handle_);
        close();
      }
    inherited::operator=(std::move(other));
    return *this;
  }

  cursor_managed(const cursor_managed &) = delete;
  cursor_managed &operator=(const cursor_managed &) = delete;
  ~cursor_managed() noexcept { ::mdbx_cursor_close(handle_); }
};

//------------------------------------------------------------------------------

LIBMDBX_API ::std::ostream &operator<<(::std::ostream &, const slice &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &, const pair &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &, const pair_result &);
template <class ALLOCATOR, typename CAPACITY_POLICY>
inline ::std::ostream &
operator<<(::std::ostream &out, const buffer<ALLOCATOR, CAPACITY_POLICY> &it) {
  return (it.is_freestanding()
              ? out << "buf-" << it.headroom() << "." << it.tailroom()
              : out << "ref-")
         << it.slice();
}
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &,
                                       const env::geometry::size &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &, const env::geometry &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &,
                                       const env::operate_parameters &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &, const env::mode &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &,
                                       const env::durability &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &,
                                       const env::reclaiming_options &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &,
                                       const env::operate_options &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &,
                                       const env_managed::create_parameters &);

LIBMDBX_API ::std::ostream &operator<<(::std::ostream &,
                                       const MDBX_log_level_t &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &,
                                       const MDBX_debug_flags_t &);
LIBMDBX_API ::std::ostream &operator<<(::std::ostream &, const error &);
inline ::std::ostream &operator<<(::std::ostream &out,
                                  const MDBX_error_t &errcode) {
  return out << error(errcode);
}

//==============================================================================
//
// Inline body of the libmdbx C++ API
//

MDBX_CXX11_CONSTEXPR const version_info &get_version() noexcept {
  return ::mdbx_version;
}
MDBX_CXX11_CONSTEXPR const build_info &get_build() noexcept {
  return ::mdbx_build;
}

static MDBX_CXX17_CONSTEXPR size_t strlen(const char *c_str) noexcept {
#if defined(__cpp_lib_is_constant_evaluated) &&                                \
    __cpp_lib_is_constant_evaluated >= 201811L
  if (::std::is_constant_evaluated()) {
    for (size_t i = 0; c_str; ++i)
      if (!c_str[i])
        return i;
    return 0;
  }
#endif /* __cpp_lib_is_constant_evaluated >= 201811 */
#if defined(__cpp_lib_string_view) && __cpp_lib_string_view >= 201606L
  return c_str ? ::std::string_view(c_str).length() : 0;
#else
  return c_str ? ::std::strlen(c_str) : 0;
#endif
}

MDBX_MAYBE_UNUSED static MDBX_CXX20_CONSTEXPR void *
memcpy(void *dest, const void *src, size_t bytes) noexcept {
#if defined(__cpp_lib_is_constant_evaluated) &&                                \
    __cpp_lib_is_constant_evaluated >= 201811L
  if (::std::is_constant_evaluated()) {
    for (size_t i = 0; i < bytes; ++i)
      static_cast<byte *>(dest)[i] = static_cast<const byte *>(src)[i];
    return dest;
  } else
#endif /* __cpp_lib_is_constant_evaluated >= 201811 */
    return ::std::memcpy(dest, src, bytes);
}

static MDBX_CXX20_CONSTEXPR int memcmp(const void *a, const void *b,
                                       size_t bytes) noexcept {
#if defined(__cpp_lib_is_constant_evaluated) &&                                \
    __cpp_lib_is_constant_evaluated >= 201811L
  if (::std::is_constant_evaluated()) {
    for (size_t i = 0; i < bytes; ++i) {
      const int diff =
          static_cast<const byte *>(a)[i] - static_cast<const byte *>(b)[i];
      if (diff)
        return diff;
    }
    return 0;
  } else
#endif /* __cpp_lib_is_constant_evaluated >= 201811 */
    return ::std::memcmp(a, b, bytes);
}

static MDBX_CXX14_CONSTEXPR size_t check_length(size_t bytes) {
  if (MDBX_UNLIKELY(bytes > size_t(MDBX_MAXDATASIZE)))
    MDBX_CXX20_UNLIKELY throw_max_length_exceeded();
  return bytes;
}

static MDBX_CXX14_CONSTEXPR size_t check_length(size_t headroom,
                                                size_t payload) {
  return check_length(check_length(headroom) + check_length(payload));
}

MDBX_MAYBE_UNUSED static MDBX_CXX14_CONSTEXPR size_t
check_length(size_t headroom, size_t payload, size_t tailroom) {
  return check_length(check_length(headroom, payload) + check_length(tailroom));
}

inline bool exception_thunk::is_clean() const noexcept { return !captured_; }

inline void exception_thunk::capture() noexcept {
  assert(is_clean());
  captured_ = ::std::current_exception();
}

inline void exception_thunk::rethrow_captured() const {
  if (captured_)
    MDBX_CXX20_UNLIKELY ::std::rethrow_exception(captured_);
}

//------------------------------------------------------------------------------

MDBX_CXX11_CONSTEXPR error::error(MDBX_error_t error_code) noexcept
    : code_(error_code) {}

inline error &error::operator=(MDBX_error_t error_code) noexcept {
  code_ = error_code;
  return *this;
}

MDBX_CXX11_CONSTEXPR bool operator==(const error &a, const error &b) noexcept {
  return a.code_ == b.code_;
}

MDBX_CXX11_CONSTEXPR bool operator!=(const error &a, const error &b) noexcept {
  return !(a == b);
}

MDBX_CXX11_CONSTEXPR bool error::is_success() const noexcept {
  return code_ == MDBX_SUCCESS;
}

MDBX_CXX11_CONSTEXPR bool error::is_result_true() const noexcept {
  return code_ == MDBX_RESULT_FALSE;
}

MDBX_CXX11_CONSTEXPR bool error::is_result_false() const noexcept {
  return code_ == MDBX_RESULT_TRUE;
}

MDBX_CXX11_CONSTEXPR bool error::is_failure() const noexcept {
  return code_ != MDBX_SUCCESS && code_ != MDBX_RESULT_TRUE;
}

MDBX_CXX11_CONSTEXPR MDBX_error_t error::code() const noexcept { return code_; }

MDBX_CXX11_CONSTEXPR bool error::is_mdbx_error() const noexcept {
  return (code() >= MDBX_FIRST_LMDB_ERRCODE &&
          code() <= MDBX_LAST_LMDB_ERRCODE) ||
         (code() >= MDBX_FIRST_ADDED_ERRCODE &&
          code() <= MDBX_LAST_ADDED_ERRCODE);
}

inline void error::throw_exception(int error_code) {
  const error trouble(static_cast<MDBX_error_t>(error_code));
  trouble.throw_exception();
}

inline void error::throw_on_failure() const {
  if (MDBX_UNLIKELY(is_failure()))
    MDBX_CXX20_UNLIKELY throw_exception();
}

inline void error::success_or_throw() const {
  if (MDBX_UNLIKELY(!is_success()))
    MDBX_CXX20_UNLIKELY throw_exception();
}

inline void error::success_or_throw(const exception_thunk &thunk) const {
  assert(thunk.is_clean() || code() != MDBX_SUCCESS);
  if (MDBX_UNLIKELY(!is_success())) {
    MDBX_CXX20_UNLIKELY if (!thunk.is_clean()) thunk.rethrow_captured();
    else throw_exception();
  }
}

inline void error::panic_on_failure(const char *context_where,
                                    const char *func_who) const noexcept {
  if (MDBX_UNLIKELY(is_failure()))
    MDBX_CXX20_UNLIKELY panic(context_where, func_who);
}

inline void error::success_or_panic(const char *context_where,
                                    const char *func_who) const noexcept {
  if (MDBX_UNLIKELY(!is_success()))
    MDBX_CXX20_UNLIKELY panic(context_where, func_who);
}

inline void error::throw_on_nullptr(const void *ptr, MDBX_error_t error_code) {
  if (MDBX_UNLIKELY(ptr == nullptr))
    MDBX_CXX20_UNLIKELY error(error_code).throw_exception();
}

inline void error::throw_on_failure(int error_code) {
  error rc(static_cast<MDBX_error_t>(error_code));
  rc.throw_on_failure();
}

inline void error::success_or_throw(MDBX_error_t error_code) {
  error rc(error_code);
  rc.success_or_throw();
}

inline bool error::boolean_or_throw(int error_code) {
  switch (error_code) {
  case MDBX_RESULT_FALSE:
    return false;
  case MDBX_RESULT_TRUE:
    return true;
  default:
    MDBX_CXX20_UNLIKELY throw_exception(error_code);
  }
}

inline void error::success_or_throw(int error_code,
                                    const exception_thunk &thunk) {
  error rc(static_cast<MDBX_error_t>(error_code));
  rc.success_or_throw(thunk);
}

inline void error::panic_on_failure(int error_code, const char *context_where,
                                    const char *func_who) noexcept {
  error rc(static_cast<MDBX_error_t>(error_code));
  rc.panic_on_failure(context_where, func_who);
}

inline void error::success_or_panic(int error_code, const char *context_where,
                                    const char *func_who) noexcept {
  error rc(static_cast<MDBX_error_t>(error_code));
  rc.success_or_panic(context_where, func_who);
}

