Initial preparations for CURL and Discord integration.

2024-11-08 00:37:15 +01:00 · 2021-01-27 07:27:48 +02:00 · 2021-01-27 07:27:48 +02:00 · 95705e87c8
commit 95705e87c8
parent 8257eb61d6
1751 changed files with 440547 additions and 854 deletions
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@ -8,19 +8,44 @@ set(CMAKE_MODULE_PATH ${PROJECT_SOURCE_DIR}/cmake)
 option(BUILTIN_RUNTIMES "Include the MinGW runtime into the binary itself." ON)
 option(LTO_ENABLED "Enable link time optimizations (takes a long time to compile!)." OFF)
 option(FORCE_32BIT_BIN "Create a 32-bit executable binary if the compiler defaults to 64-bit." OFF)
-option(ENABLE_MYSQL "Enable the MySQL library." OFF)
+option(ENABLE_CURL "Enable the CURL library." ON)
 option(ENABLE_MYSQL "Enable the MySQL library." ON)
 option(ENABLE_MYSQL_OPENSSL "Enable MySQL library to use OpenSSL (windows only)." ON)
 option(ENABLE_API21 "Build for 2.1 API." OFF)
-# Default to c++14 standard
+include(CMakeDependentOption)
 # Discord depends on CURL
 cmake_dependent_option(ENABLE_DISCORD "Enable the Discord library." ON "ENABLE_CURL" OFF)
 include(CheckCXXCompilerFlag)
 # C++ standard availability check
 check_cxx_compiler_flag(-std=c++20 HAVE_FLAG_STD_CXX20)
 if(HAVE_FLAG_STD_CXX20)
 	# We can use C++20
    set(CPP_STD_NUMBER 20)
 else()
 	check_cxx_compiler_flag(-std=c++17 HAVE_FLAG_STD_CXX17)
    if(HAVE_FLAG_STD_CXX17)
 		# We can use C++17
 		set(CPP_STD_NUMBER 17)
    else()
 		# C++14 is mandatory
 		set(CPP_STD_NUMBER 14)
    endif()
 endif()
 message(STATUS "Using C++${CPP_STD_NUMBER} standard.")
 # Default to the identified standard
 if(CMAKE_VERSION VERSION_LESS "3.1")
 	if(CMAKE_CXX_COMPILER_ID STREQUAL "GNU")
-		set (CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -std=c++14")
+		set (CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -std=c++${CPP_STD_NUMBER}")
 	endif()
 else()
 	# Apparently the above does not work with cmake from on debian 8
-	set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -std=c++14")
+	set(CMAKE_CXX_FLAGS "${CMAKE_CXX_FLAGS} -std=c++${CPP_STD_NUMBER}")
 	# Try the standard method as well
-	set(CMAKE_CXX_STANDARD 14)
+	set(CMAKE_CXX_STANDARD ${CPP_STD_NUMBER})
 	set(CMAKE_CXX_STANDARD_REQUIRED ON)
 endif()
--- a/module/Base/AABB.cpp
+++ b/module/Base/AABB.cpp
@ -793,10 +793,7 @@ const AABB & AABB::GetEx(SQChar delim, StackStrF & str)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_AABB(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef AABB::Value Val;
--- a/module/Base/Buffer.cpp
+++ b/module/Base/Buffer.cpp
@ -343,7 +343,7 @@ private:
 };
 // ------------------------------------------------------------------------------------------------
-MemRef MemRef::s_Mem;
+MemRef MemRef::s_Mem{nullptr};
 // ------------------------------------------------------------------------------------------------
 void MemRef::Grab()
--- a/module/Base/Buffer.hpp
+++ b/module/Base/Buffer.hpp
@ -59,6 +59,15 @@ public:
        Grab();
    }
    /* --------------------------------------------------------------------------------------------
     * Default constructor (null).
    */
    explicit MemRef(std::nullptr_t) noexcept
            : m_Ptr(nullptr)
            , m_Ref(nullptr)
    {
    }
    /* --------------------------------------------------------------------------------------------
     * Copy constructor.
    */
@ -877,7 +886,7 @@ public:
            // Request the memory
            Request(n * sizeof(T));
            // Return the backup
-            return std::move(bkp);
+            return bkp;
        }
        // Return an empty buffer
        return Buffer();
--- a/module/Base/Circle.cpp
+++ b/module/Base/Circle.cpp
@ -551,10 +551,7 @@ const Circle & Circle::GetEx(SQChar delim, StackStrF & str)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_Circle(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef Circle::Value Val;
--- a/module/Base/Color3.cpp
+++ b/module/Base/Color3.cpp
@ -740,10 +740,7 @@ static void SqSetColor3UpperCaseHex(bool t)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_Color3(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef Color3::Value Val;
--- a/module/Base/Color4.cpp
+++ b/module/Base/Color4.cpp
@ -777,10 +777,7 @@ static void SqSetColor4UpperCaseHex(bool t)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_Color4(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef Color4::Value Val;
--- a/module/Base/DynArg.hpp
+++ b/module/Base/DynArg.hpp
@ -398,10 +398,7 @@ template < typename F, typename U, typename... Ts > SQInteger SqDynArgFwd(HSQUIR
        return sq_throwerror(vm, "Unknown error occurred during comparison");
    }
    // We shouldn't really reach this point but something must be returned
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "OCDFAInspection"
    return sq_throwerror(vm, "Operation encountered unknown behavior");
 #pragma clang diagnostic pop
 }
 /* ------------------------------------------------------------------------------------------------
--- a/module/Base/Quaternion.cpp
+++ b/module/Base/Quaternion.cpp
@ -771,10 +771,7 @@ const Quaternion & Quaternion::GetEx(SQChar delim, StackStrF & str)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_Quaternion(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef Quaternion::Value Val;
--- a/module/Base/Sphere.cpp
+++ b/module/Base/Sphere.cpp
@ -525,10 +525,7 @@ const Sphere & Sphere::GetEx(SQChar delim, StackStrF & str)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_Sphere(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef Sphere::Value Val;
--- a/module/Base/Vector2.cpp
+++ b/module/Base/Vector2.cpp
@ -431,10 +431,7 @@ const Vector2 & Vector2::GetEx(SQChar delim, StackStrF & str)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_Vector2(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef Vector2::Value Val;
--- a/module/Base/Vector2i.cpp
+++ b/module/Base/Vector2i.cpp
@ -577,10 +577,7 @@ const Vector2i & Vector2i::GetEx(SQChar delim, StackStrF & str)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_Vector2i(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef Vector2i::Value Val;
--- a/module/Base/Vector3.cpp
+++ b/module/Base/Vector3.cpp
@ -685,10 +685,7 @@ const Vector3 & Vector3::GetEx(SQChar delim, StackStrF & str)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_Vector3(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef Vector3::Value Val;
--- a/module/Base/Vector4.cpp
+++ b/module/Base/Vector4.cpp
@ -522,10 +522,7 @@ const Vector4 & Vector4::GetEx(SQChar delim, StackStrF & str)
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_Vector4(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    typedef Vector4::Value Val;
--- a/module/CMakeLists.txt
+++ b/module/CMakeLists.txt
@ -86,8 +86,32 @@ if(GCC OR MINGW)
 endif()
 # Link to libraries
 target_link_libraries(SqModule SqModSDK FmtLib SimpleINI HashLib B64Lib AES256Lib WhirlpoolLib TinyDir PUGIXML SQLite MaxmindDB SimpleSocket ConcurrentQueue)
 # Link to Discord libraries
 if(ENABLE_DISCORD)
 	# Discord needs CURL to be on
 	set(ENABLE_CURL ON CACHE INTERNAL "" FORCE)
 	# Link to necessary libraries
 	target_link_libraries(SqModule sleepy-discord)
 	# Include the implementation 
 	target_sources(SqModule PRIVATE Library/Discord.cpp Library/Discord.hpp)
 	# Specify that Discord is enabled
 	target_compile_definitions(SqModule PRIVATE SQ_ENABLE_DISCORD=1)
 endif()
 # Link to CURL libraries
 if(ENABLE_CURL)
 	# Link to necessary libraries
 	target_link_libraries(SqModule libcurl cpr::cpr)
 	# Windows needs a few extra libraries
 	if(WIN32)
 		target_link_libraries(SqModule wldap32 ws2_32)
 	endif(WIN32)
 	# Include the implementation
 	target_sources(SqModule PRIVATE Library/CURL.cpp Library/CURL.hpp)
 	# Specify that CURL is enabled
 	target_compile_definitions(SqModule PRIVATE SQ_ENABLE_CURL=1)
 endif()
 # Enable LTO
-if (LTO_ENABLED)
+if(LTO_ENABLED)
 	target_link_libraries(SqModule -flto)
 endif()
 # Link to mysql client library
--- a/module/Core/Events.inc
+++ b/module/Core/Events.inc
@ -232,8 +232,6 @@ void Core::EmitServerFrame(Float32 elapsed_time)
    //SQMOD_CO_EV_TRACEBACK("[TRACE>] Core::ServerFrame")
 }
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "MemberFunctionCanBeStatic"
 // ------------------------------------------------------------------------------------------------
 void Core::EmitPluginCommand(Uint32 command_identifier, CCStr message)
 {
@ -247,7 +245,6 @@ void Core::EmitPluginCommand(Uint32 command_identifier, CCStr message)
    (void)message;
 #endif
 }
 #pragma clang diagnostic pop
 // ------------------------------------------------------------------------------------------------
 void Core::EmitIncomingConnection(CStr player_name, size_t name_buffer_size, CCStr user_password, CCStr ip_address)
--- a/module/Entity/Blip.cpp
+++ b/module/Entity/Blip.cpp
@ -281,10 +281,7 @@ static LightObj & Blip_Create(Int32 index, Int32 world, const Vector3 & pos, Int
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_CBlip(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    RootTable(vm).Bind(Typename::Str,
        Class< CBlip, NoConstructor< CBlip > >(vm, Typename::Str)
--- a/module/Entity/Checkpoint.cpp
+++ b/module/Entity/Checkpoint.cpp
@ -502,10 +502,7 @@ static LightObj & Checkpoint_Create(Int32 world, bool sphere, const Vector3 & po
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_CCheckpoint(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    RootTable(vm).Bind(Typename::Str,
        Class< CCheckpoint, NoConstructor< CCheckpoint > >(vm, Typename::Str)
--- a/module/Entity/Keybind.cpp
+++ b/module/Entity/Keybind.cpp
@ -180,10 +180,7 @@ static SQInteger Keybind_UnusedSlot()
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_CKeybind(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    RootTable(vm).Bind(Typename::Str,
        Class< CKeybind, NoConstructor< CKeybind > >(vm, Typename::Str)
--- a/module/Entity/Object.cpp
+++ b/module/Entity/Object.cpp
@ -861,10 +861,7 @@ static LightObj & Object_Create(Int32 model, Int32 world, const Vector3 & pos, I
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_CObject(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    RootTable(vm).Bind(Typename::Str,
        Class< CObject, NoConstructor< CObject > >(vm, Typename::Str)
--- a/module/Entity/Pickup.cpp
+++ b/module/Entity/Pickup.cpp
@ -479,10 +479,7 @@ static LightObj & Pickup_Create(Int32 model, Int32 world, Int32 quantity, const
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_CPickup(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    RootTable(vm).Bind(Typename::Str,
        Class< CPickup, NoConstructor< CPickup > >(vm, Typename::Str)
--- a/module/Entity/Vehicle.cpp
+++ b/module/Entity/Vehicle.cpp
@ -1996,10 +1996,7 @@ static LightObj & Vehicle_Create(Int32 model, Int32 world, const Vector3 & pos,
 }
 // ================================================================================================
 #pragma clang diagnostic push
 #pragma clang diagnostic ignored "-Wunused-parameter"
 void Register_CVehicle(HSQUIRRELVM vm)
 #pragma clang diagnostic pop
 {
    RootTable(vm).Bind(Typename::Str,
        Class< CVehicle, NoConstructor< CVehicle > >(vm, Typename::Str)
--- a/module/Library/CURL.cpp
+++ b/module/Library/CURL.cpp
@ -0,0 +1,20 @@
 // ------------------------------------------------------------------------------------------------
 #include "Library/CURL.hpp"
 #include "Base/Shared.hpp"
 // ------------------------------------------------------------------------------------------------
 #include <cstdlib>
 #include <cstring>
 // ------------------------------------------------------------------------------------------------
 namespace SqMod {
 // ------------------------------------------------------------------------------------------------
 // ================================================================================================
 void Register_CURL(HSQUIRRELVM vm)
 {
 }
 } // Namespace:: SqMod
--- a/module/Library/CURL.hpp
+++ b/module/Library/CURL.hpp
@ -0,0 +1,14 @@
 #pragma once
 // ------------------------------------------------------------------------------------------------
 #include "SqBase.hpp"
 // ------------------------------------------------------------------------------------------------
 #include <cpr/cpr.h>
 // ------------------------------------------------------------------------------------------------
 namespace SqMod {
 } // Namespace:: SqMod
--- a/module/Library/Crypt/AES.cpp
+++ b/module/Library/Crypt/AES.cpp
@ -98,7 +98,7 @@ String AES256::Encrypt(CSStr data)
        aes256_encrypt_ecb(&m_Context, reinterpret_cast< Uint8 * >(&str[n]));
    }
    // Return ownership of the encrypted string
-    return std::move(str);
+    return str;
 }
 // ------------------------------------------------------------------------------------------------
@ -127,7 +127,7 @@ String AES256::Decrypt(CSStr data)
        str.pop_back();
    }
    // Return ownership of the encrypted string
-    return std::move(str);
+    return str;
 }
 // ================================================================================================
--- a/module/Library/Discord.cpp
+++ b/module/Library/Discord.cpp
@ -0,0 +1,20 @@
 // ------------------------------------------------------------------------------------------------
 #include "Library/Discord.hpp"
 #include "Base/Shared.hpp"
 // ------------------------------------------------------------------------------------------------
 #include <cstdlib>
 #include <cstring>
 // ------------------------------------------------------------------------------------------------
 namespace SqMod {
 // ------------------------------------------------------------------------------------------------
 // ================================================================================================
 void Register_Discord(HSQUIRRELVM vm)
 {
 }
 } // Namespace:: SqMod
--- a/module/Library/Discord.hpp
+++ b/module/Library/Discord.hpp
@ -0,0 +1,11 @@
 #pragma once
 // ------------------------------------------------------------------------------------------------
 #include "SqBase.hpp"
 // ------------------------------------------------------------------------------------------------
 namespace SqMod {
 } // Namespace:: SqMod
--- a/module/Library/Numeric/Math.cpp
+++ b/module/Library/Numeric/Math.cpp
@ -193,7 +193,7 @@ static SQInteger SqNanL(HSQUIRRELVM vm)
    {
        return sq_throwerror(vm, e.what());
    }
-    catch (const std::exception e)
+    catch (const std::exception & e)
    {
        return sq_throwerror(vm, e.what());
    }
@ -698,7 +698,7 @@ static SQInteger SqRoundL(HSQUIRRELVM vm)
    {
        return sq_throwerror(vm, e.what());
    }
-    catch (const std::exception e)
+    catch (const std::exception & e)
    {
        return sq_throwerror(vm, e.what());
    }
--- a/module/Library/Numeric/Random.cpp
+++ b/module/Library/Numeric/Random.cpp
@ -363,7 +363,7 @@ static String RandomString(Int32 len)
    // Request the random fill
    GetRandomString(str, len);
    // Return ownership of the string
-    return std::move(str);
+    return str;
 }
 // ------------------------------------------------------------------------------------------------
@ -377,7 +377,7 @@ static String RandomString(Int32 len, SQChar n)
    // Request the random fill
    GetRandomString(str, len, n);
    // Return ownership of the string
-    return std::move(str);
+    return str;
 }
 // ------------------------------------------------------------------------------------------------
@ -391,7 +391,7 @@ static String RandomString(Int32 len, SQChar m, SQChar n)
    // Request the random fill
    GetRandomString(str, len, m, n);
    // Return ownership of the string
-    return std::move(str);
+    return str;
 }
 // ------------------------------------------------------------------------------------------------
--- a/module/Library/SQLite.cpp
+++ b/module/Library/SQLite.cpp
@ -21,10 +21,6 @@ SQMODE_DECL_TYPENAME(SQLiteColumnTypename, _SC("SQLiteColumn"))
 SQMODE_DECL_TYPENAME(SQLiteStatementTypename, _SC("SQLiteStatement"))
 SQMODE_DECL_TYPENAME(SQLiteTransactionTypename, _SC("SQLiteTransaction"))
 // ------------------------------------------------------------------------------------------------
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "hicpp-signed-bitwise"
 /* ------------------------------------------------------------------------------------------------
 * Helper class that represents an integral enumeration value. Used to reduce compilation times.