//------------------------------------------------------------------------------

MDBX_CXX11_CONSTEXPR slice::slice() noexcept : ::MDBX_val({nullptr, 0}) {}

MDBX_CXX14_CONSTEXPR slice::slice(const void *ptr, size_t bytes)
    : ::MDBX_val({const_cast<void *>(ptr), check_length(bytes)}) {}

MDBX_CXX14_CONSTEXPR slice::slice(const void *begin, const void *end)
    : slice(begin, static_cast<const byte *>(end) -
                       static_cast<const byte *>(begin)) {}

MDBX_CXX17_CONSTEXPR slice::slice(const char *c_str)
    : slice(c_str, ::mdbx::strlen(c_str)) {}

MDBX_CXX14_CONSTEXPR slice::slice(const MDBX_val &src)
    : slice(src.iov_base, src.iov_len) {}

MDBX_CXX14_CONSTEXPR slice::slice(MDBX_val &&src) : slice(src) {
  src.iov_base = nullptr;
}

MDBX_CXX14_CONSTEXPR slice::slice(slice &&src) noexcept : slice(src) {
  src.invalidate();
}

inline slice &slice::assign(const void *ptr, size_t bytes) {
  iov_base = const_cast<void *>(ptr);
  iov_len = check_length(bytes);
  return *this;
}

inline slice &slice::assign(const slice &src) noexcept {
  iov_base = src.iov_base;
  iov_len = src.iov_len;
  return *this;
}

inline slice &slice::assign(const ::MDBX_val &src) {
  return assign(src.iov_base, src.iov_len);
}

slice &slice::assign(slice &&src) noexcept {
  assign(src);
  src.invalidate();
  return *this;
}

inline slice &slice::assign(::MDBX_val &&src) {
  assign(src.iov_base, src.iov_len);
  src.iov_base = nullptr;
  return *this;
}

inline slice &slice::assign(const void *begin, const void *end) {
  return assign(begin, static_cast<const byte *>(end) -
                           static_cast<const byte *>(begin));
}

inline slice &slice::assign(const char *c_str) {
  return assign(c_str, ::mdbx::strlen(c_str));
}

inline slice &slice::operator=(slice &&src) noexcept {
  return assign(::std::move(src));
}

inline slice &slice::operator=(::MDBX_val &&src) {
  return assign(::std::move(src));
}

inline void slice::swap(slice &other) noexcept {
  const auto temp = *this;
  *this = other;
  other = temp;
}

MDBX_CXX11_CONSTEXPR const ::mdbx::byte *slice::byte_ptr() const noexcept {
  return static_cast<const byte *>(iov_base);
}

MDBX_CXX11_CONSTEXPR const ::mdbx::byte *slice::end_byte_ptr() const noexcept {
  return byte_ptr() + length();
}

MDBX_CXX11_CONSTEXPR ::mdbx::byte *slice::byte_ptr() noexcept {
  return static_cast<byte *>(iov_base);
}

MDBX_CXX11_CONSTEXPR ::mdbx::byte *slice::end_byte_ptr() noexcept {
  return byte_ptr() + length();
}

MDBX_CXX11_CONSTEXPR const char *slice::char_ptr() const noexcept {
  return static_cast<const char *>(iov_base);
}

MDBX_CXX11_CONSTEXPR const char *slice::end_char_ptr() const noexcept {
  return char_ptr() + length();
}

MDBX_CXX11_CONSTEXPR char *slice::char_ptr() noexcept {
  return static_cast<char *>(iov_base);
}

MDBX_CXX11_CONSTEXPR char *slice::end_char_ptr() noexcept {
  return char_ptr() + length();
}

MDBX_CXX11_CONSTEXPR const void *slice::data() const noexcept {
  return iov_base;
}

MDBX_CXX11_CONSTEXPR const void *slice::end() const noexcept {
  return static_cast<const void *>(end_byte_ptr());
}

MDBX_CXX11_CONSTEXPR void *slice::data() noexcept { return iov_base; }

MDBX_CXX11_CONSTEXPR void *slice::end() noexcept {
  return static_cast<void *>(end_byte_ptr());
}

MDBX_CXX11_CONSTEXPR size_t slice::length() const noexcept { return iov_len; }

MDBX_CXX14_CONSTEXPR slice &slice::set_length(size_t bytes) {
  iov_len = check_length(bytes);
  return *this;
}

MDBX_CXX14_CONSTEXPR slice &slice::set_end(const void *ptr) {
  MDBX_CONSTEXPR_ASSERT(static_cast<const char *>(ptr) >= char_ptr());
  return set_length(static_cast<const char *>(ptr) - char_ptr());
}

MDBX_CXX11_CONSTEXPR bool slice::empty() const noexcept {
  return length() == 0;
}

MDBX_CXX11_CONSTEXPR bool slice::is_null() const noexcept {
  return data() == nullptr;
}

MDBX_CXX11_CONSTEXPR size_t slice::size() const noexcept { return length(); }

MDBX_CXX11_CONSTEXPR slice::operator bool() const noexcept {
  return !is_null();
}

MDBX_CXX14_CONSTEXPR void slice::invalidate() noexcept { iov_base = nullptr; }

MDBX_CXX14_CONSTEXPR void slice::clear() noexcept {
  iov_base = nullptr;
  iov_len = 0;
}

inline void slice::remove_prefix(size_t n) noexcept {
  assert(n <= size());
  iov_base = static_cast<byte *>(iov_base) + n;
  iov_len -= n;
}

inline void slice::safe_remove_prefix(size_t n) {
  if (MDBX_UNLIKELY(n > size()))
    MDBX_CXX20_UNLIKELY throw_out_range();
  remove_prefix(n);
}

inline void slice::remove_suffix(size_t n) noexcept {
  assert(n <= size());
  iov_len -= n;
}

inline void slice::safe_remove_suffix(size_t n) {
  if (MDBX_UNLIKELY(n > size()))
    MDBX_CXX20_UNLIKELY throw_out_range();
  remove_suffix(n);
}

MDBX_CXX14_CONSTEXPR bool
slice::starts_with(const slice &prefix) const noexcept {
  return length() >= prefix.length() &&
         memcmp(data(), prefix.data(), prefix.length()) == 0;
}

MDBX_CXX14_CONSTEXPR bool slice::ends_with(const slice &suffix) const noexcept {
  return length() >= suffix.length() &&
         memcmp(byte_ptr() + length() - suffix.length(), suffix.data(),
                suffix.length()) == 0;
}

MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR size_t
slice::hash_value() const noexcept {
  size_t h = length() * 3977471;
  for (size_t i = 0; i < length(); ++i)
    h = (h ^ static_cast<const uint8_t *>(data())[i]) * 1664525 + 1013904223;
  return h ^ 3863194411 * (h >> 11);
}

MDBX_CXX11_CONSTEXPR byte slice::operator[](size_t n) const noexcept {
  MDBX_CONSTEXPR_ASSERT(n < size());
  return byte_ptr()[n];
}

MDBX_CXX11_CONSTEXPR byte slice::at(size_t n) const {
  if (MDBX_UNLIKELY(n >= size()))
    MDBX_CXX20_UNLIKELY throw_out_range();
  return byte_ptr()[n];
}

MDBX_CXX14_CONSTEXPR slice slice::head(size_t n) const noexcept {
  MDBX_CONSTEXPR_ASSERT(n <= size());
  return slice(data(), n);
}

MDBX_CXX14_CONSTEXPR slice slice::tail(size_t n) const noexcept {
  MDBX_CONSTEXPR_ASSERT(n <= size());
  return slice(char_ptr() + size() - n, n);
}