 */
@ -371,7 +367,6 @@ static const SEnumElement g_MainEnum[] = {
    {_SC("WARNING"),                              SQLITE_WARNING},
    {_SC("WARNING_AUTOINDEX"),                    SQLITE_WARNING_AUTOINDEX}
 };
 #pragma clang diagnostic pop
 // ------------------------------------------------------------------------------------------------
 static inline bool IsDigitsOnly(CSStr str)
@ -874,7 +869,7 @@ void SQLiteConnection::TraceOutput(void * /*ptr*/, CCStr sql)
 // ------------------------------------------------------------------------------------------------
 void SQLiteConnection::ProfileOutput(void * /*ptr*/, CCStr sql, sqlite3_uint64 time)
 {
-    LogInf("SQLite profile (time: %llu): %s", time, sql);
+    LogInf("SQLite profile (time: %" PRINT_UINT_FMT "): %s", time, sql);
 }
 // ------------------------------------------------------------------------------------------------
--- a/module/Library/String.cpp
+++ b/module/Library/String.cpp
@ -233,7 +233,7 @@ static Buffer StrJustAlphaNumImpl(CSStr str, Uint32 len)
    // Move the cursor to the end
    b.Move(n);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -295,7 +295,7 @@ static Buffer StrToLowercaseImpl(CSStr str, Uint32 len)
    // Move the cursor to the end
    b.Move(n);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -357,7 +357,7 @@ static Buffer StrToUppercaseImpl(CSStr str, Uint32 len)
    // Move the cursor to the end
    b.Move(n);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
--- a/module/Library/System/Environment.cpp
+++ b/module/Library/System/Environment.cpp
@ -113,7 +113,7 @@ Buffer SysEnv::Get(CCStr name, CCStr fallback)
    // Forward the call to the shared function
    Get(b, name, fallback);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -544,7 +544,7 @@ Buffer SysEnv::ExpandVars(CCStr str)
    // Forward the call to the internal function
    ExpandVars(b, str, str + len);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -560,7 +560,7 @@ Buffer SysEnv::ExpandVars(const String & str)
    // Forward the call to the internal function
    ExpandVars(b, str.c_str(), str.c_str() + str.size());
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -616,7 +616,7 @@ Buffer SysEnv::ExpandPath(CCStr path)
    // Forward the call to the internal function
    ExpandPath(b, path, path + len);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -632,7 +632,7 @@ Buffer SysEnv::ExpandPath(const String & path)
    // Forward the call to the internal function
    ExpandPath(b, path.c_str(), path.c_str() + path.size());
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -683,7 +683,7 @@ Buffer SysEnv::WorkingDir()
    // Forward the call to the regular function
    WorkingDir(b);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -696,7 +696,7 @@ void SysEnv::HomeDir(Buffer & b)
        b.Grow(SQMOD_MAX_PATH - b.Remaining() + 2);
    }
    // Try the primary method of retrieving the home directory
-    if (SUCCEEDED(SHGetFolderPathA(NULL, CSIDL_PROFILE, nullptr, 0, &b.Cursor())))
+    if (SUCCEEDED(SHGetFolderPathA(nullptr, CSIDL_PROFILE, nullptr, 0, &b.Cursor())))
    {
        // Move the edit cursor to the end of the appended data
        b.Advance(strlen(&b.Cursor()));
@ -753,7 +753,7 @@ Buffer SysEnv::HomeDir()
    // Forward the call to the regular function
    HomeDir(b);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -795,7 +795,7 @@ Buffer SysEnv::ConfigHomeDir()
    // Forward the call to the regular function
    ConfigHomeDir(b);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -834,7 +834,7 @@ Buffer SysEnv::DataHomeDir()
    // Forward the call to the regular function
    DataHomeDir(b);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -861,7 +861,7 @@ Buffer SysEnv::TempHomeDir()
    // Forward the call to the regular function
    TempHomeDir(b);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -888,7 +888,7 @@ Buffer SysEnv::CacheHomeDir()
    // Forward the call to the regular function
    CacheHomeDir(b);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -962,7 +962,7 @@ Buffer SysEnv::TempDir()
    // Forward the call to the regular function
    TempDir(b);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -1004,7 +1004,7 @@ Buffer SysEnv::ConfigDir()
    // Forward the call to the regular function
    ConfigDir(b);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -1051,7 +1051,7 @@ Buffer SysEnv::SystemDir()
    // Forward the call to the regular function
    SystemDir(b);
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -1080,7 +1080,7 @@ Buffer SysEnv::NullDir()
    // Make sure that whatever string is in the buffer, if any, is null terminated
    b.Cursor() = '\0';
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
--- a/module/Library/System/Path.cpp
+++ b/module/Library/System/Path.cpp
@ -76,7 +76,7 @@ Buffer GetRealFilePath(CSStr path)
 #endif // SQMOD_OS_WINDOWS
    // Return ownership of the buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -1207,7 +1207,7 @@ SysPath SysPath::Parent() const
    // Force the copy to be parent
    p.MakeParent();
    // Return ownership of copy
-    return std::move(p);
+    return p;
 }
 // ------------------------------------------------------------------------------------------------
@ -1530,7 +1530,7 @@ Buffer SysPath::BuildUnix() const
    // Make sure the string is null terminated
    b.Cursor() = '\0';
    // Return ownership of buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
@ -1570,7 +1570,7 @@ Buffer SysPath::BuildWindows() const
    // Make sure the string is null terminated
    b.Cursor() = '\0';
    // Return ownership of buffer
-    return std::move(b);
+    return b;
 }
 // ------------------------------------------------------------------------------------------------
--- a/module/Logger.cpp
+++ b/module/Logger.cpp
@ -19,8 +19,6 @@
 // ------------------------------------------------------------------------------------------------
 namespace {
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "hicpp-signed-bitwise"
 /* ------------------------------------------------------------------------------------------------
 * Common windows colors.
 */
@ -42,7 +40,6 @@ enum
    LC_LIGHT_MAGENTA    = FOREGROUND_INTENSITY | FOREGROUND_RED | FOREGROUND_BLUE,
    LC_DARK_MAGENTA     = FOREGROUND_RED | FOREGROUND_BLUE
 };
 #pragma clang diagnostic pop
 /* ------------------------------------------------------------------------------------------------
 * Logging colors.
 */
--- a/module/Misc/Areas.cpp
+++ b/module/Misc/Areas.cpp
@ -13,8 +13,6 @@ SQMODE_DECL_TYPENAME(AreaTypename, _SC("SqArea"))
 // ------------------------------------------------------------------------------------------------
 AreaManager AreaManager::s_Inst;
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "UnusedValue"
 // ------------------------------------------------------------------------------------------------
 void Area::AddArray(const Sqrat::Array & a)
 {
@ -47,7 +45,6 @@ void Area::AddArray(const Sqrat::Array & a)
        return SQ_OK;
    });
 }
 #pragma clang diagnostic pop
 // ------------------------------------------------------------------------------------------------
 void Area::AddCircleEx(SQFloat cx, SQFloat cy, SQFloat cr, SQInteger num_segments)
 {
--- a/module/Misc/Command.hpp
+++ b/module/Misc/Command.hpp
@ -115,8 +115,6 @@ inline CSStr ValidateName(CSStr name)
    // Create iterator to name start
    CSStr str = name;
    // Inspect name characters
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "OCDFAInspection"
    while ('\0' != *str)
    {
        // Does it contain spaces?
@ -127,7 +125,6 @@ inline CSStr ValidateName(CSStr name)
        // Move to the next character
        ++str;
    }
 #pragma clang diagnostic pop
    // Return the name
    return name;
 }
--- a/module/Misc/Routine.hpp
+++ b/module/Misc/Routine.hpp
@ -330,10 +330,14 @@ public:
        // Unable to find such routine
        STHROWF("Unable to find a routine with tag (%s)", tag.mPtr);
        // Should not reach this point but if it did, we have to return something
-#pragma clang diagnostic push
+#ifdef __clang__
-#pragma clang diagnostic ignored "-Warray-bounds"
+	#pragma clang diagnostic push
 	#pragma clang diagnostic ignored "-Warray-bounds"
 #endif
        return s_Instances[SQMOD_MAX_ROUTINES].mInst; // Intentional Buffer overflow!
-#pragma clang diagnostic pop
+#ifdef __clang__
 	#pragma clang diagnostic pop
 #endif
    }
    /* --------------------------------------------------------------------------------------------
     * Check if a routine with a certain tag exists.
--- a/module/Misc/Signal.hpp
+++ b/module/Misc/Signal.hpp
@ -664,9 +664,6 @@ protected:
    // --------------------------------------------------------------------------------------------
    static SignalPool   s_Signals; // List of all created signals.
    static FreeSignals  s_FreeSignals; // List of signals without a name.
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "MemberFunctionCanBeStatic"
    /* --------------------------------------------------------------------------------------------
     * Specialization for when there are no arguments given.
    */
@ -674,7 +671,6 @@ protected:
    {
        //...
    }
 #pragma clang diagnostic pop
    /* --------------------------------------------------------------------------------------------
     * Specialization for when there's only one argument given/remaining.