MDBX_CXX14_CONSTEXPR slice slice::middle(size_t from, size_t n) const noexcept {
  MDBX_CONSTEXPR_ASSERT(from + n <= size());
  return slice(char_ptr() + from, n);
}

MDBX_CXX14_CONSTEXPR slice slice::safe_head(size_t n) const {
  if (MDBX_UNLIKELY(n > size()))
    MDBX_CXX20_UNLIKELY throw_out_range();
  return head(n);
}

MDBX_CXX14_CONSTEXPR slice slice::safe_tail(size_t n) const {
  if (MDBX_UNLIKELY(n > size()))
    MDBX_CXX20_UNLIKELY throw_out_range();
  return tail(n);
}

MDBX_CXX14_CONSTEXPR slice slice::safe_middle(size_t from, size_t n) const {
  if (MDBX_UNLIKELY(n > max_length))
    MDBX_CXX20_UNLIKELY throw_max_length_exceeded();
  if (MDBX_UNLIKELY(from + n > size()))
    MDBX_CXX20_UNLIKELY throw_out_range();
  return middle(from, n);
}

MDBX_CXX14_CONSTEXPR intptr_t slice::compare_fast(const slice &a,
                                                  const slice &b) noexcept {
  const intptr_t diff = intptr_t(a.length()) - intptr_t(b.length());
  return diff ? diff
         : MDBX_UNLIKELY(a.length() == 0 || a.data() == b.data())
             ? 0
             : memcmp(a.data(), b.data(), a.length());
}

MDBX_CXX14_CONSTEXPR intptr_t
slice::compare_lexicographically(const slice &a, const slice &b) noexcept {
  const size_t shortest = ::std::min(a.length(), b.length());
  if (MDBX_LIKELY(shortest > 0))
    MDBX_CXX20_LIKELY {
      const intptr_t diff = memcmp(a.data(), b.data(), shortest);
      if (MDBX_LIKELY(diff != 0))
        MDBX_CXX20_LIKELY return diff;
    }
  return intptr_t(a.length()) - intptr_t(b.length());
}

MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR bool
operator==(const slice &a, const slice &b) noexcept {
  return slice::compare_fast(a, b) == 0;
}

MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR bool
operator<(const slice &a, const slice &b) noexcept {
  return slice::compare_lexicographically(a, b) < 0;
}

MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR bool
operator>(const slice &a, const slice &b) noexcept {
  return slice::compare_lexicographically(a, b) > 0;
}

MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR bool
operator<=(const slice &a, const slice &b) noexcept {
  return slice::compare_lexicographically(a, b) <= 0;
}

MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR bool
operator>=(const slice &a, const slice &b) noexcept {
  return slice::compare_lexicographically(a, b) >= 0;
}

MDBX_NOTHROW_PURE_FUNCTION MDBX_CXX14_CONSTEXPR bool
operator!=(const slice &a, const slice &b) noexcept {
  return slice::compare_fast(a, b) != 0;
}

template <class ALLOCATOR>
inline string<ALLOCATOR>
slice::as_hex_string(bool uppercase, unsigned wrap_width,
                     const ALLOCATOR &allocator) const {
  return to_hex(*this, uppercase, wrap_width).as_string<ALLOCATOR>(allocator);
}

template <class ALLOCATOR>
inline string<ALLOCATOR>
slice::as_base58_string(unsigned wrap_width, const ALLOCATOR &allocator) const {
  return to_base58(*this, wrap_width).as_string<ALLOCATOR>(allocator);
}

template <class ALLOCATOR>
inline string<ALLOCATOR>
slice::as_base64_string(unsigned wrap_width, const ALLOCATOR &allocator) const {
  return to_base64(*this, wrap_width).as_string<ALLOCATOR>(allocator);
}

template <class ALLOCATOR, class CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
slice::encode_hex(bool uppercase, unsigned wrap_width,
                  const ALLOCATOR &allocator) const {
  return to_hex(*this, uppercase, wrap_width)
      .as_buffer<ALLOCATOR, CAPACITY_POLICY>(allocator);
}

template <class ALLOCATOR, class CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
slice::encode_base58(unsigned wrap_width, const ALLOCATOR &allocator) const {
  return to_base58(*this, wrap_width)
      .as_buffer<ALLOCATOR, CAPACITY_POLICY>(allocator);
}

template <class ALLOCATOR, class CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
slice::encode_base64(unsigned wrap_width, const ALLOCATOR &allocator) const {
  return to_base64(*this, wrap_width)
      .as_buffer<ALLOCATOR, CAPACITY_POLICY>(allocator);
}

template <class ALLOCATOR, class CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
slice::hex_decode(bool ignore_spaces, const ALLOCATOR &allocator) const {
  return from_hex(*this, ignore_spaces)
      .as_buffer<ALLOCATOR, CAPACITY_POLICY>(allocator);
}

template <class ALLOCATOR, class CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
slice::base58_decode(bool ignore_spaces, const ALLOCATOR &allocator) const {
  return from_base58(*this, ignore_spaces)
      .as_buffer<ALLOCATOR, CAPACITY_POLICY>(allocator);
}

template <class ALLOCATOR, class CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
slice::base64_decode(bool ignore_spaces, const ALLOCATOR &allocator) const {
  return from_base64(*this, ignore_spaces)
      .as_buffer<ALLOCATOR, CAPACITY_POLICY>(allocator);
}

inline MDBX_NOTHROW_PURE_FUNCTION bool
slice::is_hex(bool ignore_spaces) const noexcept {
  return !from_hex(*this, ignore_spaces).is_erroneous();
}

inline MDBX_NOTHROW_PURE_FUNCTION bool
slice::is_base58(bool ignore_spaces) const noexcept {
  return !from_base58(*this, ignore_spaces).is_erroneous();
}

inline MDBX_NOTHROW_PURE_FUNCTION bool
slice::is_base64(bool ignore_spaces) const noexcept {
  return !from_base64(*this, ignore_spaces).is_erroneous();
}

//------------------------------------------------------------------------------

template <class ALLOCATOR, typename CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY>::buffer(
    const txn &txn, const struct slice &src, const allocator_type &allocator)
    : buffer(src, !txn.is_dirty(src.data()), allocator) {}

//------------------------------------------------------------------------------

MDBX_CXX11_CONSTEXPR map_handle::info::info(map_handle::flags flags,
                                            map_handle::state state) noexcept
    : flags(flags), state(state) {}

#if CONSTEXPR_ENUM_FLAGS_OPERATIONS
MDBX_CXX11_CONSTEXPR
#endif
::mdbx::key_mode map_handle::info::key_mode() const noexcept {
  return ::mdbx::key_mode(flags & (MDBX_REVERSEKEY | MDBX_INTEGERKEY));
}

#if CONSTEXPR_ENUM_FLAGS_OPERATIONS
MDBX_CXX11_CONSTEXPR
#endif
::mdbx::value_mode map_handle::info::value_mode() const noexcept {
  return ::mdbx::value_mode(flags & (MDBX_DUPSORT | MDBX_REVERSEDUP |
                                     MDBX_DUPFIXED | MDBX_INTEGERDUP));
}

//------------------------------------------------------------------------------

MDBX_CXX11_CONSTEXPR env::env(MDBX_env *ptr) noexcept : handle_(ptr) {}

inline env &env::operator=(env &&other) noexcept {
  handle_ = other.handle_;
  other.handle_ = nullptr;
  return *this;
}

inline env::env(env &&other) noexcept : handle_(other.handle_) {
  other.handle_ = nullptr;
}

inline env::~env() noexcept {
#ifndef NDEBUG
  handle_ = reinterpret_cast<MDBX_env *>(uintptr_t(0xDeadBeef));
#endif
}

MDBX_CXX14_CONSTEXPR env::operator bool() const noexcept {
  return handle_ != nullptr;
}

MDBX_CXX14_CONSTEXPR env::operator const MDBX_env *() const { return handle_; }

MDBX_CXX14_CONSTEXPR env::operator MDBX_env *() { return handle_; }

MDBX_CXX11_CONSTEXPR bool operator==(const env &a, const env &b) noexcept {
  return a.handle_ == b.handle_;
}