--- a/module/Misc/Tasks.hpp
+++ b/module/Misc/Tasks.hpp
@ -402,10 +402,7 @@ public:
                STHROWF("Invalid entity instance");
            }
            // Validate the actual entity instance
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "OCDFAInspection"
            inst->Validate();
 #pragma clang diagnostic pop
        }
        catch (const Sqrat::Exception & e)
        {
@ -433,10 +430,7 @@ public:
                STHROWF("Invalid entity instance");
            }
            // Validate the actual entity instance
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "OCDFAInspection"
            inst->Validate();
 #pragma clang diagnostic pop
        }
        catch (const Sqrat::Exception & e)
        {
@ -464,10 +458,7 @@ public:
                STHROWF("Invalid entity instance");
            }
            // Validate the actual entity instance
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "OCDFAInspection"
            inst->Validate();
 #pragma clang diagnostic pop
        }
        catch (const Sqrat::Exception & e)
        {
@ -500,10 +491,7 @@ public:
                STHROWF("Invalid entity instance");
            }
            // Validate the actual entity instance
 #pragma clang diagnostic push
 #pragma ide diagnostic ignored "OCDFAInspection"
            inst->Validate();
 #pragma clang diagnostic pop
        }
        catch (const Sqrat::Exception & e)
        {
--- a/module/Register.cpp
+++ b/module/Register.cpp
@ -33,6 +33,12 @@ extern void Register_CVehicle(HSQUIRRELVM vm);
 // ------------------------------------------------------------------------------------------------
 extern void Register_Chrono(HSQUIRRELVM vm);
 extern void Register_Crypt(HSQUIRRELVM vm);
 #ifdef SQ_ENABLE_CURL
 extern void Register_CURL(HSQUIRRELVM vm);
 #endif
 #ifdef SQ_ENABLE_DISCORD
 extern void Register_Discord(HSQUIRRELVM vm);
 #endif
 extern void Register_IO(HSQUIRRELVM vm);
 extern void Register_Job(HSQUIRRELVM vm);
 extern void Register_MMDB(HSQUIRRELVM vm);
@ -89,6 +95,12 @@ bool RegisterAPI(HSQUIRRELVM vm)
    Register_Chrono(vm);
    Register_Crypt(vm);
 #ifdef SQ_ENABLE_CURL
    Register_CURL(vm);
 #endif
 #ifdef SQ_ENABLE_DISCORD
    Register_Discord(vm);
 #endif
    Register_IO(vm);
    Register_Job(vm);
    Register_MMDB(vm);
--- a/module/SqBase.hpp
+++ b/module/SqBase.hpp
@ -457,9 +457,15 @@ enum EntityType
 #define SQMOD_FORMAT_ATTR(mode, index, first) __attribute__ ((format(mode, index, first)))
 #ifdef _SQ64
-    #define PRINT_SZ_FMT "llu"
+    #ifdef SQMOD_OS_WINDOWS
-    #define PRINT_INT_FMT "lld"
+        #define PRINT_SZ_FMT "%I64u"
-    #define PRINT_UINT_FMT "llu"
+        #define PRINT_INT_FMT "%I64d"
        #define PRINT_UINT_FMT "%I64u"
    #else
        #define PRINT_SZ_FMT "llu"
        #define PRINT_INT_FMT "lld"
        #define PRINT_UINT_FMT "llu"
    #endif
 #else
    #define PRINT_SZ_FMT "u"
    #define PRINT_INT_FMT "d"
--- a/module/Vendor/AES256/aes256.cpp
+++ b/module/Vendor/AES256/aes256.cpp
@ -197,7 +197,7 @@ static uint8_t rj_xtime(uint8_t x)
 /* -------------------------------------------------------------------------- */
 static void aes_subBytes(uint8_t *buf)
 {
-    register uint8_t i = 16;
+    /*register*/ uint8_t i = 16;
    while (i--) buf[i] = rj_sbox(buf[i]);
 } /* aes_subBytes */
@ -205,7 +205,7 @@ static void aes_subBytes(uint8_t *buf)
 /* -------------------------------------------------------------------------- */
 static void aes_subBytes_inv(uint8_t *buf)
 {
-    register uint8_t i = 16;
+    /*register*/ uint8_t i = 16;
    while (i--) buf[i] = rj_sbox_inv(buf[i]);
 } /* aes_subBytes_inv */
@ -213,7 +213,7 @@ static void aes_subBytes_inv(uint8_t *buf)
 /* -------------------------------------------------------------------------- */
 static void aes_addRoundKey(uint8_t *buf, uint8_t *key)
 {
-    register uint8_t i = 16;
+    /*register*/ uint8_t i = 16;
    while (i--) buf[i] ^= key[i];
 } /* aes_addRoundKey */
@ -221,7 +221,7 @@ static void aes_addRoundKey(uint8_t *buf, uint8_t *key)
 /* -------------------------------------------------------------------------- */
 static void aes_addRoundKey_cpy(uint8_t *buf, uint8_t *key, uint8_t *cpk)
 {
-    register uint8_t i = 16;
+    /*register*/ uint8_t i = 16;
    while (i--)  buf[i] ^= (cpk[i] = key[i]), cpk[16 + i] = key[16 + i];
 } /* aes_addRoundKey_cpy */
@ -230,7 +230,7 @@ static void aes_addRoundKey_cpy(uint8_t *buf, uint8_t *key, uint8_t *cpk)
 /* -------------------------------------------------------------------------- */
 static void aes_shiftRows(uint8_t *buf)
 {
-    register uint8_t i, j; /* to make it potentially parallelable :) */
+    /*register*/ uint8_t i, j; /* to make it potentially parallelable :) */
    i = buf[1], buf[1] = buf[5], buf[5] = buf[9], buf[9] = buf[13], buf[13] = i;
    i = buf[10], buf[10] = buf[2], buf[2] = i;
@ -242,7 +242,7 @@ static void aes_shiftRows(uint8_t *buf)
 /* -------------------------------------------------------------------------- */
 static void aes_shiftRows_inv(uint8_t *buf)
 {
-    register uint8_t i, j; /* same as above :) */
+    /*register*/ uint8_t i, j; /* same as above :) */
    i = buf[1], buf[1] = buf[13], buf[13] = buf[9], buf[9] = buf[5], buf[5] = i;
    i = buf[2], buf[2] = buf[10], buf[10] = i;
@ -254,7 +254,7 @@ static void aes_shiftRows_inv(uint8_t *buf)
 /* -------------------------------------------------------------------------- */
 static void aes_mixColumns(uint8_t *buf)
 {
-    register uint8_t i, a, b, c, d, e;
+    /*register*/ uint8_t i, a, b, c, d, e;
    for (i = 0; i < 16; i += 4)
    {
@ -273,7 +273,7 @@ static void aes_mixColumns(uint8_t *buf)
 /* -------------------------------------------------------------------------- */
 void aes_mixColumns_inv(uint8_t *buf)
 {
-    register uint8_t i, a, b, c, d, e, x, y, z;
+    /*register*/ uint8_t i, a, b, c, d, e, x, y, z;
    for (i = 0; i < 16; i += 4)
    {
@ -295,7 +295,7 @@ void aes_mixColumns_inv(uint8_t *buf)
 /* -------------------------------------------------------------------------- */
 static void aes_expandEncKey(uint8_t *k, uint8_t *rc)
 {
-    register uint8_t i;
+    /*register*/ uint8_t i;
    k[0] ^= rj_sbox(k[29]) ^ (*rc);
    k[1] ^= rj_sbox(k[30]);
@ -343,7 +343,7 @@ void aes_expandDecKey(uint8_t *k, uint8_t *rc)
 void aes256_init(aes256_context *ctx, uint8_t *k)
 {
    uint8_t rcon = 1;
-    register uint8_t i;
+    /*register*/ uint8_t i;
    for (i = 0; i < sizeof(ctx->key); i++) ctx->enckey[i] = ctx->deckey[i] = k[i];
    for (i = 8; --i;) aes_expandEncKey(ctx->deckey, &rcon);
@ -352,7 +352,7 @@ void aes256_init(aes256_context *ctx, uint8_t *k)
 /* -------------------------------------------------------------------------- */
 void aes256_done(aes256_context *ctx)
 {
-    register uint8_t i;
+    /*register*/ uint8_t i;
    for (i = 0; i < sizeof(ctx->key); i++)
        ctx->key[i] = ctx->enckey[i] = ctx->deckey[i] = 0;
--- a/module/Vendor/ASIO/COPYING
+++ b/module/Vendor/ASIO/COPYING
@ -0,0 +1,4 @@
 Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 Distributed under the Boost Software License, Version 1.0. (See accompanying
 file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
--- a/module/Vendor/ASIO/INSTALL
+++ b/module/Vendor/ASIO/INSTALL
@ -0,0 +1,5 @@
 See doc/index.html for information on:
  - External dependencies
  - Using, building, and configuring Asio
  - Supported platforms
  - How to build the tests and examples
--- a/module/Vendor/ASIO/LICENSE_1_0.txt
+++ b/module/Vendor/ASIO/LICENSE_1_0.txt
@ -0,0 +1,23 @@
 Boost Software License - Version 1.0 - August 17th, 2003
 Permission is hereby granted, free of charge, to any person or organization
 obtaining a copy of the software and accompanying documentation covered by
 this license (the "Software") to use, reproduce, display, distribute,
 execute, and transmit the Software, and to prepare derivative works of the
 Software, and to permit third-parties to whom the Software is furnished to
 do so, all subject to the following:
 The copyright notices in the Software and this entire statement, including
 the above license grant, this restriction and the following disclaimer,
 must be included in all copies of the Software, in whole or in part, and
 all derivative works of the Software, unless such copies or derivative
 works are solely in the form of machine-executable object code generated by
 a source language processor.
 THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 FITNESS FOR A PARTICULAR PURPOSE, TITLE AND NON-INFRINGEMENT. IN NO EVENT
 SHALL THE COPYRIGHT HOLDERS OR ANYONE DISTRIBUTING THE SOFTWARE BE LIABLE
 FOR ANY DAMAGES OR OTHER LIABILITY, WHETHER IN CONTRACT, TORT OR OTHERWISE,
 ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER
 DEALINGS IN THE SOFTWARE.
--- a/module/Vendor/ASIO/Makefile.am
+++ b/module/Vendor/ASIO/Makefile.am
@ -0,0 +1,19 @@
 AUTOMAKE_OPTIONS = foreign dist-bzip2 dist-zip
 SUBDIRS = include src
 MAINTAINERCLEANFILES = \
 	$(srcdir)/aclocal.m4 \
 	$(srcdir)/configure \
 	$(srcdir)/config.guess \
 	$(srcdir)/config.sub \
 	$(srcdir)/depcomp \
 	$(srcdir)/install-sh \
 	$(srcdir)/missing \
 	$(srcdir)/mkinstalldirs \
 	$(srcdir)/Makefile.in \
 	asio-*.tar.gz
 EXTRA_DIST = \
 	LICENSE_1_0.txt \
 	doc
--- a/module/Vendor/ASIO/README
+++ b/module/Vendor/ASIO/README
@ -0,0 +1,4 @@
 asio version 1.18.1
 Released Saturday, 26 December 2020.
 See doc/index.html for API documentation and a tutorial.
--- a/module/Vendor/ASIO/asio.manifest
+++ b/module/Vendor/ASIO/asio.manifest
--- a/module/Vendor/ASIO/autogen.sh
+++ b/module/Vendor/ASIO/autogen.sh
@ -0,0 +1,55 @@
 #!/bin/sh
 # Helps bootstrapping the application when checked out from CVS.
 # Requires GNU autoconf, GNU automake and GNU which.
 #
 # Copyright (C) 2004, by
 #
 # Carlo Wood, Run on IRC <carlo@alinoe.com>
 # RSA-1024 0x624ACAD5 1997-01-26                    Sign & Encrypt
 # Fingerprint16 = 32 EC A7 B6 AC DB 65 A6  F6 F6 55 DD 1C DC FF 61
 #
 # Do sanity checks.
 # Directory check.
 if [ ! -f autogen.sh ]; then
  echo "Run ./autogen.sh from the directory it exists in."
  exit 1
 fi
 AUTOMAKE=${AUTOMAKE:-automake}
 ACLOCAL=${ACLOCAL:-aclocal}
 AUTOCONF=${AUTOCONF:-autoconf}
 ($AUTOCONF --version) >/dev/null 2>/dev/null || (echo "You need GNU autoconf to install from CVS (ftp://ftp.gnu.org/gnu/autoconf/)"; exit 1) || exit 1
 ($AUTOMAKE --version) >/dev/null 2>/dev/null || (echo "You need GNU automake 1.7 or higher to install from CVS (ftp://ftp.gnu.org/gnu/automake/)"; exit 1) || exit 1
 # Determine the version of automake.
 automake_version=`$AUTOMAKE --version | head -n 1 | sed -e 's/[^12]*\([12]\.[0-9][^ ]*\).*/\1/'`
 automake_major=`echo $automake_version | cut -f1 -d.`
 automake_minor=`echo $automake_version | cut -f2 -d.`
 automake_version_number=`expr "$automake_major" \* 1000 \+ "$automake_minor"`
 # Require automake 1.7.
 if expr "1007" \> "$automake_version_number" >/dev/null; then
  $AUTOMAKE --version | head -n 1
  echo ""
  echo "Fatal error: automake 1.7 or higher is required.  Please set \$AUTOMAKE"
  echo "to point to a newer automake, or upgrade."
  echo ""
  exit 1
 fi
 run()
 {
  echo "Running $1 ..."