MDBX_CXX11_CONSTEXPR bool operator!=(const env &a, const env &b) noexcept {
  return a.handle_ != b.handle_;
}

inline env::geometry &env::geometry::make_fixed(intptr_t size) noexcept {
  size_lower = size_now = size_upper = size;
  growth_step = shrink_threshold = 0;
  return *this;
}

inline env::geometry &env::geometry::make_dynamic(intptr_t lower,
                                                  intptr_t upper) noexcept {
  size_now = size_lower = lower;
  size_upper = upper;
  growth_step = shrink_threshold = default_value;
  return *this;
}

inline env::reclaiming_options env::operate_parameters::reclaiming_from_flags(
    MDBX_env_flags_t flags) noexcept {
  return reclaiming_options(flags);
}

inline env::operate_options
env::operate_parameters::options_from_flags(MDBX_env_flags_t flags) noexcept {
  return operate_options(flags);
}

inline size_t env::limits::pagesize_min() noexcept { return MDBX_MIN_PAGESIZE; }

inline size_t env::limits::pagesize_max() noexcept { return MDBX_MAX_PAGESIZE; }

inline size_t env::limits::dbsize_min(intptr_t pagesize) {
  const intptr_t result = mdbx_limits_dbsize_min(pagesize);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::dbsize_max(intptr_t pagesize) {
  const intptr_t result = mdbx_limits_dbsize_max(pagesize);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::key_min(MDBX_db_flags_t flags) noexcept {
  return (flags & MDBX_INTEGERKEY) ? 4 : 0;
}

inline size_t env::limits::key_min(key_mode mode) noexcept {
  return key_min(MDBX_db_flags_t(mode));
}

inline size_t env::limits::key_max(intptr_t pagesize, MDBX_db_flags_t flags) {
  const intptr_t result = mdbx_limits_keysize_max(pagesize, flags);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::key_max(intptr_t pagesize, key_mode mode) {
  return key_max(pagesize, MDBX_db_flags_t(mode));
}

inline size_t env::limits::key_max(const env &env, MDBX_db_flags_t flags) {
  const intptr_t result = mdbx_env_get_maxkeysize_ex(env, flags);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::key_max(const env &env, key_mode mode) {
  return key_max(env, MDBX_db_flags_t(mode));
}

inline size_t env::limits::value_min(MDBX_db_flags_t flags) noexcept {
  return (flags & MDBX_INTEGERDUP) ? 4 : 0;
}

inline size_t env::limits::value_min(value_mode mode) noexcept {
  return value_min(MDBX_db_flags_t(mode));
}

inline size_t env::limits::value_max(intptr_t pagesize, MDBX_db_flags_t flags) {
  const intptr_t result = mdbx_limits_valsize_max(pagesize, flags);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::value_max(intptr_t pagesize, value_mode mode) {
  return value_max(pagesize, MDBX_db_flags_t(mode));
}

inline size_t env::limits::value_max(const env &env, MDBX_db_flags_t flags) {
  const intptr_t result = mdbx_env_get_maxvalsize_ex(env, flags);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::value_max(const env &env, value_mode mode) {
  return value_max(env, MDBX_db_flags_t(mode));
}

inline size_t env::limits::pairsize4page_max(intptr_t pagesize,
                                             MDBX_db_flags_t flags) {
  const intptr_t result = mdbx_limits_pairsize4page_max(pagesize, flags);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::pairsize4page_max(intptr_t pagesize,
                                             value_mode mode) {
  return pairsize4page_max(pagesize, MDBX_db_flags_t(mode));
}

inline size_t env::limits::pairsize4page_max(const env &env,
                                             MDBX_db_flags_t flags) {
  const intptr_t result = mdbx_env_get_pairsize4page_max(env, flags);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::pairsize4page_max(const env &env, value_mode mode) {
  return pairsize4page_max(env, MDBX_db_flags_t(mode));
}

inline size_t env::limits::valsize4page_max(intptr_t pagesize,
                                            MDBX_db_flags_t flags) {
  const intptr_t result = mdbx_limits_valsize4page_max(pagesize, flags);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::valsize4page_max(intptr_t pagesize,
                                            value_mode mode) {
  return valsize4page_max(pagesize, MDBX_db_flags_t(mode));
}

inline size_t env::limits::valsize4page_max(const env &env,
                                            MDBX_db_flags_t flags) {
  const intptr_t result = mdbx_env_get_valsize4page_max(env, flags);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline size_t env::limits::valsize4page_max(const env &env, value_mode mode) {
  return valsize4page_max(env, MDBX_db_flags_t(mode));
}

inline size_t env::limits::transaction_size_max(intptr_t pagesize) {
  const intptr_t result = mdbx_limits_txnsize_max(pagesize);
  if (result < 0)
    MDBX_CXX20_UNLIKELY error::throw_exception(MDBX_EINVAL);
  return static_cast<size_t>(result);
}

inline env::operate_parameters env::get_operation_parameters() const {
  const auto flags = get_flags();
  return operate_parameters(max_maps(), max_readers(),
                            operate_parameters::mode_from_flags(flags),
                            operate_parameters::durability_from_flags(flags),
                            operate_parameters::reclaiming_from_flags(flags),
                            operate_parameters::options_from_flags(flags));
}

inline env::mode env::get_mode() const {
  return operate_parameters::mode_from_flags(get_flags());
}

inline env::durability env::get_durability() const {
  return env::operate_parameters::durability_from_flags(get_flags());
}

inline env::reclaiming_options env::get_reclaiming() const {
  return env::operate_parameters::reclaiming_from_flags(get_flags());
}

inline env::operate_options env::get_options() const {
  return env::operate_parameters::options_from_flags(get_flags());
}

inline env::stat env::get_stat() const {
  env::stat r;
  error::success_or_throw(::mdbx_env_stat_ex(handle_, nullptr, &r, sizeof(r)));
  return r;
}

inline env::stat env::get_stat(const txn &txn) const {
  env::stat r;
  error::success_or_throw(::mdbx_env_stat_ex(handle_, txn, &r, sizeof(r)));
  return r;
}

inline env::info env::get_info() const {
  env::info r;
  error::success_or_throw(::mdbx_env_info_ex(handle_, nullptr, &r, sizeof(r)));
  return r;
}

inline env::info env::get_info(const txn &txn) const {
  env::info r;
  error::success_or_throw(::mdbx_env_info_ex(handle_, txn, &r, sizeof(r)));
  return r;
}

inline filehandle env::get_filehandle() const {
  filehandle fd;
  error::success_or_throw(::mdbx_env_get_fd(handle_, &fd));
  return fd;
}

inline MDBX_env_flags_t env::get_flags() const {
  unsigned bits;
  error::success_or_throw(::mdbx_env_get_flags(handle_, &bits));
  return MDBX_env_flags_t(bits);
}

inline unsigned env::max_readers() const {
  unsigned r;
  error::success_or_throw(::mdbx_env_get_maxreaders(handle_, &r));
  return r;
}

inline unsigned env::max_maps() const {
  unsigned r;
  error::success_or_throw(::mdbx_env_get_maxdbs(handle_, &r));
  return r;
}

inline void *env::get_context() const noexcept {
  return mdbx_env_get_userctx(handle_);
}

inline env &env::set_context(void *ptr) {
  error::success_or_throw(::mdbx_env_set_userctx(handle_, ptr));
  return *this;
}

inline env &env::set_sync_threshold(size_t bytes) {
  error::success_or_throw(::mdbx_env_set_syncbytes(handle_, bytes));
  return *this;
}

inline env &env::set_sync_period(unsigned seconds_16dot16) {
  error::success_or_throw(::mdbx_env_set_syncperiod(handle_, seconds_16dot16));
  return *this;
}

inline env &env::set_sync_period(double seconds) {
  return set_sync_period(unsigned(seconds * 65536));
}

inline env &env::alter_flags(MDBX_env_flags_t flags, bool on_off) {
  error::success_or_throw(::mdbx_env_set_flags(handle_, flags, on_off));
  return *this;
}

inline env &env::set_geometry(const geometry &geo) {
  error::success_or_throw(::mdbx_env_set_geometry(
      handle_, geo.size_lower, geo.size_now, geo.size_upper, geo.growth_step,
      geo.shrink_threshold, geo.pagesize));
  return *this;
}

inline bool env::sync_to_disk(bool force, bool nonblock) {
  const int err = ::mdbx_env_sync_ex(handle_, force, nonblock);
  switch (err) {
  case MDBX_SUCCESS /* flush done */:
  case MDBX_RESULT_TRUE /* no data pending for flush to disk */:
    return true;
  case MDBX_BUSY /* the environment is used by other thread */:
    return false;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline void env::close_map(const map_handle &handle) {
  error::success_or_throw(::mdbx_dbi_close(*this, handle.dbi));
}