  $1
 }
 # This is needed when someone just upgraded automake and this cache is still generated by an old version.
 rm -rf autom4te.cache config.cache
 run "$ACLOCAL"
 run "$AUTOCONF"
 run "$AUTOMAKE --add-missing --foreign"
--- a/module/Vendor/ASIO/boost_asio.manifest
+++ b/module/Vendor/ASIO/boost_asio.manifest
--- a/module/Vendor/ASIO/boostify.pl
+++ b/module/Vendor/ASIO/boostify.pl
@ -0,0 +1,635 @@
 #!/usr/bin/perl -w
 use strict;
 use File::Path;
 our $boost_dir = "boostified";
 sub print_line
 {
  my ($output, $line, $from, $lineno) = @_;
  # Warn if the resulting line is >80 characters wide.
  if (length($line) > 80)
  {
    if ($from =~ /\.[chi]pp$/)
    {
      print("Warning: $from:$lineno: output >80 characters wide.\n");
    }
  }
  # Write the output.
  print($output $line . "\n");
 }
 sub source_contains_asio_thread_usage
 {
  my ($from) = @_;
  # Open the input file.
  open(my $input, "<$from") or die("Can't open $from for reading");
  # Check file for use of asio::thread.
  while (my $line = <$input>)
  {
    chomp($line);
    if ($line =~ /asio::thread/)
    {
      close($input);
      return 1;
    }
    elsif ($line =~ /^ *thread /)
    {
      close($input);
      return 1;
    }
  }
  close($input);
  return 0;
 }
 sub source_contains_asio_include
 {
  my ($from) = @_;
  # Open the input file.
  open(my $input, "<$from") or die("Can't open $from for reading");
  # Check file for inclusion of asio.hpp.
  while (my $line = <$input>)
  {
    chomp($line);
    if ($line =~ /# *include [<"]asio\.hpp[>"]/)
    {
      close($input);
      return 1;
    }
  }
  close($input);
  return 0;
 }
 sub copy_source_file
 {
  my ($from, $to) = @_;
  # Ensure the output directory exists.
  my $dir = $to;
  $dir =~ s/[^\/]*$//;
  mkpath($dir);
  # First determine whether the file makes any use of asio::thread.
  my $uses_asio_thread = source_contains_asio_thread_usage($from);
  my $includes_asio = source_contains_asio_include($from);
  my $is_asio_hpp = 0;
  $is_asio_hpp = 1 if ($from =~ /asio\.hpp/);
  my $needs_doc_link = 0;
  $needs_doc_link = 1 if ($is_asio_hpp);
  my $is_error_hpp = 0;
  $is_error_hpp = 1 if ($from =~ /asio\/error\.hpp/);
  my $is_qbk = 0;
  $is_qbk = 1 if ($from =~ /.qbk$/);
  my $is_xsl = 0;
  $is_xsl = 1 if ($from =~ /.xsl$/);
  my $is_test = 0;
  $is_test = 1 if ($from =~ /tests\/unit/);
  my $is_coroutine_related = 0;
  $is_coroutine_related = 1 if ($from =~ /await/);
  # Open the files.
  open(my $input, "<$from") or die("Can't open $from for reading");
  open(my $output, ">$to") or die("Can't open $to for writing");
  # Copy the content.
  my $lineno = 1;
  while (my $line = <$input>)
  {
    chomp($line);
    # Unconditional replacements.
    $line =~ s/[\\@]ref boost_bind/boost::bind()/g;
    if ($from =~ /.*\.txt$/)
    {
      $line =~ s/[\\@]ref async_read/boost::asio::async_read()/g;
      $line =~ s/[\\@]ref async_write/boost::asio::async_write()/g;
    }
    if ($line =~ /asio_detail_posix_thread_function/)
    {
      $line =~ s/asio_detail_posix_thread_function/boost_asio_detail_posix_thread_function/g;
    }
    if ($line =~ /asio_signal_handler/)
    {
      $line =~ s/asio_signal_handler/boost_asio_signal_handler/g;
    }
    if ($line =~ /ASIO_/ && !($line =~ /BOOST_ASIO_/))
    {
      $line =~ s/ASIO_/BOOST_ASIO_/g;
    }
    # Extra replacements for quickbook and XSL source only.
    if ($is_qbk || $is_xsl)
    {
      $line =~ s/asio\.examples/boost_asio.examples/g;
      $line =~ s/asio\.history/boost_asio.history/g;
      $line =~ s/asio\.index/boost_asio.index/g;
      $line =~ s/asio\.net_ts/boost_asio.net_ts/g;
      $line =~ s/asio\.std_executors/boost_asio.std_executors/g;
      $line =~ s/asio\.overview/boost_asio.overview/g;
      $line =~ s/asio\.reference/boost_asio.reference/g;
      $line =~ s/asio\.tutorial/boost_asio.tutorial/g;
      $line =~ s/asio\.using/boost_asio.using/g;
      $line =~ s/Asio/Boost.Asio/g;
      $line =~ s/changes made in each release/changes made in each Boost release/g;
      $line =~ s/\[\$/[\$boost_asio\//g;
      $line =~ s/\[@\.\.\/src\/examples/[\@boost_asio\/example/g;
      $line =~ s/include\/asio/boost\/asio/g;
      $line =~ s/\^asio/^boost\/asio/g;
      $line =~ s/namespaceasio/namespaceboost_1_1asio/g;
      $line =~ s/ \(\[\@examples\/diffs.*$//;
    }
    # Conditional replacements.
    if ($line =~ /^( *)namespace asio \{/)
    {
      if ($is_qbk)
      {
        print_line($output, $1 . "namespace boost { namespace asio {", $from, $lineno);
      }
      else
      {
        print_line($output, $1 . "namespace boost {", $from, $lineno);
        print_line($output, $line, $from, $lineno);
      }
    }
    elsif ($line =~ /^( *)} \/\/ namespace asio$/)
    {
      if ($is_qbk)
      {
        print_line($output, $1 . "} } // namespace boost::asio", $from, $lineno);
      }
      else
      {
        print_line($output, $line, $from, $lineno);
        print_line($output, $1 . "} // namespace boost", $from, $lineno);
      }
    }
    elsif ($line =~ /^(# *include )[<"](asio\.hpp)[>"]$/)
    {
      print_line($output, $1 . "<boost/" . $2 . ">", $from, $lineno);
      if ($uses_asio_thread)
      {
        print_line($output, $1 . "<boost/thread/thread.hpp>", $from, $lineno) if (!$is_test);
        $uses_asio_thread = 0;
      }
    }
    elsif ($line =~ /^(# *include )[<"]boost\/.*[>"].*$/)
    {
      if (!$includes_asio && $uses_asio_thread)
      {
        print_line($output, $1 . "<boost/thread/thread.hpp>", $from, $lineno) if (!$is_test);
        $uses_asio_thread = 0;
      }
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /^(# *include )[<"]asio\/thread\.hpp[>"]/)
    {
      if ($is_test)
      {
        print_line($output, $1 . "<boost/asio/detail/thread.hpp>", $from, $lineno);
      }
      else
      {
        # Line is removed.
      }
    }
    elsif ($line =~ /(# *include )[<"]asio\/error_code\.hpp[>"]/)
    {
      if ($is_asio_hpp)
      {
        # Line is removed.
      }
      else
      {
        print_line($output, $1 . "<boost/cerrno.hpp>", $from, $lineno) if ($is_error_hpp);
        print_line($output, $1 . "<boost/system/error_code.hpp>", $from, $lineno);
      }
    }
    elsif ($line =~ /# *include [<"]asio\/impl\/error_code\.[hi]pp[>"]/)
    {
      # Line is removed.
    }
    elsif ($line =~ /(# *include )[<"]asio\/system_error\.hpp[>"]/)
    {
      if ($is_asio_hpp)
      {
        # Line is removed.
      }
      else
      {
        print_line($output, $1 . "<boost/system/system_error.hpp>", $from, $lineno);
      }
    }
    elsif ($line =~ /(^.*# *include )[<"](asio\/[^>"]*)[>"](.*)$/)
    {
      print_line($output, $1 . "<boost/" . $2 . ">" . $3, $from, $lineno);
    }
    elsif ($line =~ /#.*defined\(.*ASIO_HAS_STD_SYSTEM_ERROR\)$/)
    {
      # Line is removed.
    }
    elsif ($line =~ /asio::thread\b/)
    {
      if ($is_test)
      {
        $line =~ s/asio::thread/asio::detail::thread/g;
      }
      else
      {
        $line =~ s/asio::thread/boost::thread/g;
      }
      if (!($line =~ /boost::asio::/))
      {
        $line =~ s/asio::/boost::asio::/g;
      }
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /^( *)thread( .*)$/ && !$is_qbk)
    {
      if ($is_test)
      {
        print_line($output, $1 . "boost::asio::detail::thread" . $2, $from, $lineno);
      }
      else
      {
        print_line($output, $1 . "boost::thread" . $2, $from, $lineno);
      }
    }
    elsif ($line =~ /namespace std \{ *$/ && !$is_coroutine_related)
    {
      print_line($output, "namespace boost {", $from, $lineno);
      print_line($output, "namespace system {", $from, $lineno);
    }
    elsif ($line =~ /std::error_code/)
    {
      $line =~ s/std::error_code/boost::system::error_code/g;
      $line =~ s/asio::/boost::asio::/g if !$is_xsl;
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /^} \/\/ namespace std/ && !$is_coroutine_related)
    {
      print_line($output, "} // namespace system", $from, $lineno);
      print_line($output, "} // namespace boost", $from, $lineno);
    }
    elsif ($line =~ /asio::/ && !($line =~ /boost::asio::/))
    {
      $line =~ s/asio::error_code/boost::system::error_code/g;
      $line =~ s/asio::error_category/boost::system::error_category/g;
      $line =~ s/asio::system_category/boost::system::system_category/g;
      $line =~ s/asio::system_error/boost::system::system_error/g;
      $line =~ s/asio::/boost::asio::/g if !$is_xsl;
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /using namespace asio/)
    {
      $line =~ s/using namespace asio/using namespace boost::asio/g;
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /asio_handler_alloc_helpers/)
    {
      $line =~ s/asio_handler_alloc_helpers/boost_asio_handler_alloc_helpers/g;
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /asio_handler_cont_helpers/)
    {
      $line =~ s/asio_handler_cont_helpers/boost_asio_handler_cont_helpers/g;
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /asio_handler_invoke_helpers/)
    {
      $line =~ s/asio_handler_invoke_helpers/boost_asio_handler_invoke_helpers/g;
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /[\\@]ref boost_bind/)
    {
      $line =~ s/[\\@]ref boost_bind/boost::bind()/g;
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /( *)\[category template\]/)
    {
      print_line($output, $1 . "[authors [Kohlhoff, Christopher]]", $from, $lineno);
      print_line($output, $line, $from, $lineno);
    }
    elsif ($line =~ /boostify: non-boost docs start here/)
    { 
      while ($line = <$input>)
      {
        last if $line =~ /boostify: non-boost docs end here/;
      }
    }
    elsif ($line =~ /boostify: non-boost code starts here/)
    { 
      while ($line = <$input>)
      {
        last if $line =~ /boostify: non-boost code ends here/;
      }
    }
    elsif ($line =~ /^$/ && $needs_doc_link)
    {
      $needs_doc_link = 0;
      print_line($output, "//  See www.boost.org/libs/asio for documentation.", $from, $lineno);
      print_line($output, "//", $from, $lineno);
      print_line($output, $line, $from, $lineno);
    }
    else
    {
      print_line($output, $line, $from, $lineno);
    }
    ++$lineno;