MDBX_CXX11_CONSTEXPR
env::reader_info::reader_info(int slot, mdbx_pid_t pid, mdbx_tid_t thread,
                              uint64_t txnid, uint64_t lag, size_t used,
                              size_t retained) noexcept
    : slot(slot), pid(pid), thread(thread), transaction_id(txnid),
      transaction_lag(lag), bytes_used(used), bytes_retained(retained) {}

template <typename VISITOR>
inline int env::enumerate_readers(VISITOR &visitor) {
  struct reader_visitor_thunk : public exception_thunk {
    VISITOR &visitor_;
    static int cb(void *ctx, int number, int slot, mdbx_pid_t pid,
                  mdbx_tid_t thread, uint64_t txnid, uint64_t lag, size_t used,
                  size_t retained) noexcept {
      reader_visitor_thunk *thunk = static_cast<reader_visitor_thunk *>(ctx);
      assert(thunk->is_clean());
      try {
        const reader_info info(slot, pid, thread, txnid, lag, used, retained);
        return loop_control(thunk->visitor_(info, number));
      } catch (... /* capture any exception to rethrow it over C code */) {
        thunk->capture();
        return loop_control::exit_loop;
      }
    }
    MDBX_CXX11_CONSTEXPR reader_visitor_thunk(VISITOR &visitor) noexcept
        : visitor_(visitor) {}
  };
  reader_visitor_thunk thunk(visitor);
  const auto rc = ::mdbx_reader_list(*this, thunk.cb, &thunk);
  thunk.rethrow_captured();
  return rc;
}

inline unsigned env::check_readers() {
  int dead_count;
  error::throw_on_failure(::mdbx_reader_check(*this, &dead_count));
  assert(dead_count >= 0);
  return static_cast<unsigned>(dead_count);
}

inline env &env::set_HandleSlowReaders(MDBX_hsr_func *cb) {
  error::success_or_throw(::mdbx_env_set_hsr(handle_, cb));
  return *this;
}

inline MDBX_hsr_func *env::get_HandleSlowReaders() const noexcept {
  return ::mdbx_env_get_hsr(handle_);
}

inline txn_managed env::start_read() const {
  ::MDBX_txn *ptr;
  error::success_or_throw(
      ::mdbx_txn_begin(handle_, nullptr, MDBX_TXN_RDONLY, &ptr));
  assert(ptr != nullptr);
  return txn_managed(ptr);
}

inline txn_managed env::prepare_read() const {
  ::MDBX_txn *ptr;
  error::success_or_throw(
      ::mdbx_txn_begin(handle_, nullptr, MDBX_TXN_RDONLY_PREPARE, &ptr));
  assert(ptr != nullptr);
  return txn_managed(ptr);
}

inline txn_managed env::start_write(bool dont_wait) {
  ::MDBX_txn *ptr;
  error::success_or_throw(::mdbx_txn_begin(
      handle_, nullptr, dont_wait ? MDBX_TXN_TRY : MDBX_TXN_READWRITE, &ptr));
  assert(ptr != nullptr);
  return txn_managed(ptr);
}

inline txn_managed env::try_start_write() { return start_write(true); }

//------------------------------------------------------------------------------

MDBX_CXX11_CONSTEXPR txn::txn(MDBX_txn *ptr) noexcept : handle_(ptr) {}

inline txn &txn::operator=(txn &&other) noexcept {
  handle_ = other.handle_;
  other.handle_ = nullptr;
  return *this;
}

inline txn::txn(txn &&other) noexcept : handle_(other.handle_) {
  other.handle_ = nullptr;
}

inline txn::~txn() noexcept {
#ifndef NDEBUG
  handle_ = reinterpret_cast<MDBX_txn *>(uintptr_t(0xDeadBeef));
#endif
}

MDBX_CXX14_CONSTEXPR txn::operator bool() const noexcept {
  return handle_ != nullptr;
}

MDBX_CXX14_CONSTEXPR txn::operator const MDBX_txn *() const { return handle_; }

MDBX_CXX14_CONSTEXPR txn::operator MDBX_txn *() { return handle_; }

MDBX_CXX11_CONSTEXPR bool operator==(const txn &a, const txn &b) noexcept {
  return a.handle_ == b.handle_;
}

MDBX_CXX11_CONSTEXPR bool operator!=(const txn &a, const txn &b) noexcept {
  return a.handle_ != b.handle_;
}

inline bool txn::is_dirty(const void *ptr) const {
  int err = ::mdbx_is_dirty(handle_, ptr);
  switch (err) {
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  case MDBX_RESULT_TRUE:
    return true;
  case MDBX_RESULT_FALSE:
    return false;
  }
}

inline ::mdbx::env txn::env() const noexcept { return ::mdbx_txn_env(handle_); }

inline MDBX_txn_flags_t txn::flags() const {
  const int bits = mdbx_txn_flags(handle_);
  error::throw_on_failure((bits != -1) ? MDBX_SUCCESS : MDBX_BAD_TXN);
  return static_cast<MDBX_txn_flags_t>(bits);
}

inline uint64_t txn::id() const {
  const uint64_t txnid = mdbx_txn_id(handle_);
  error::throw_on_failure(txnid ? MDBX_SUCCESS : MDBX_BAD_TXN);
  return txnid;
}

inline void txn::reset_reading() {
  error::success_or_throw(::mdbx_txn_reset(handle_));
}

inline void txn::renew_reading() {
  error::success_or_throw(::mdbx_txn_renew(handle_));
}

inline txn::info txn::get_info(bool scan_reader_lock_table) const {
  txn::info r;
  error::success_or_throw(::mdbx_txn_info(handle_, &r, scan_reader_lock_table));
  return r;
}

inline cursor_managed txn::open_cursor(map_handle map) {
  MDBX_cursor *ptr;
  error::success_or_throw(::mdbx_cursor_open(handle_, map.dbi, &ptr));
  return cursor_managed(ptr);
}

inline ::mdbx::map_handle
txn::open_map(const char *name, const ::mdbx::key_mode key_mode,
              const ::mdbx::value_mode value_mode) const {
  ::mdbx::map_handle map;
  error::success_or_throw(::mdbx_dbi_open(
      handle_, name, MDBX_db_flags_t(key_mode) | MDBX_db_flags_t(value_mode),
      &map.dbi));
  assert(map.dbi != 0);
  return map;
}

inline ::mdbx::map_handle
txn::open_map(const ::std::string &name, const ::mdbx::key_mode key_mode,
              const ::mdbx::value_mode value_mode) const {
  return open_map(name.c_str(), key_mode, value_mode);
}

inline ::mdbx::map_handle txn::create_map(const char *name,
                                          const ::mdbx::key_mode key_mode,
                                          const ::mdbx::value_mode value_mode) {
  ::mdbx::map_handle map;
  error::success_or_throw(::mdbx_dbi_open(
      handle_, name,
      MDBX_CREATE | MDBX_db_flags_t(key_mode) | MDBX_db_flags_t(value_mode),
      &map.dbi));
  assert(map.dbi != 0);
  return map;
}

inline ::mdbx::map_handle txn::create_map(const ::std::string &name,
                                          const ::mdbx::key_mode key_mode,
                                          const ::mdbx::value_mode value_mode) {
  return create_map(name.c_str(), key_mode, value_mode);
}

inline void txn::drop_map(map_handle map) {
  error::success_or_throw(::mdbx_drop(handle_, map.dbi, true));
}

inline bool txn::drop_map(const ::std::string &name, bool throw_if_absent) {
  return drop_map(name.c_str(), throw_if_absent);
}

inline void txn::clear_map(map_handle map) {
  error::success_or_throw(::mdbx_drop(handle_, map.dbi, false));
}

inline bool txn::clear_map(const ::std::string &name, bool throw_if_absent) {
  return clear_map(name.c_str(), throw_if_absent);
}

inline txn::map_stat txn::get_map_stat(map_handle map) const {
  txn::map_stat r;
  error::success_or_throw(::mdbx_dbi_stat(handle_, map.dbi, &r, sizeof(r)));
  return r;
}

inline uint32_t txn::get_tree_deepmask(map_handle map) const {
  uint32_t r;
  error::success_or_throw(::mdbx_dbi_dupsort_depthmask(handle_, map.dbi, &r));
  return r;
}

inline map_handle::info txn::get_handle_info(map_handle map) const {
  unsigned flags, state;
  error::success_or_throw(
      ::mdbx_dbi_flags_ex(handle_, map.dbi, &flags, &state));
  return map_handle::info(MDBX_db_flags_t(flags), MDBX_dbi_state_t(state));
}