  }
  # Ok, we're done.
  close($input);
  close($output);
 }
 sub copy_include_files
 {
  my @dirs = (
      "include",
      "include/asio",
      "include/asio/detail",
      "include/asio/detail/impl",
      "include/asio/execution",
      "include/asio/execution/detail",
      "include/asio/execution/impl",
      "include/asio/experimental",
      "include/asio/experimental/impl",
      "include/asio/generic",
      "include/asio/generic/detail",
      "include/asio/generic/detail/impl",
      "include/asio/impl",
      "include/asio/ip",
      "include/asio/ip/impl",
      "include/asio/ip/detail",
      "include/asio/ip/detail/impl",
      "include/asio/local",
      "include/asio/local/detail",
      "include/asio/local/detail/impl",
      "include/asio/posix",
      "include/asio/ssl",
      "include/asio/ssl/detail",
      "include/asio/ssl/detail/impl",
      "include/asio/ssl/impl",
      "include/asio/ssl/old",
      "include/asio/ssl/old/detail",
      "include/asio/traits",
      "include/asio/ts",
      "include/asio/windows");
  foreach my $dir (@dirs)
  {
    our $boost_dir;
    my @files = ( glob("$dir/*.hpp"), glob("$dir/*.ipp") );
    foreach my $file (@files)
    {
      if ($file ne "include/asio/thread.hpp"
          and $file ne "include/asio/error_code.hpp"
          and $file ne "include/asio/system_error.hpp"
          and $file ne "include/asio/impl/error_code.hpp"
          and $file ne "include/asio/impl/error_code.ipp")
      {
        my $from = $file;
        my $to = $file;
        $to =~ s/^include\//$boost_dir\/libs\/asio\/include\/boost\//;
        copy_source_file($from, $to);
      }
    }
  }
 }
 sub create_lib_directory
 {
  my @dirs = (
      "doc",
      "example",
      "test");
  our $boost_dir;
  foreach my $dir (@dirs)
  {
    mkpath("$boost_dir/libs/asio/$dir");
  }
 }
 sub copy_unit_tests
 {
  my @dirs = (
      "src/tests/unit",
      "src/tests/unit/archetypes",
      "src/tests/unit/execution",
      "src/tests/unit/generic",
      "src/tests/unit/ip",
      "src/tests/unit/local",
      "src/tests/unit/posix",
      "src/tests/unit/ssl",
      "src/tests/unit/ts",
      "src/tests/unit/windows");
  our $boost_dir;
  foreach my $dir (@dirs)
  {
    my @files = ( glob("$dir/*.*pp"), glob("$dir/Jamfile*") );
    foreach my $file (@files)
    {
      if ($file ne "src/tests/unit/thread.cpp"
          and $file ne "src/tests/unit/error_handler.cpp"
          and $file ne "src/tests/unit/unit_test.cpp")
      {
        my $from = $file;
        my $to = $file;
        $to =~ s/^src\/tests\/unit\//$boost_dir\/libs\/asio\/test\//;
        copy_source_file($from, $to);
      }
    }
  }
 }
 sub copy_latency_tests
 {
  my @dirs = (
      "src/tests/latency");
  our $boost_dir;
  foreach my $dir (@dirs)
  {
    my @files = ( glob("$dir/*.*pp"), glob("$dir/Jamfile*") );
    foreach my $file (@files)
    {
      my $from = $file;
      my $to = $file;
      $to =~ s/^src\/tests\/latency\//$boost_dir\/libs\/asio\/test\/latency\//;
      copy_source_file($from, $to);
    }
  }
 }
 sub copy_properties_tests
 {
  my @dirs = (
      "src/tests/properties/cpp03",
      "src/tests/properties/cpp11",
      "src/tests/properties/cpp14");
  our $boost_dir;
  foreach my $dir (@dirs)
  {
    my @files = ( glob("$dir/*.*pp"), glob("$dir/Jamfile*") );
    foreach my $file (@files)
    {
      my $from = $file;
      my $to = $file;
      $to =~ s/^src\/tests\/properties\//$boost_dir\/libs\/asio\/test\/properties\//;
      copy_source_file($from, $to);
    }
  }
 }
 sub copy_examples
 {
  my @dirs = (
      "src/examples/cpp03/allocation",
      "src/examples/cpp03/buffers",
      "src/examples/cpp03/chat",
      "src/examples/cpp03/echo",
      "src/examples/cpp03/fork",
      "src/examples/cpp03/http/client",
      "src/examples/cpp03/http/doc_root",
      "src/examples/cpp03/http/server",
      "src/examples/cpp03/http/server2",
      "src/examples/cpp03/http/server3",
      "src/examples/cpp03/http/server4",
      "src/examples/cpp03/icmp",
      "src/examples/cpp03/invocation",
      "src/examples/cpp03/iostreams",
      "src/examples/cpp03/local",
      "src/examples/cpp03/multicast",
      "src/examples/cpp03/nonblocking",
      "src/examples/cpp03/porthopper",
      "src/examples/cpp03/serialization",
      "src/examples/cpp03/services",
      "src/examples/cpp03/socks4",
      "src/examples/cpp03/spawn",
      "src/examples/cpp03/ssl",
      "src/examples/cpp03/timeouts",
      "src/examples/cpp03/timers",
      "src/examples/cpp03/tutorial",
      "src/examples/cpp03/tutorial/daytime1",
      "src/examples/cpp03/tutorial/daytime2",
      "src/examples/cpp03/tutorial/daytime3",
      "src/examples/cpp03/tutorial/daytime4",
      "src/examples/cpp03/tutorial/daytime5",
      "src/examples/cpp03/tutorial/daytime6",
      "src/examples/cpp03/tutorial/daytime7",
      "src/examples/cpp03/tutorial/timer1",
      "src/examples/cpp03/tutorial/timer2",
      "src/examples/cpp03/tutorial/timer3",
      "src/examples/cpp03/tutorial/timer4",
      "src/examples/cpp03/tutorial/timer5",
      "src/examples/cpp03/windows",
      "src/examples/cpp11/allocation",
      "src/examples/cpp11/buffers",
      "src/examples/cpp11/chat",
      "src/examples/cpp11/echo",
      "src/examples/cpp11/executors",
      "src/examples/cpp11/fork",
      "src/examples/cpp11/futures",
      "src/examples/cpp11/handler_tracking",
      "src/examples/cpp11/http/server",
      "src/examples/cpp11/invocation",
      "src/examples/cpp11/iostreams",
      "src/examples/cpp11/local",
      "src/examples/cpp11/multicast",
      "src/examples/cpp11/nonblocking",
      "src/examples/cpp11/operations",
      "src/examples/cpp11/socks4",
      "src/examples/cpp11/spawn",
      "src/examples/cpp11/ssl",
      "src/examples/cpp11/timeouts",
      "src/examples/cpp11/timers",
      "src/examples/cpp14/executors",
      "src/examples/cpp14/operations",
      "src/examples/cpp17/coroutines_ts");
  our $boost_dir;
  foreach my $dir (@dirs)
  {
    my @files = (
        glob("$dir/*.*pp"),
        glob("$dir/*.html"),
        glob("$dir/Jamfile*"),
        glob("$dir/*.pem"),
        glob("$dir/README*"),
        glob("$dir/*.txt"));
    foreach my $file (@files)
    {
      my $from = $file;
      my $to = $file;
      $to =~ s/^src\/examples\//$boost_dir\/libs\/asio\/example\//;
      copy_source_file($from, $to);
    }
  }
 }
 sub copy_doc
 {
  our $boost_dir;
  my @files = (
      "src/doc/asio.qbk",
      "src/doc/examples.qbk",
      "src/doc/net_ts.qbk",
      "src/doc/reference.xsl",
      "src/doc/std_executors.qbk",
      "src/doc/tutorial.xsl",
      glob("src/doc/overview/*.qbk"),
      glob("src/doc/requirements/*.qbk"));
  foreach my $file (@files)
  {
    my $from = $file;
    my $to = $file;
    $to =~ s/^src\/doc\//$boost_dir\/libs\/asio\/doc\//;
    copy_source_file($from, $to);
  }
 }
 sub copy_tools
 {
  our $boost_dir;
  my @files = (
      glob("src/tools/*.pl"));
  foreach my $file (@files)
  {
    my $from = $file;
    my $to = $file;
    $to =~ s/^src\/tools\//$boost_dir\/libs\/asio\/tools\//;
    copy_source_file($from, $to);
  }
 }
 copy_include_files();
 create_lib_directory();
 copy_unit_tests();
 copy_latency_tests();
 copy_properties_tests();
 copy_examples();
 copy_doc();
 copy_tools();
--- a/module/Vendor/ASIO/configure.ac
+++ b/module/Vendor/ASIO/configure.ac
@ -0,0 +1,230 @@
 AC_INIT(asio, [1.18.1])
 AC_CONFIG_SRCDIR(include/asio.hpp)
 AM_MAINTAINER_MODE
 AM_INIT_AUTOMAKE([tar-ustar])
 AC_CANONICAL_HOST
 AM_PROG_CC_C_O
 AC_PROG_CXX
 AC_LANG(C++)
 AC_PROG_RANLIB
 AC_DEFINE(_REENTRANT, [1], [Define this])
 AC_ARG_WITH(boost,
  AC_HELP_STRING([--with-boost=DIR],[location of boost distribution]),
 [
  if test "${withval}" = no; then
    STANDALONE="yes"
  else
    if test "${withval}" != system; then
      CPPFLAGS="$CPPFLAGS -I${withval}"
      LIBS="$LIBS -L${withval}/stage/lib"
    fi
    CPPFLAGS="$CPPFLAGS -DASIO_ENABLE_BOOST -DBOOST_CHRONO_HEADER_ONLY -DBOOST_CHRONO_DONT_PROVIDE_HYBRID_ERROR_HANDLING"
  fi
 ],
 [
  STANDALONE="yes"
 ])
 AC_ARG_ENABLE(separate-compilation,
 [  --enable-separate-compilation  separate compilation of asio source],
 [
  SEPARATE_COMPILATION=yes
 ])
 AC_ARG_ENABLE(boost-coroutine,
 [  --enable-boost-coroutine  use Boost.Coroutine to implement stackful coroutines],
 [
  HAVE_BOOST_COROUTINE=yes
 ])
 if test "$STANDALONE" != yes; then
  AC_CHECK_HEADER([boost/noncopyable.hpp],,
  [
    echo "Can't find boost headers. Please check the location of the boost"
    echo "distribution and rerun configure using the --with-boost=DIR option."
    echo "Alternatively, run with --without-boost to enable standalone build."
    exit 1
  ],[])
 fi
 AC_ARG_WITH(openssl,
  AC_HELP_STRING([--with-openssl=DIR],[location of openssl]),
 [
  CPPFLAGS="$CPPFLAGS -I${withval}/include"
  LIBS="$LIBS -L${withval}/lib"
 ],[])
 AC_CHECK_HEADER([openssl/ssl.h],,
 [
  OPENSSL_FOUND=no
 ],[])
 if test x$OPENSSL_FOUND != xno; then
  LIBS="$LIBS -lssl -lcrypto"
 fi
 AM_CONDITIONAL(HAVE_OPENSSL,test x$OPENSSL_FOUND != xno)
 WINDOWS=no
 case $host in
  *-*-linux*)
    CXXFLAGS="$CXXFLAGS -pthread"
    LDFLAGS="$LDFLAGS -pthread"
    LIBS="$LIBS -lrt"
    ;;
  *-*-solaris*)
    if test "$GXX" = yes; then
      CXXFLAGS="$CXXFLAGS -D_PTHREADS"
    else
      # We'll assume Sun's CC.
      CXXFLAGS="$CXXFLAGS -mt"
    fi
    LIBS="$LIBS -lsocket -lnsl -lpthread"
    ;;
  *-*-mingw32*)
    CXXFLAGS="$CXXFLAGS -mthreads"
    LDFLAGS="$LDFLAGS -mthreads"
    LIBS="$LIBS -lws2_32 -lmswsock"
    WINDOWS=yes
    ;;
  *-*-mingw64*)
    CXXFLAGS="$CXXFLAGS -mthreads"
    LDFLAGS="$LDFLAGS -mthreads"
    LIBS="$LIBS -lws2_32 -lmswsock"
    WINDOWS=yes
    ;;
  *-pc-cygwin*)
    CXXFLAGS="$CXXFLAGS -D__USE_W32_SOCKETS -D_WIN32_WINNT=0x0601"
    LIBS="$LIBS -lws2_32 -lmswsock"
    WINDOWS=yes
    ;;
  *-apple-darwin*)
    CXXFLAGS="$CXXFLAGS"
    LDFLAGS="$LDFLAGS"
    ;;
  *-*-freebsd*)
    CXXFLAGS="$CXXFLAGS -pthread"
    LDFLAGS="$LDFLAGS -pthread"
    ;;
  *-*-netbsd*)
    CXXFLAGS="$CXXFLAGS -pthread"
    LDFLAGS="$LDFLAGS -pthread"
    ;;
  *-*-haiku*)
    CXXFLAGS="$CXXFLAGS -lnetwork"
    LDFLAGS="$LDFLAGS -lnetwork"
 esac
 if test "$GXX" = yes; then
  CXXFLAGS="$CXXFLAGS -ftemplate-depth-256"
 fi
 if test "$STANDALONE" = yes; then
  CPPFLAGS="$CPPFLAGS -DASIO_STANDALONE"
 fi
 if test "$SEPARATE_COMPILATION" = yes; then
  CPPFLAGS="$CPPFLAGS -DASIO_SEPARATE_COMPILATION"
 fi
 AC_MSG_CHECKING([whether C++11 is enabled])
 AC_COMPILE_IFELSE(