inline txn &txn::put_canary(const txn::canary &canary) {
  error::success_or_throw(::mdbx_canary_put(handle_, &canary));
  return *this;
}

inline txn::canary txn::get_canary() const {
  txn::canary r;
  error::success_or_throw(::mdbx_canary_get(handle_, &r));
  return r;
}

inline uint64_t txn::sequence(map_handle map) const {
  uint64_t result;
  error::success_or_throw(::mdbx_dbi_sequence(handle_, map.dbi, &result, 0));
  return result;
}

inline uint64_t txn::sequence(map_handle map, uint64_t increment) {
  uint64_t result;
  error::success_or_throw(
      ::mdbx_dbi_sequence(handle_, map.dbi, &result, increment));
  return result;
}

inline int txn::compare_keys(map_handle map, const slice &a,
                             const slice &b) const noexcept {
  return ::mdbx_cmp(handle_, map.dbi, &a, &b);
}

inline int txn::compare_values(map_handle map, const slice &a,
                               const slice &b) const noexcept {
  return ::mdbx_dcmp(handle_, map.dbi, &a, &b);
}

inline int txn::compare_keys(map_handle map, const pair &a,
                             const pair &b) const noexcept {
  return compare_keys(map, a.key, b.key);
}

inline int txn::compare_values(map_handle map, const pair &a,
                               const pair &b) const noexcept {
  return compare_values(map, a.value, b.value);
}

inline slice txn::get(map_handle map, const slice &key) const {
  slice result;
  error::success_or_throw(::mdbx_get(handle_, map.dbi, &key, &result));
  return result;
}

inline slice txn::get(map_handle map, slice key, size_t &values_count) const {
  slice result;
  error::success_or_throw(
      ::mdbx_get_ex(handle_, map.dbi, &key, &result, &values_count));
  return result;
}

inline slice txn::get(map_handle map, const slice &key,
                      const slice &value_at_absence) const {
  slice result;
  const int err = ::mdbx_get(handle_, map.dbi, &key, &result);
  switch (err) {
  case MDBX_SUCCESS:
    return result;
  case MDBX_NOTFOUND:
    return value_at_absence;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline slice txn::get(map_handle map, slice key, size_t &values_count,
                      const slice &value_at_absence) const {
  slice result;
  const int err = ::mdbx_get_ex(handle_, map.dbi, &key, &result, &values_count);
  switch (err) {
  case MDBX_SUCCESS:
    return result;
  case MDBX_NOTFOUND:
    return value_at_absence;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline pair_result txn::get_equal_or_great(map_handle map,
                                           const slice &key) const {
  pair result(key, slice());
  bool exact = !error::boolean_or_throw(
      ::mdbx_get_equal_or_great(handle_, map.dbi, &result.key, &result.value));
  return pair_result(result.key, result.value, exact);
}

inline pair_result
txn::get_equal_or_great(map_handle map, const slice &key,
                        const slice &value_at_absence) const {
  pair result{key, slice()};
  const int err =
      ::mdbx_get_equal_or_great(handle_, map.dbi, &result.key, &result.value);
  switch (err) {
  case MDBX_SUCCESS:
    return pair_result{result.key, result.value, true};
  case MDBX_RESULT_TRUE:
    return pair_result{result.key, result.value, false};
  case MDBX_NOTFOUND:
    return pair_result{key, value_at_absence, false};
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline MDBX_error_t txn::put(map_handle map, const slice &key, slice *value,
                             MDBX_put_flags_t flags) noexcept {
  return MDBX_error_t(::mdbx_put(handle_, map.dbi, &key, value, flags));
}

inline void txn::put(map_handle map, const slice &key, slice value,
                     put_mode mode) {
  error::success_or_throw(put(map, key, &value, MDBX_put_flags_t(mode)));
}

inline void txn::insert(map_handle map, const slice &key, slice value) {
  error::success_or_throw(
      put(map, key, &value /* takes the present value in case MDBX_KEYEXIST */,
          MDBX_put_flags_t(put_mode::insert_unique)));
}

inline value_result txn::try_insert(map_handle map, const slice &key,
                                    slice value) {
  const int err =
      put(map, key, &value /* takes the present value in case MDBX_KEYEXIST */,
          MDBX_put_flags_t(put_mode::insert_unique));
  switch (err) {
  case MDBX_SUCCESS:
    return value_result{slice(), true};
  case MDBX_KEYEXIST:
    return value_result{value, false};
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline slice txn::insert_reserve(map_handle map, const slice &key,
                                 size_t value_length) {
  slice result(nullptr, value_length);
  error::success_or_throw(
      put(map, key, &result /* takes the present value in case MDBX_KEYEXIST */,
          MDBX_put_flags_t(put_mode::insert_unique) | MDBX_RESERVE));
  return result;
}

inline value_result txn::try_insert_reserve(map_handle map, const slice &key,
                                            size_t value_length) {
  slice result(nullptr, value_length);
  const int err =
      put(map, key, &result /* takes the present value in case MDBX_KEYEXIST */,
          MDBX_put_flags_t(put_mode::insert_unique) | MDBX_RESERVE);
  switch (err) {
  case MDBX_SUCCESS:
    return value_result{result, true};
  case MDBX_KEYEXIST:
    return value_result{result, false};
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline void txn::upsert(map_handle map, const slice &key, const slice &value) {
  error::success_or_throw(put(map, key, const_cast<slice *>(&value),
                              MDBX_put_flags_t(put_mode::upsert)));
}

inline slice txn::upsert_reserve(map_handle map, const slice &key,
                                 size_t value_length) {
  slice result(nullptr, value_length);
  error::success_or_throw(put(
      map, key, &result, MDBX_put_flags_t(put_mode::upsert) | MDBX_RESERVE));
  return result;
}

inline void txn::update(map_handle map, const slice &key, const slice &value) {
  error::success_or_throw(put(map, key, const_cast<slice *>(&value),
                              MDBX_put_flags_t(put_mode::update)));
}

inline bool txn::try_update(map_handle map, const slice &key,
                            const slice &value) {
  const int err = put(map, key, const_cast<slice *>(&value),
                      MDBX_put_flags_t(put_mode::update));
  switch (err) {
  case MDBX_SUCCESS:
    return true;
  case MDBX_NOTFOUND:
    return false;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline slice txn::update_reserve(map_handle map, const slice &key,
                                 size_t value_length) {
  slice result(nullptr, value_length);
  error::success_or_throw(put(
      map, key, &result, MDBX_put_flags_t(put_mode::update) | MDBX_RESERVE));
  return result;
}

inline value_result txn::try_update_reserve(map_handle map, const slice &key,
                                            size_t value_length) {
  slice result(nullptr, value_length);
  const int err =
      put(map, key, &result, MDBX_put_flags_t(put_mode::update) | MDBX_RESERVE);
  switch (err) {
  case MDBX_SUCCESS:
    return value_result{result, true};
  case MDBX_NOTFOUND:
    return value_result{slice(), false};
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline bool txn::erase(map_handle map, const slice &key) {
  const int err = ::mdbx_del(handle_, map.dbi, &key, nullptr);
  switch (err) {
  case MDBX_SUCCESS:
    return true;
  case MDBX_NOTFOUND:
    return false;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline bool txn::erase(map_handle map, const slice &key, const slice &value) {
  const int err = ::mdbx_del(handle_, map.dbi, &key, &value);
  switch (err) {
  case MDBX_SUCCESS:
    return true;
  case MDBX_NOTFOUND:
    return false;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline void txn::replace(map_handle map, const slice &key, slice old_value,
                         const slice &new_value) {
  error::success_or_throw(::mdbx_replace_ex(
      handle_, map.dbi, &key, const_cast<slice *>(&new_value), &old_value,
      MDBX_CURRENT | MDBX_NOOVERWRITE, nullptr, nullptr));
}

template <class ALLOCATOR, typename CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
txn::extract(map_handle map, const slice &key,
             const typename buffer<ALLOCATOR, CAPACITY_POLICY>::allocator_type
                 &allocator) {
  typename buffer<ALLOCATOR, CAPACITY_POLICY>::data_preserver result(allocator);
  error::success_or_throw(::mdbx_replace_ex(handle_, map.dbi, &key, nullptr,
                                            &result.slice_, MDBX_CURRENT,
                                            result, &result),
                          result);
  return result;
}