  [AC_LANG_PROGRAM(
    [[#if __cplusplus < 201103L]]
    [[#error C++11 not available]]
    [[#endif]])],
  [AC_MSG_RESULT([yes])
    HAVE_CXX11=yes;],
  [AC_MSG_RESULT([no])
    HAVE_CXX11=no;])
 AC_MSG_CHECKING([whether C++14 is enabled])
 AC_COMPILE_IFELSE(
  [AC_LANG_PROGRAM(
    [[#if defined(__GNUC__) && !defined(__clang__)]]
    [[# if (__GNUC__ <= 6)]]
    [[#  error C++14 support on this compiler not sufficiently compliant]]
    [[# endif]]
    [[#endif]]
    [[#if __cplusplus < 201402L]]
    [[#error C++14 not available]]
    [[#endif]])],
  [AC_MSG_RESULT([yes])
    HAVE_CXX14=yes;],
  [AC_MSG_RESULT([no])
    HAVE_CXX14=no;])
 AC_MSG_CHECKING([whether C++17 is enabled])
 AC_COMPILE_IFELSE(
  [AC_LANG_PROGRAM(
    [[#if __cplusplus < 201703L]]
    [[#error C++17 not available]]
    [[#endif]])],
  [AC_MSG_RESULT([yes])
    HAVE_CXX17=yes;],
  [AC_MSG_RESULT([no])
    HAVE_CXX17=no;])
 AC_MSG_CHECKING([whether coroutines are enabled])
 AC_COMPILE_IFELSE(
  [AC_LANG_PROGRAM(
    [[#if defined(__clang__)]]
    [[# if (__cplusplus >= 201703) && (__cpp_coroutines >= 201703)]]
    [[#  if __has_include(<experimental/coroutine>)]]
    [[#   define ASIO_HAS_CO_AWAIT 1]]
    [[#  endif]]
    [[# endif]]
    [[#elif defined(__GNUC__)]]
    [[# if (__cplusplus >= 201709) && (__cpp_impl_coroutine >= 201902)]]
    [[#  if __has_include(<coroutine>)]]
    [[#   define ASIO_HAS_CO_AWAIT 1]]
    [[#  endif]]
    [[# endif]]
    [[#endif]]
    [[#ifndef ASIO_HAS_CO_AWAIT]]
    [[# error coroutines not available]]
    [[#endif]])],
  [AC_MSG_RESULT([yes])
    HAVE_COROUTINES=yes;],
  [AC_MSG_RESULT([no])
    HAVE_COROUTINES=no;])
 if test "$GXX" = yes; then
  if test "$STANDALONE" = yes; then
    if test "$HAVE_CXX11" = no; then
      HAVE_CXX11=yes
      CPPFLAGS="-std=c++0x $CPPFLAGS"
    fi
  fi
 fi
 AM_CONDITIONAL(STANDALONE,test x$STANDALONE = xyes)
 AM_CONDITIONAL(SEPARATE_COMPILATION,test x$SEPARATE_COMPILATION = xyes)
 AM_CONDITIONAL(HAVE_BOOST_COROUTINE,test x$HAVE_BOOST_COROUTINE = xyes)
 AM_CONDITIONAL(WINDOWS_TARGET,test x$WINDOWS != xno)
 AM_CONDITIONAL(HAVE_CXX11,test x$HAVE_CXX11 = xyes)
 AM_CONDITIONAL(HAVE_CXX14,test x$HAVE_CXX14 = xyes)
 AM_CONDITIONAL(HAVE_CXX17,test x$HAVE_CXX17 = xyes)
 AM_CONDITIONAL(HAVE_COROUTINES,test x$HAVE_COROUTINES = xyes)
 AC_OUTPUT([
  Makefile
  include/Makefile
  src/Makefile
  src/tests/Makefile
  src/tests/properties/Makefile
  src/examples/cpp03/Makefile
  src/examples/cpp11/Makefile
  src/examples/cpp14/Makefile
  src/examples/cpp17/Makefile])
--- a/module/Vendor/ASIO/include/Makefile.am
+++ b/module/Vendor/ASIO/include/Makefile.am
@ -0,0 +1,565 @@
 # find . -name "*.*pp" | sed -e 's/^\.\///' | sed -e 's/^.*$/  & \\/' | sort
 nobase_include_HEADERS = \
 	asio/any_io_executor.hpp \
 	asio/associated_allocator.hpp \
 	asio/associated_executor.hpp \
 	asio/async_result.hpp \
 	asio/awaitable.hpp \
 	asio/basic_datagram_socket.hpp \
 	asio/basic_deadline_timer.hpp \
 	asio/basic_io_object.hpp \
 	asio/basic_raw_socket.hpp \
 	asio/basic_seq_packet_socket.hpp \
 	asio/basic_serial_port.hpp \
 	asio/basic_signal_set.hpp \
 	asio/basic_socket_acceptor.hpp \
 	asio/basic_socket.hpp \
 	asio/basic_socket_iostream.hpp \
 	asio/basic_socket_streambuf.hpp \
 	asio/basic_streambuf_fwd.hpp \
 	asio/basic_streambuf.hpp \
 	asio/basic_stream_socket.hpp \
 	asio/basic_waitable_timer.hpp \
 	asio/bind_executor.hpp \
 	asio/buffered_read_stream_fwd.hpp \
 	asio/buffered_read_stream.hpp \
 	asio/buffered_stream_fwd.hpp \
 	asio/buffered_stream.hpp \
 	asio/buffered_write_stream_fwd.hpp \
 	asio/buffered_write_stream.hpp \
 	asio/buffer.hpp \
 	asio/buffers_iterator.hpp \
 	asio/co_spawn.hpp \
 	asio/completion_condition.hpp \
 	asio/compose.hpp \
 	asio/connect.hpp \
 	asio/coroutine.hpp \
 	asio/deadline_timer.hpp \
 	asio/defer.hpp \
 	asio/detached.hpp \
 	asio/detail/array_fwd.hpp \
 	asio/detail/array.hpp \
 	asio/detail/assert.hpp \
 	asio/detail/atomic_count.hpp \
 	asio/detail/base_from_completion_cond.hpp \
 	asio/detail/bind_handler.hpp \
 	asio/detail/blocking_executor_op.hpp \
 	asio/detail/buffered_stream_storage.hpp \
 	asio/detail/buffer_resize_guard.hpp \
 	asio/detail/buffer_sequence_adapter.hpp \
 	asio/detail/bulk_executor_op.hpp \
 	asio/detail/call_stack.hpp \
 	asio/detail/chrono.hpp \
 	asio/detail/chrono_time_traits.hpp \
 	asio/detail/completion_handler.hpp \
 	asio/detail/concurrency_hint.hpp \
 	asio/detail/conditionally_enabled_event.hpp \
 	asio/detail/conditionally_enabled_mutex.hpp \
 	asio/detail/config.hpp \
 	asio/detail/consuming_buffers.hpp \
 	asio/detail/cstddef.hpp \
 	asio/detail/cstdint.hpp \
 	asio/detail/date_time_fwd.hpp \
 	asio/detail/deadline_timer_service.hpp \
 	asio/detail/dependent_type.hpp \
 	asio/detail/descriptor_ops.hpp \
 	asio/detail/descriptor_read_op.hpp \
 	asio/detail/descriptor_write_op.hpp \
 	asio/detail/dev_poll_reactor.hpp \
 	asio/detail/epoll_reactor.hpp \
 	asio/detail/eventfd_select_interrupter.hpp \
 	asio/detail/event.hpp \
 	asio/detail/executor_function.hpp \
 	asio/detail/executor_op.hpp \
 	asio/detail/fd_set_adapter.hpp \
 	asio/detail/fenced_block.hpp \
 	asio/detail/functional.hpp \
 	asio/detail/future.hpp \
 	asio/detail/gcc_arm_fenced_block.hpp \
 	asio/detail/gcc_hppa_fenced_block.hpp \
 	asio/detail/gcc_sync_fenced_block.hpp \
 	asio/detail/gcc_x86_fenced_block.hpp \
 	asio/detail/global.hpp \
 	asio/detail/handler_alloc_helpers.hpp \
 	asio/detail/handler_cont_helpers.hpp \
 	asio/detail/handler_invoke_helpers.hpp \
 	asio/detail/handler_tracking.hpp \
 	asio/detail/handler_type_requirements.hpp \
 	asio/detail/handler_work.hpp \
 	asio/detail/hash_map.hpp \
 	asio/detail/impl/buffer_sequence_adapter.ipp \
 	asio/detail/impl/descriptor_ops.ipp \
 	asio/detail/impl/dev_poll_reactor.hpp \
 	asio/detail/impl/dev_poll_reactor.ipp \
 	asio/detail/impl/epoll_reactor.hpp \
 	asio/detail/impl/epoll_reactor.ipp \
 	asio/detail/impl/eventfd_select_interrupter.ipp \
 	asio/detail/impl/handler_tracking.ipp \
 	asio/detail/impl/kqueue_reactor.hpp \
 	asio/detail/impl/kqueue_reactor.ipp \
 	asio/detail/impl/null_event.ipp \
 	asio/detail/impl/pipe_select_interrupter.ipp \
 	asio/detail/impl/posix_event.ipp \
 	asio/detail/impl/posix_mutex.ipp \
 	asio/detail/impl/posix_thread.ipp \
 	asio/detail/impl/posix_tss_ptr.ipp \
 	asio/detail/impl/reactive_descriptor_service.ipp \
 	asio/detail/impl/reactive_serial_port_service.ipp \
 	asio/detail/impl/reactive_socket_service_base.ipp \
 	asio/detail/impl/resolver_service_base.ipp \
 	asio/detail/impl/scheduler.ipp \
 	asio/detail/impl/select_reactor.hpp \
 	asio/detail/impl/select_reactor.ipp \
 	asio/detail/impl/service_registry.hpp \
 	asio/detail/impl/service_registry.ipp \
 	asio/detail/impl/signal_set_service.ipp \
 	asio/detail/impl/socket_ops.ipp \
 	asio/detail/impl/socket_select_interrupter.ipp \
 	asio/detail/impl/strand_executor_service.hpp \
 	asio/detail/impl/strand_executor_service.ipp \
 	asio/detail/impl/strand_service.hpp \
 	asio/detail/impl/strand_service.ipp \
 	asio/detail/impl/throw_error.ipp \
 	asio/detail/impl/timer_queue_ptime.ipp \
 	asio/detail/impl/timer_queue_set.ipp \
 	asio/detail/impl/win_event.ipp \
 	asio/detail/impl/win_iocp_handle_service.ipp \
 	asio/detail/impl/win_iocp_io_context.hpp \
 	asio/detail/impl/win_iocp_io_context.ipp \
 	asio/detail/impl/win_iocp_serial_port_service.ipp \
 	asio/detail/impl/win_iocp_socket_service_base.ipp \
 	asio/detail/impl/win_mutex.ipp \
 	asio/detail/impl/win_object_handle_service.ipp \
 	asio/detail/impl/winrt_ssocket_service_base.ipp \
 	asio/detail/impl/winrt_timer_scheduler.hpp \
 	asio/detail/impl/winrt_timer_scheduler.ipp \
 	asio/detail/impl/winsock_init.ipp \
 	asio/detail/impl/win_static_mutex.ipp \
 	asio/detail/impl/win_thread.ipp \
 	asio/detail/impl/win_tss_ptr.ipp \
 	asio/detail/io_control.hpp \
 	asio/detail/io_object_impl.hpp \
 	asio/detail/is_buffer_sequence.hpp \
 	asio/detail/is_executor.hpp \
 	asio/detail/keyword_tss_ptr.hpp \
 	asio/detail/kqueue_reactor.hpp \
 	asio/detail/limits.hpp \
 	asio/detail/local_free_on_block_exit.hpp \
 	asio/detail/macos_fenced_block.hpp \
 	asio/detail/memory.hpp \
 	asio/detail/mutex.hpp \
 	asio/detail/non_const_lvalue.hpp \
 	asio/detail/noncopyable.hpp \
 	asio/detail/null_event.hpp \
 	asio/detail/null_fenced_block.hpp \
 	asio/detail/null_global.hpp \
 	asio/detail/null_mutex.hpp \
 	asio/detail/null_reactor.hpp \
 	asio/detail/null_signal_blocker.hpp \
 	asio/detail/null_socket_service.hpp \
 	asio/detail/null_static_mutex.hpp \
 	asio/detail/null_thread.hpp \
 	asio/detail/null_tss_ptr.hpp \
 	asio/detail/object_pool.hpp \
 	asio/detail/old_win_sdk_compat.hpp \
 	asio/detail/operation.hpp \
 	asio/detail/op_queue.hpp \
 	asio/detail/pipe_select_interrupter.hpp \
 	asio/detail/pop_options.hpp \
 	asio/detail/posix_event.hpp \
 	asio/detail/posix_fd_set_adapter.hpp \
 	asio/detail/posix_global.hpp \
 	asio/detail/posix_mutex.hpp \
 	asio/detail/posix_signal_blocker.hpp \
 	asio/detail/posix_static_mutex.hpp \
 	asio/detail/posix_thread.hpp \
 	asio/detail/posix_tss_ptr.hpp \
 	asio/detail/push_options.hpp \
 	asio/detail/reactive_descriptor_service.hpp \
 	asio/detail/reactive_null_buffers_op.hpp \
 	asio/detail/reactive_serial_port_service.hpp \
 	asio/detail/reactive_socket_accept_op.hpp \
 	asio/detail/reactive_socket_connect_op.hpp \
 	asio/detail/reactive_socket_recvfrom_op.hpp \
 	asio/detail/reactive_socket_recvmsg_op.hpp \
 	asio/detail/reactive_socket_recv_op.hpp \
 	asio/detail/reactive_socket_send_op.hpp \
 	asio/detail/reactive_socket_sendto_op.hpp \
 	asio/detail/reactive_socket_service_base.hpp \
 	asio/detail/reactive_socket_service.hpp \
 	asio/detail/reactive_wait_op.hpp \
 	asio/detail/reactor_fwd.hpp \
 	asio/detail/reactor.hpp \
 	asio/detail/reactor_op.hpp \
 	asio/detail/reactor_op_queue.hpp \
 	asio/detail/recycling_allocator.hpp \
 	asio/detail/regex_fwd.hpp \
 	asio/detail/resolve_endpoint_op.hpp \
 	asio/detail/resolve_op.hpp \
 	asio/detail/resolve_query_op.hpp \
 	asio/detail/resolver_service_base.hpp \
 	asio/detail/resolver_service.hpp \
 	asio/detail/scheduler.hpp \
 	asio/detail/scheduler_operation.hpp \
 	asio/detail/scheduler_thread_info.hpp \
 	asio/detail/scoped_lock.hpp \
 	asio/detail/scoped_ptr.hpp \
 	asio/detail/select_interrupter.hpp \
 	asio/detail/select_reactor.hpp \
 	asio/detail/service_registry.hpp \
 	asio/detail/signal_blocker.hpp \
 	asio/detail/signal_handler.hpp \
 	asio/detail/signal_init.hpp \
 	asio/detail/signal_op.hpp \
 	asio/detail/signal_set_service.hpp \
 	asio/detail/socket_holder.hpp \
 	asio/detail/socket_ops.hpp \
 	asio/detail/socket_option.hpp \
 	asio/detail/socket_select_interrupter.hpp \
 	asio/detail/socket_types.hpp \
 	asio/detail/solaris_fenced_block.hpp \
 	asio/detail/source_location.hpp \
 	asio/detail/static_mutex.hpp \
 	asio/detail/std_event.hpp \
 	asio/detail/std_fenced_block.hpp \
 	asio/detail/std_global.hpp \
 	asio/detail/std_mutex.hpp \
 	asio/detail/std_static_mutex.hpp \
 	asio/detail/std_thread.hpp \
 	asio/detail/strand_executor_service.hpp \
 	asio/detail/strand_service.hpp \
 	asio/detail/string_view.hpp \
 	asio/detail/thread_context.hpp \
 	asio/detail/thread_group.hpp \
 	asio/detail/thread.hpp \
 	asio/detail/thread_info_base.hpp \
 	asio/detail/throw_error.hpp \
 	asio/detail/throw_exception.hpp \
 	asio/detail/timer_queue_base.hpp \
 	asio/detail/timer_queue.hpp \
 	asio/detail/timer_queue_ptime.hpp \
 	asio/detail/timer_queue_set.hpp \
 	asio/detail/timer_scheduler_fwd.hpp \
 	asio/detail/timer_scheduler.hpp \
 	asio/detail/tss_ptr.hpp \
 	asio/detail/type_traits.hpp \
 	asio/detail/variadic_templates.hpp \
 	asio/detail/wait_handler.hpp \
 	asio/detail/wait_op.hpp \
 	asio/detail/winapp_thread.hpp \
 	asio/detail/wince_thread.hpp \
 	asio/detail/win_event.hpp \
 	asio/detail/win_fd_set_adapter.hpp \
 	asio/detail/win_fenced_block.hpp \
 	asio/detail/win_global.hpp \
 	asio/detail/win_iocp_handle_read_op.hpp \
 	asio/detail/win_iocp_handle_service.hpp \
 	asio/detail/win_iocp_handle_write_op.hpp \
 	asio/detail/win_iocp_io_context.hpp \
 	asio/detail/win_iocp_null_buffers_op.hpp \
 	asio/detail/win_iocp_operation.hpp \
 	asio/detail/win_iocp_overlapped_op.hpp \
 	asio/detail/win_iocp_overlapped_ptr.hpp \
 	asio/detail/win_iocp_serial_port_service.hpp \
 	asio/detail/win_iocp_socket_accept_op.hpp \
 	asio/detail/win_iocp_socket_connect_op.hpp \
 	asio/detail/win_iocp_socket_recvfrom_op.hpp \
 	asio/detail/win_iocp_socket_recvmsg_op.hpp \
 	asio/detail/win_iocp_socket_recv_op.hpp \
 	asio/detail/win_iocp_socket_send_op.hpp \
 	asio/detail/win_iocp_socket_service_base.hpp \
 	asio/detail/win_iocp_socket_service.hpp \
 	asio/detail/win_iocp_thread_info.hpp \
 	asio/detail/win_iocp_wait_op.hpp \
 	asio/detail/win_mutex.hpp \
 	asio/detail/win_object_handle_service.hpp \
 	asio/detail/winrt_async_manager.hpp \
 	asio/detail/winrt_async_op.hpp \
 	asio/detail/winrt_resolve_op.hpp \
 	asio/detail/winrt_resolver_service.hpp \
 	asio/detail/winrt_socket_connect_op.hpp \
 	asio/detail/winrt_socket_recv_op.hpp \
 	asio/detail/winrt_socket_send_op.hpp \
 	asio/detail/winrt_ssocket_service_base.hpp \
 	asio/detail/winrt_ssocket_service.hpp \
 	asio/detail/winrt_timer_scheduler.hpp \
 	asio/detail/winrt_utils.hpp \
 	asio/detail/winsock_init.hpp \
 	asio/detail/win_static_mutex.hpp \
 	asio/detail/win_thread.hpp \
 	asio/detail/win_tss_ptr.hpp \
 	asio/detail/work_dispatcher.hpp \
 	asio/detail/wrapped_handler.hpp \
 	asio/dispatch.hpp \
 	asio/error_code.hpp \
 	asio/error.hpp \
 	asio/execution.hpp \
 	asio/execution_context.hpp \
 	asio/execution/allocator.hpp \
 	asio/execution/any_executor.hpp \
 	asio/execution/bad_executor.hpp \
 	asio/execution/blocking.hpp \
 	asio/execution/blocking_adaptation.hpp \
 	asio/execution/bulk_execute.hpp \
 	asio/execution/bulk_guarantee.hpp \
 	asio/execution/connect.hpp \
 	asio/execution/context.hpp \
 	asio/execution/context_as.hpp \
 	asio/execution/detail/as_invocable.hpp \
 	asio/execution/detail/as_operation.hpp \
 	asio/execution/detail/as_receiver.hpp \
 	asio/execution/detail/bulk_sender.hpp \
 	asio/execution/detail/void_receiver.hpp \
 	asio/execution/detail/submit_receiver.hpp \
 	asio/execution/execute.hpp \
 	asio/execution/executor.hpp \
 	asio/execution/impl/bad_executor.ipp \
 	asio/execution/impl/receiver_invocation_error.ipp \
 	asio/execution/invocable_archetype.hpp \
 	asio/execution/mapping.hpp \
 	asio/execution/occupancy.hpp \
 	asio/execution/operation_state.hpp \
 	asio/execution/outstanding_work.hpp \
 	asio/execution/prefer_only.hpp \
 	asio/execution/receiver.hpp \
 	asio/execution/receiver_invocation_error.hpp \
 	asio/execution/relationship.hpp \
 	asio/execution/schedule.hpp \
 	asio/execution/scheduler.hpp \
 	asio/execution/sender.hpp \
 	asio/execution/set_done.hpp \
 	asio/execution/set_error.hpp \
 	asio/execution/set_value.hpp \
 	asio/execution/start.hpp \
 	asio/execution/submit.hpp \
 	asio/executor.hpp \
 	asio/executor_work_guard.hpp \
 	asio/experimental/as_single.hpp \
 	asio/experimental/impl/as_single.hpp \
 	asio/generic/basic_endpoint.hpp \
 	asio/generic/datagram_protocol.hpp \
 	asio/generic/detail/endpoint.hpp \
 	asio/generic/detail/impl/endpoint.ipp \
 	asio/generic/raw_protocol.hpp \
 	asio/generic/seq_packet_protocol.hpp \
 	asio/generic/stream_protocol.hpp \
 	asio/handler_alloc_hook.hpp \
 	asio/handler_continuation_hook.hpp \
 	asio/handler_invoke_hook.hpp \
 	asio/high_resolution_timer.hpp \
 	asio.hpp \
 	asio/impl/awaitable.hpp \
 	asio/impl/buffered_read_stream.hpp \
 	asio/impl/buffered_write_stream.hpp \
 	asio/impl/co_spawn.hpp \
 	asio/impl/compose.hpp \
 	asio/impl/connect.hpp \
 	asio/impl/defer.hpp \
 	asio/impl/detached.hpp \
 	asio/impl/dispatch.hpp \
 	asio/impl/error_code.ipp \
 	asio/impl/error.ipp \
 	asio/impl/execution_context.hpp \
 	asio/impl/execution_context.ipp \
 	asio/impl/executor.hpp \
 	asio/impl/executor.ipp \
 	asio/impl/handler_alloc_hook.ipp \
 	asio/impl/io_context.hpp \
 	asio/impl/io_context.ipp \
 	asio/impl/multiple_exceptions.ipp \
 	asio/impl/post.hpp \
 	asio/impl/read_at.hpp \
 	asio/impl/read.hpp \
 	asio/impl/read_until.hpp \
 	asio/impl/redirect_error.hpp \
 	asio/impl/serial_port_base.hpp \
 	asio/impl/serial_port_base.ipp \
 	asio/impl/spawn.hpp \
 	asio/impl/src.hpp \
 	asio/impl/system_context.hpp \
 	asio/impl/system_context.ipp \
 	asio/impl/system_executor.hpp \
 	asio/impl/thread_pool.hpp \
 	asio/impl/thread_pool.ipp \
 	asio/impl/use_awaitable.hpp \
 	asio/impl/use_future.hpp \
 	asio/impl/write_at.hpp \
 	asio/impl/write.hpp \
 	asio/io_context.hpp \
 	asio/io_context_strand.hpp \
 	asio/io_service.hpp \
 	asio/io_service_strand.hpp \
 	asio/ip/address.hpp \
 	asio/ip/address_v4.hpp \
 	asio/ip/address_v4_iterator.hpp \
 	asio/ip/address_v4_range.hpp \
 	asio/ip/address_v6.hpp \
 	asio/ip/address_v6_iterator.hpp \
 	asio/ip/address_v6_range.hpp \
 	asio/ip/bad_address_cast.hpp \
 	asio/ip/basic_endpoint.hpp \
 	asio/ip/basic_resolver_entry.hpp \
 	asio/ip/basic_resolver.hpp \
 	asio/ip/basic_resolver_iterator.hpp \
 	asio/ip/basic_resolver_query.hpp \
 	asio/ip/basic_resolver_results.hpp \
 	asio/ip/detail/endpoint.hpp \
 	asio/ip/detail/impl/endpoint.ipp \
 	asio/ip/detail/socket_option.hpp \
 	asio/ip/host_name.hpp \
 	asio/ip/icmp.hpp \
 	asio/ip/impl/address.hpp \
 	asio/ip/impl/address.ipp \
 	asio/ip/impl/address_v4.hpp \
 	asio/ip/impl/address_v4.ipp \
 	asio/ip/impl/address_v6.hpp \
 	asio/ip/impl/address_v6.ipp \
 	asio/ip/impl/basic_endpoint.hpp \
 	asio/ip/impl/host_name.ipp \
 	asio/ip/impl/network_v4.hpp \
 	asio/ip/impl/network_v4.ipp \
 	asio/ip/impl/network_v6.hpp \
 	asio/ip/impl/network_v6.ipp \
 	asio/ip/multicast.hpp \
 	asio/ip/network_v4.hpp \
 	asio/ip/network_v6.hpp \
 	asio/ip/resolver_base.hpp \
 	asio/ip/resolver_query_base.hpp \
 	asio/ip/tcp.hpp \
 	asio/ip/udp.hpp \
 	asio/ip/unicast.hpp \
 	asio/ip/v6_only.hpp \
 	asio/is_applicable_property.hpp \
 	asio/is_executor.hpp \
 	asio/is_read_buffered.hpp \
 	asio/is_write_buffered.hpp \
 	asio/local/basic_endpoint.hpp \
 	asio/local/connect_pair.hpp \
 	asio/local/datagram_protocol.hpp \
 	asio/local/detail/endpoint.hpp \
 	asio/local/detail/impl/endpoint.ipp \
 	asio/local/stream_protocol.hpp \
 	asio/multiple_exceptions.hpp \
 	asio/packaged_task.hpp \
 	asio/placeholders.hpp \
 	asio/posix/basic_descriptor.hpp \
 	asio/posix/basic_stream_descriptor.hpp \
 	asio/posix/descriptor_base.hpp \
 	asio/posix/descriptor.hpp \
 	asio/posix/stream_descriptor.hpp \
 	asio/post.hpp \
 	asio/prefer.hpp \
 	asio/query.hpp \
 	asio/read_at.hpp \
 	asio/read.hpp \
 	asio/read_until.hpp \
 	asio/redirect_error.hpp \
 	asio/require.hpp \
 	asio/require_concept.hpp \
 	asio/serial_port_base.hpp \
 	asio/serial_port.hpp \
 	asio/signal_set.hpp \
 	asio/socket_base.hpp \
 	asio/spawn.hpp \
 	asio/ssl/context_base.hpp \
 	asio/ssl/context.hpp \
 	asio/ssl/detail/buffered_handshake_op.hpp \
 	asio/ssl/detail/engine.hpp \
 	asio/ssl/detail/handshake_op.hpp \
 	asio/ssl/detail/impl/engine.ipp \
 	asio/ssl/detail/impl/openssl_init.ipp \
 	asio/ssl/detail/io.hpp \
 	asio/ssl/detail/openssl_init.hpp \
 	asio/ssl/detail/openssl_types.hpp \
 	asio/ssl/detail/password_callback.hpp \
 	asio/ssl/detail/read_op.hpp \
 	asio/ssl/detail/shutdown_op.hpp \
 	asio/ssl/detail/stream_core.hpp \
 	asio/ssl/detail/verify_callback.hpp \
 	asio/ssl/detail/write_op.hpp \
 	asio/ssl/error.hpp \
 	asio/ssl.hpp \
 	asio/ssl/host_name_verification.hpp \
 	asio/ssl/impl/context.hpp \
 	asio/ssl/impl/context.ipp \
 	asio/ssl/impl/error.ipp \
 	asio/ssl/impl/host_name_verification.ipp \
 	asio/ssl/impl/rfc2818_verification.ipp \
 	asio/ssl/impl/src.hpp \
 	asio/ssl/rfc2818_verification.hpp \
 	asio/ssl/stream_base.hpp \
 	asio/ssl/stream.hpp \
 	asio/ssl/verify_context.hpp \
 	asio/ssl/verify_mode.hpp \
 	asio/static_thread_pool.hpp \
 	asio/steady_timer.hpp \
 	asio/strand.hpp \
 	asio/streambuf.hpp \
 	asio/system_context.hpp \
 	asio/system_error.hpp \
 	asio/system_executor.hpp \
 	asio/system_timer.hpp \
 	asio/this_coro.hpp \
 	asio/thread.hpp \
 	asio/thread_pool.hpp \
 	asio/time_traits.hpp \
 	asio/traits/bulk_execute_free.hpp \
 	asio/traits/bulk_execute_member.hpp \
 	asio/traits/connect_free.hpp \
 	asio/traits/connect_member.hpp \
 	asio/traits/equality_comparable.hpp \
 	asio/traits/execute_free.hpp \
 	asio/traits/execute_member.hpp \
 	asio/traits/prefer_free.hpp \
 	asio/traits/prefer_member.hpp \
 	asio/traits/query_free.hpp \
 	asio/traits/query_member.hpp \
 	asio/traits/query_static_constexpr_member.hpp \
 	asio/traits/require_concept_free.hpp \
 	asio/traits/require_concept_member.hpp \
 	asio/traits/require_free.hpp \
 	asio/traits/require_member.hpp \
 	asio/traits/schedule_free.hpp \
 	asio/traits/schedule_member.hpp \
 	asio/traits/set_done_free.hpp \
 	asio/traits/set_done_member.hpp \
 	asio/traits/set_error_free.hpp \
 	asio/traits/set_error_member.hpp \
 	asio/traits/set_value_free.hpp \
 	asio/traits/set_value_member.hpp \