template <class ALLOCATOR, typename CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY>
txn::replace(map_handle map, const slice &key, const slice &new_value,
             const typename buffer<ALLOCATOR, CAPACITY_POLICY>::allocator_type
                 &allocator) {
  typename buffer<ALLOCATOR, CAPACITY_POLICY>::data_preserver result(allocator);
  error::success_or_throw(
      ::mdbx_replace_ex(handle_, map.dbi, &key, const_cast<slice *>(&new_value),
                        &result.slice_, MDBX_CURRENT, result, &result),
      result);
  return result;
}

template <class ALLOCATOR, typename CAPACITY_POLICY>
inline buffer<ALLOCATOR, CAPACITY_POLICY> txn::replace_reserve(
    map_handle map, const slice &key, slice &new_value,
    const typename buffer<ALLOCATOR, CAPACITY_POLICY>::allocator_type
        &allocator) {
  typename buffer<ALLOCATOR, CAPACITY_POLICY>::data_preserver result(allocator);
  error::success_or_throw(
      ::mdbx_replace_ex(handle_, map.dbi, &key, &new_value, &result.slice_,
                        MDBX_CURRENT | MDBX_RESERVE, result, &result),
      result);
  return result;
}

inline void txn::append(map_handle map, const slice &key, const slice &value,
                        bool multivalue_order_preserved) {
  error::success_or_throw(::mdbx_put(
      handle_, map.dbi, const_cast<slice *>(&key), const_cast<slice *>(&value),
      multivalue_order_preserved ? (MDBX_APPEND | MDBX_APPENDDUP)
                                 : MDBX_APPEND));
}

inline size_t txn::put_multiple(map_handle map, const slice &key,
                                const size_t value_length,
                                const void *values_array, size_t values_count,
                                put_mode mode, bool allow_partial) {
  MDBX_val args[2] = {{const_cast<void *>(values_array), value_length},
                      {nullptr, values_count}};
  const int err = ::mdbx_put(handle_, map.dbi, const_cast<slice *>(&key), args,
                             MDBX_put_flags_t(mode) | MDBX_MULTIPLE);
  switch (err) {
  case MDBX_SUCCESS:
    MDBX_CXX20_LIKELY break;
  case MDBX_KEYEXIST:
    if (allow_partial)
      break;
    mdbx_txn_break(handle_);
    MDBX_CXX17_FALLTHROUGH /* fallthrough */;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
  return args[1].iov_len /* done item count */;
}

inline ptrdiff_t txn::estimate(map_handle map, pair from, pair to) const {
  ptrdiff_t result;
  error::success_or_throw(mdbx_estimate_range(
      handle_, map.dbi, &from.key, &from.value, &to.key, &to.value, &result));
  return result;
}

inline ptrdiff_t txn::estimate(map_handle map, slice from, slice to) const {
  ptrdiff_t result;
  error::success_or_throw(mdbx_estimate_range(handle_, map.dbi, &from, nullptr,
                                              &to, nullptr, &result));
  return result;
}

inline ptrdiff_t txn::estimate_from_first(map_handle map, slice to) const {
  ptrdiff_t result;
  error::success_or_throw(mdbx_estimate_range(handle_, map.dbi, nullptr,
                                              nullptr, &to, nullptr, &result));
  return result;
}

inline ptrdiff_t txn::estimate_to_last(map_handle map, slice from) const {
  ptrdiff_t result;
  error::success_or_throw(mdbx_estimate_range(handle_, map.dbi, &from, nullptr,
                                              nullptr, nullptr, &result));
  return result;
}

//------------------------------------------------------------------------------

MDBX_CXX11_CONSTEXPR cursor::cursor(MDBX_cursor *ptr) noexcept : handle_(ptr) {}

inline cursor &cursor::operator=(cursor &&other) noexcept {
  handle_ = other.handle_;
  other.handle_ = nullptr;
  return *this;
}

inline cursor::cursor(cursor &&other) noexcept : handle_(other.handle_) {
  other.handle_ = nullptr;
}

inline cursor::~cursor() noexcept {
#ifndef NDEBUG
  handle_ = reinterpret_cast<MDBX_cursor *>(uintptr_t(0xDeadBeef));
#endif
}

MDBX_CXX14_CONSTEXPR cursor::operator bool() const noexcept {
  return handle_ != nullptr;
}

MDBX_CXX14_CONSTEXPR cursor::operator const MDBX_cursor *() const {
  return handle_;
}

MDBX_CXX14_CONSTEXPR cursor::operator MDBX_cursor *() { return handle_; }

MDBX_CXX11_CONSTEXPR bool operator==(const cursor &a,
                                     const cursor &b) noexcept {
  return a.handle_ == b.handle_;
}

MDBX_CXX11_CONSTEXPR bool operator!=(const cursor &a,
                                     const cursor &b) noexcept {
  return a.handle_ != b.handle_;
}

inline cursor::move_result::move_result(const cursor &cursor,
                                        bool throw_notfound)
    : pair_result(key, value, false) {
  done = cursor.move(get_current, &key, &value, throw_notfound);
}

inline cursor::move_result::move_result(cursor &cursor,
                                        move_operation operation,
                                        bool throw_notfound)
    : pair_result(key, value, false) {
  done = cursor.move(operation, &key, &value, throw_notfound);
}

inline cursor::move_result::move_result(cursor &cursor,
                                        move_operation operation,
                                        const slice &key, bool throw_notfound)
    : pair_result(key, slice(), false) {
  this->done = cursor.move(operation, &this->key, &this->value, throw_notfound);
}

inline cursor::move_result::move_result(cursor &cursor,
                                        move_operation operation,
                                        const slice &key, const slice &value,
                                        bool throw_notfound)
    : pair_result(key, value, false) {
  this->done = cursor.move(operation, &this->key, &this->value, throw_notfound);
}

inline bool cursor::move(move_operation operation, MDBX_val *key,
                         MDBX_val *value, bool throw_notfound) const {
  const int err =
      ::mdbx_cursor_get(handle_, key, value, MDBX_cursor_op(operation));
  switch (err) {
  case MDBX_SUCCESS:
    MDBX_CXX20_LIKELY return true;
  case MDBX_NOTFOUND:
    if (!throw_notfound)
      return false;
    MDBX_CXX17_FALLTHROUGH /* fallthrough */;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline ptrdiff_t cursor::estimate(move_operation operation, MDBX_val *key,
                                  MDBX_val *value) const {
  ptrdiff_t result;
  error::success_or_throw(::mdbx_estimate_move(
      *this, key, value, MDBX_cursor_op(operation), &result));
  return result;
}

inline ptrdiff_t estimate(const cursor &from, const cursor &to) {
  ptrdiff_t result;
  error::success_or_throw(mdbx_estimate_distance(from, to, &result));
  return result;
}

inline cursor::move_result cursor::move(move_operation operation,
                                        bool throw_notfound) {
  return move_result(*this, operation, throw_notfound);
}

inline cursor::move_result cursor::to_first(bool throw_notfound) {
  return move(first, throw_notfound);
}

inline cursor::move_result cursor::to_previous(bool throw_notfound) {
  return move(previous, throw_notfound);
}

inline cursor::move_result cursor::to_previous_last_multi(bool throw_notfound) {
  return move(multi_prevkey_lastvalue, throw_notfound);
}

inline cursor::move_result cursor::to_current_first_multi(bool throw_notfound) {
  return move(multi_currentkey_firstvalue, throw_notfound);
}

inline cursor::move_result cursor::to_current_prev_multi(bool throw_notfound) {
  return move(multi_currentkey_prevvalue, throw_notfound);
}

inline cursor::move_result cursor::current(bool throw_notfound) const {
  return move_result(*this, throw_notfound);
}

inline cursor::move_result cursor::to_current_next_multi(bool throw_notfound) {
  return move(multi_currentkey_nextvalue, throw_notfound);
}

inline cursor::move_result cursor::to_current_last_multi(bool throw_notfound) {
  return move(multi_currentkey_lastvalue, throw_notfound);
}

inline cursor::move_result cursor::to_next_first_multi(bool throw_notfound) {
  return move(multi_nextkey_firstvalue, throw_notfound);
}

inline cursor::move_result cursor::to_next(bool throw_notfound) {
  return move(next, throw_notfound);
}

inline cursor::move_result cursor::to_last(bool throw_notfound) {
  return move(last, throw_notfound);
}

inline cursor::move_result cursor::move(move_operation operation,
                                        const slice &key, bool throw_notfound) {
  return move_result(*this, operation, key, throw_notfound);
}

inline cursor::move_result cursor::find(const slice &key, bool throw_notfound) {
  return move(key_exact, key, throw_notfound);
}

inline cursor::move_result cursor::lower_bound(const slice &key,
                                               bool throw_notfound) {
  return move(key_lowerbound, key, throw_notfound);
}

inline cursor::move_result cursor::move(move_operation operation,
                                        const slice &key, const slice &value,
                                        bool throw_notfound) {
  return move_result(*this, operation, key, value, throw_notfound);
}

inline cursor::move_result cursor::find_multivalue(const slice &key,
                                                   const slice &value,
                                                   bool throw_notfound) {
  return move(multi_find_pair, key, value, throw_notfound);
}

inline cursor::move_result cursor::lower_bound_multivalue(const slice &key,
                                                          const slice &value,
                                                          bool throw_notfound) {
  return move(multi_exactkey_lowerboundvalue, key, value, throw_notfound);
}

inline bool cursor::seek(const slice &key) {
  return move(find_key, const_cast<slice *>(&key), nullptr, false);
}

inline bool cursor::move(move_operation operation, slice &key, slice &value,
                         bool throw_notfound) {
  return move(operation, &key, &value, throw_notfound);
}

inline size_t cursor::count_multivalue() const {
  size_t result;
  error::success_or_throw(::mdbx_cursor_count(*this, &result));
  return result;
}

inline bool cursor::eof() const {
  return error::boolean_or_throw(::mdbx_cursor_eof(*this));
}

inline bool cursor::on_first() const {
  return error::boolean_or_throw(::mdbx_cursor_on_first(*this));
}

inline bool cursor::on_last() const {
  return error::boolean_or_throw(::mdbx_cursor_on_last(*this));
}

inline ptrdiff_t cursor::estimate(slice key, slice value) const {
  return estimate(multi_exactkey_lowerboundvalue, &key, &value);
}

inline ptrdiff_t cursor::estimate(slice key) const {
  return estimate(key_lowerbound, &key, nullptr);
}

inline ptrdiff_t cursor::estimate(move_operation operation) const {
  slice unused_key;
  return estimate(operation, &unused_key, nullptr);
}

inline void cursor::renew(::mdbx::txn &txn) {
  error::success_or_throw(::mdbx_cursor_renew(txn, handle_));
}

inline void cursor::bind(::mdbx::txn &txn, ::mdbx::map_handle map_handle) {
  error::success_or_throw(::mdbx_cursor_bind(txn, handle_, map_handle.dbi));
}

inline txn cursor::txn() const {
  MDBX_txn *txn = ::mdbx_cursor_txn(handle_);
  error::throw_on_nullptr(txn, MDBX_EINVAL);
  return ::mdbx::txn(txn);
}

inline map_handle cursor::map() const {
  const MDBX_dbi dbi = ::mdbx_cursor_dbi(handle_);
  if (MDBX_UNLIKELY(dbi > MDBX_MAX_DBI))
    error::throw_exception(MDBX_EINVAL);
  return map_handle(dbi);
}

inline MDBX_error_t cursor::put(const slice &key, slice *value,
                                MDBX_put_flags_t flags) noexcept {
  return MDBX_error_t(::mdbx_cursor_put(handle_, &key, value, flags));
}

inline void cursor::insert(const slice &key, slice value) {
  error::success_or_throw(
      put(key, &value /* takes the present value in case MDBX_KEYEXIST */,
          MDBX_put_flags_t(put_mode::insert_unique)));
}

inline value_result cursor::try_insert(const slice &key, slice value) {
  const int err =
      put(key, &value /* takes the present value in case MDBX_KEYEXIST */,
          MDBX_put_flags_t(put_mode::insert_unique));
  switch (err) {
  case MDBX_SUCCESS:
    return value_result{slice(), true};
  case MDBX_KEYEXIST:
    return value_result{value, false};
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline slice cursor::insert_reserve(const slice &key, size_t value_length) {
  slice result(nullptr, value_length);
  error::success_or_throw(
      put(key, &result /* takes the present value in case MDBX_KEYEXIST */,
          MDBX_put_flags_t(put_mode::insert_unique) | MDBX_RESERVE));
  return result;
}

inline value_result cursor::try_insert_reserve(const slice &key,
                                               size_t value_length) {
  slice result(nullptr, value_length);
  const int err =
      put(key, &result /* takes the present value in case MDBX_KEYEXIST */,
          MDBX_put_flags_t(put_mode::insert_unique) | MDBX_RESERVE);
  switch (err) {
  case MDBX_SUCCESS:
    return value_result{result, true};
  case MDBX_KEYEXIST:
    return value_result{result, false};
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline void cursor::upsert(const slice &key, const slice &value) {
  error::success_or_throw(put(key, const_cast<slice *>(&value),
                              MDBX_put_flags_t(put_mode::upsert)));
}

inline slice cursor::upsert_reserve(const slice &key, size_t value_length) {
  slice result(nullptr, value_length);
  error::success_or_throw(
      put(key, &result, MDBX_put_flags_t(put_mode::upsert) | MDBX_RESERVE));
  return result;
}

inline void cursor::update(const slice &key, const slice &value) {
  error::success_or_throw(put(key, const_cast<slice *>(&value),
                              MDBX_put_flags_t(put_mode::update)));
}

inline bool cursor::try_update(const slice &key, const slice &value) {
  const int err =
      put(key, const_cast<slice *>(&value), MDBX_put_flags_t(put_mode::update));
  switch (err) {
  case MDBX_SUCCESS:
    return true;
  case MDBX_NOTFOUND:
    return false;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline slice cursor::update_reserve(const slice &key, size_t value_length) {
  slice result(nullptr, value_length);
  error::success_or_throw(
      put(key, &result, MDBX_put_flags_t(put_mode::update) | MDBX_RESERVE));
  return result;
}

inline value_result cursor::try_update_reserve(const slice &key,
                                               size_t value_length) {
  slice result(nullptr, value_length);
  const int err =
      put(key, &result, MDBX_put_flags_t(put_mode::update) | MDBX_RESERVE);
  switch (err) {
  case MDBX_SUCCESS:
    return value_result{result, true};
  case MDBX_NOTFOUND:
    return value_result{slice(), false};
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline bool cursor::erase(bool whole_multivalue) {
  const int err = ::mdbx_cursor_del(handle_, whole_multivalue ? MDBX_ALLDUPS
                                                              : MDBX_CURRENT);
  switch (err) {
  case MDBX_SUCCESS:
    MDBX_CXX20_LIKELY return true;
  case MDBX_NOTFOUND:
    return false;
  default:
    MDBX_CXX20_UNLIKELY error::throw_exception(err);
  }
}

inline bool cursor::erase(const slice &key, bool whole_multivalue) {
  bool found = seek(key);
  return found ? erase(whole_multivalue) : found;
}

inline bool cursor::erase(const slice &key, const slice &value) {
  move_result data = find_multivalue(key, value, false);
  return data.done && erase();
}

/// end cxx_api @}
} // namespace mdbx

//------------------------------------------------------------------------------

/// \brief The `std:: namespace part of libmdbx C++ API
/// \ingroup cxx_api
namespace std {

/// \defgroup cxx_api C++ API
/// @{

inline string to_string(const ::mdbx::slice &value) {
  ostringstream out;
  out << value;
  return out.str();
}

template <class ALLOCATOR, typename CAPACITY_POLICY>
inline string
to_string(const ::mdbx::buffer<ALLOCATOR, CAPACITY_POLICY> &buffer) {
  ostringstream out;
  out << buffer;
  return out.str();
}

inline string to_string(const ::mdbx::pair &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::mdbx::env::geometry &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::mdbx::env::operate_parameters &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::mdbx::env::mode &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::mdbx::env::durability &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::mdbx::env::reclaiming_options &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::mdbx::env::operate_options &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::mdbx::env_managed::create_parameters &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::MDBX_log_level_t &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::MDBX_debug_flags_t &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::mdbx::error &value) {
  ostringstream out;
  out << value;
  return out.str();
}

inline string to_string(const ::MDBX_error_t &errcode) {
  return to_string(::mdbx::error(errcode));
}

template <> struct hash<::mdbx::slice> {
  MDBX_CXX14_CONSTEXPR size_t
  operator()(::mdbx::slice const &slice) const noexcept {
    return slice.hash_value();
  }
};

/// end cxx_api @}
} // namespace std

#if defined(__LCC__) && __LCC__ >= 126
#pragma diagnostic pop
#endif

#ifdef _MSC_VER
#pragma warning(pop)
#endif