 	asio/traits/start_free.hpp \
 	asio/traits/start_member.hpp \
 	asio/traits/static_query.hpp \
 	asio/traits/static_require.hpp \
 	asio/traits/static_require_concept.hpp \
 	asio/traits/submit_free.hpp \
 	asio/traits/submit_member.hpp \
 	asio/ts/buffer.hpp \
 	asio/ts/executor.hpp \
 	asio/ts/internet.hpp \
 	asio/ts/io_context.hpp \
 	asio/ts/netfwd.hpp \
 	asio/ts/net.hpp \
 	asio/ts/socket.hpp \
 	asio/ts/timer.hpp \
 	asio/unyield.hpp \
 	asio/use_awaitable.hpp \
 	asio/use_future.hpp \
 	asio/uses_executor.hpp \
 	asio/version.hpp \
 	asio/wait_traits.hpp \
 	asio/windows/basic_object_handle.hpp \
 	asio/windows/basic_overlapped_handle.hpp \
 	asio/windows/basic_random_access_handle.hpp \
 	asio/windows/basic_stream_handle.hpp \
 	asio/windows/object_handle.hpp \
 	asio/windows/overlapped_handle.hpp \
 	asio/windows/overlapped_ptr.hpp \
 	asio/windows/random_access_handle.hpp \
 	asio/windows/stream_handle.hpp \
 	asio/write_at.hpp \
 	asio/write.hpp \
 	asio/yield.hpp
 MAINTAINERCLEANFILES = \
 	$(srcdir)/Makefile.in
--- a/module/Vendor/ASIO/include/asio.hpp
+++ b/module/Vendor/ASIO/include/asio.hpp
@ -0,0 +1,182 @@
 //
 // asio.hpp
 // ~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_HPP
 #define ASIO_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/associated_allocator.hpp"
 #include "asio/associated_executor.hpp"
 #include "asio/async_result.hpp"
 #include "asio/awaitable.hpp"
 #include "asio/basic_datagram_socket.hpp"
 #include "asio/basic_deadline_timer.hpp"
 #include "asio/basic_io_object.hpp"
 #include "asio/basic_raw_socket.hpp"
 #include "asio/basic_seq_packet_socket.hpp"
 #include "asio/basic_serial_port.hpp"
 #include "asio/basic_signal_set.hpp"
 #include "asio/basic_socket.hpp"
 #include "asio/basic_socket_acceptor.hpp"
 #include "asio/basic_socket_iostream.hpp"
 #include "asio/basic_socket_streambuf.hpp"
 #include "asio/basic_stream_socket.hpp"
 #include "asio/basic_streambuf.hpp"
 #include "asio/basic_waitable_timer.hpp"
 #include "asio/bind_executor.hpp"
 #include "asio/buffer.hpp"
 #include "asio/buffered_read_stream_fwd.hpp"
 #include "asio/buffered_read_stream.hpp"
 #include "asio/buffered_stream_fwd.hpp"
 #include "asio/buffered_stream.hpp"
 #include "asio/buffered_write_stream_fwd.hpp"
 #include "asio/buffered_write_stream.hpp"
 #include "asio/buffers_iterator.hpp"
 #include "asio/co_spawn.hpp"
 #include "asio/completion_condition.hpp"
 #include "asio/compose.hpp"
 #include "asio/connect.hpp"
 #include "asio/coroutine.hpp"
 #include "asio/deadline_timer.hpp"
 #include "asio/defer.hpp"
 #include "asio/detached.hpp"
 #include "asio/dispatch.hpp"
 #include "asio/error.hpp"
 #include "asio/error_code.hpp"
 #include "asio/execution.hpp"
 #include "asio/execution/allocator.hpp"
 #include "asio/execution/any_executor.hpp"
 #include "asio/execution/blocking.hpp"
 #include "asio/execution/blocking_adaptation.hpp"
 #include "asio/execution/bulk_execute.hpp"
 #include "asio/execution/bulk_guarantee.hpp"
 #include "asio/execution/connect.hpp"
 #include "asio/execution/context.hpp"
 #include "asio/execution/context_as.hpp"
 #include "asio/execution/execute.hpp"
 #include "asio/execution/executor.hpp"
 #include "asio/execution/invocable_archetype.hpp"
 #include "asio/execution/mapping.hpp"
 #include "asio/execution/occupancy.hpp"
 #include "asio/execution/operation_state.hpp"
 #include "asio/execution/outstanding_work.hpp"
 #include "asio/execution/prefer_only.hpp"
 #include "asio/execution/receiver.hpp"
 #include "asio/execution/receiver_invocation_error.hpp"
 #include "asio/execution/relationship.hpp"
 #include "asio/execution/schedule.hpp"
 #include "asio/execution/scheduler.hpp"
 #include "asio/execution/sender.hpp"
 #include "asio/execution/set_done.hpp"
 #include "asio/execution/set_error.hpp"
 #include "asio/execution/set_value.hpp"
 #include "asio/execution/start.hpp"
 #include "asio/execution_context.hpp"
 #include "asio/executor.hpp"
 #include "asio/executor_work_guard.hpp"
 #include "asio/generic/basic_endpoint.hpp"
 #include "asio/generic/datagram_protocol.hpp"
 #include "asio/generic/raw_protocol.hpp"
 #include "asio/generic/seq_packet_protocol.hpp"
 #include "asio/generic/stream_protocol.hpp"
 #include "asio/handler_alloc_hook.hpp"
 #include "asio/handler_continuation_hook.hpp"
 #include "asio/handler_invoke_hook.hpp"
 #include "asio/high_resolution_timer.hpp"
 #include "asio/io_context.hpp"
 #include "asio/io_context_strand.hpp"
 #include "asio/io_service.hpp"
 #include "asio/io_service_strand.hpp"
 #include "asio/ip/address.hpp"
 #include "asio/ip/address_v4.hpp"
 #include "asio/ip/address_v4_iterator.hpp"
 #include "asio/ip/address_v4_range.hpp"
 #include "asio/ip/address_v6.hpp"
 #include "asio/ip/address_v6_iterator.hpp"
 #include "asio/ip/address_v6_range.hpp"
 #include "asio/ip/network_v4.hpp"
 #include "asio/ip/network_v6.hpp"
 #include "asio/ip/bad_address_cast.hpp"
 #include "asio/ip/basic_endpoint.hpp"
 #include "asio/ip/basic_resolver.hpp"
 #include "asio/ip/basic_resolver_entry.hpp"
 #include "asio/ip/basic_resolver_iterator.hpp"
 #include "asio/ip/basic_resolver_query.hpp"
 #include "asio/ip/host_name.hpp"
 #include "asio/ip/icmp.hpp"
 #include "asio/ip/multicast.hpp"
 #include "asio/ip/resolver_base.hpp"
 #include "asio/ip/resolver_query_base.hpp"
 #include "asio/ip/tcp.hpp"
 #include "asio/ip/udp.hpp"
 #include "asio/ip/unicast.hpp"
 #include "asio/ip/v6_only.hpp"
 #include "asio/is_applicable_property.hpp"
 #include "asio/is_executor.hpp"
 #include "asio/is_read_buffered.hpp"
 #include "asio/is_write_buffered.hpp"
 #include "asio/local/basic_endpoint.hpp"
 #include "asio/local/connect_pair.hpp"
 #include "asio/local/datagram_protocol.hpp"
 #include "asio/local/stream_protocol.hpp"
 #include "asio/multiple_exceptions.hpp"
 #include "asio/packaged_task.hpp"
 #include "asio/placeholders.hpp"
 #include "asio/posix/basic_descriptor.hpp"
 #include "asio/posix/basic_stream_descriptor.hpp"
 #include "asio/posix/descriptor.hpp"
 #include "asio/posix/descriptor_base.hpp"
 #include "asio/posix/stream_descriptor.hpp"
 #include "asio/post.hpp"
 #include "asio/prefer.hpp"
 #include "asio/query.hpp"
 #include "asio/read.hpp"
 #include "asio/read_at.hpp"
 #include "asio/read_until.hpp"
 #include "asio/redirect_error.hpp"
 #include "asio/require.hpp"
 #include "asio/require_concept.hpp"
 #include "asio/serial_port.hpp"
 #include "asio/serial_port_base.hpp"
 #include "asio/signal_set.hpp"
 #include "asio/socket_base.hpp"
 #include "asio/static_thread_pool.hpp"
 #include "asio/steady_timer.hpp"
 #include "asio/strand.hpp"
 #include "asio/streambuf.hpp"
 #include "asio/system_context.hpp"
 #include "asio/system_error.hpp"
 #include "asio/system_executor.hpp"
 #include "asio/system_timer.hpp"
 #include "asio/this_coro.hpp"
 #include "asio/thread.hpp"
 #include "asio/thread_pool.hpp"
 #include "asio/time_traits.hpp"
 #include "asio/use_awaitable.hpp"
 #include "asio/use_future.hpp"
 #include "asio/uses_executor.hpp"
 #include "asio/version.hpp"
 #include "asio/wait_traits.hpp"
 #include "asio/windows/basic_object_handle.hpp"
 #include "asio/windows/basic_overlapped_handle.hpp"
 #include "asio/windows/basic_random_access_handle.hpp"
 #include "asio/windows/basic_stream_handle.hpp"
 #include "asio/windows/object_handle.hpp"
 #include "asio/windows/overlapped_handle.hpp"
 #include "asio/windows/overlapped_ptr.hpp"
 #include "asio/windows/random_access_handle.hpp"
 #include "asio/windows/stream_handle.hpp"
 #include "asio/write.hpp"
 #include "asio/write_at.hpp"
 #endif // ASIO_HPP
--- a/module/Vendor/ASIO/include/asio/any_io_executor.hpp
+++ b/module/Vendor/ASIO/include/asio/any_io_executor.hpp
@ -0,0 +1,71 @@
 //
 // any_io_executor.hpp
 // ~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_ANY_IO_EXECUTOR_HPP
 #define ASIO_ANY_IO_EXECUTOR_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if defined(ASIO_USE_TS_EXECUTOR_AS_DEFAULT)
 # include "asio/executor.hpp"
 #else // defined(ASIO_USE_TS_EXECUTOR_AS_DEFAULT)
 # include "asio/execution.hpp"
 # include "asio/execution_context.hpp"
 #endif // defined(ASIO_USE_TS_EXECUTOR_AS_DEFAULT)
 #include "asio/detail/push_options.hpp"
 namespace asio {
 #if defined(ASIO_USE_TS_EXECUTOR_AS_DEFAULT)
 typedef executor any_io_executor;
 #else // defined(ASIO_USE_TS_EXECUTOR_AS_DEFAULT)
 /// Polymorphic executor type for use with I/O objects.
 /**
 * The @c any_io_executor type is a polymorphic executor that supports the set
 * of properties required by I/O objects. It is defined as the
 * execution::any_executor class template parameterised as follows:
 * @code execution::any_executor<
 *   execution::context_as_t<execution_context&>,
 *   execution::blocking_t::never_t,
 *   execution::prefer_only<execution::blocking_t::possibly_t>,
 *   execution::prefer_only<execution::outstanding_work_t::tracked_t>,
 *   execution::prefer_only<execution::outstanding_work_t::untracked_t>,
 *   execution::prefer_only<execution::relationship_t::fork_t>,
 *   execution::prefer_only<execution::relationship_t::continuation_t>
 * > @endcode
 */
 #if defined(GENERATING_DOCUMENTATION)
 typedef execution::any_executor<...> any_io_executor;
 #else // defined(GENERATING_DOCUMENTATION)
 typedef execution::any_executor<
    execution::context_as_t<execution_context&>,
    execution::blocking_t::never_t,
    execution::prefer_only<execution::blocking_t::possibly_t>,
    execution::prefer_only<execution::outstanding_work_t::tracked_t>,
    execution::prefer_only<execution::outstanding_work_t::untracked_t>,
    execution::prefer_only<execution::relationship_t::fork_t>,
    execution::prefer_only<execution::relationship_t::continuation_t>
  > any_io_executor;
 #endif // defined(GENERATING_DOCUMENTATION)
 #endif // defined(ASIO_USE_TS_EXECUTOR_AS_DEFAULT)
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_ANY_IO_EXECUTOR_HPP
--- a/module/Vendor/ASIO/include/asio/associated_allocator.hpp
+++ b/module/Vendor/ASIO/include/asio/associated_allocator.hpp
@ -0,0 +1,125 @@
 //
 // associated_allocator.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_ASSOCIATED_ALLOCATOR_HPP
 #define ASIO_ASSOCIATED_ALLOCATOR_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include <memory>
 #include "asio/detail/type_traits.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 template <typename T, typename E, typename = void>
 struct associated_allocator_impl
 {
  typedef E type;
  static type get(const T&, const E& e) ASIO_NOEXCEPT
  {
    return e;
  }
 };
 template <typename T, typename E>
 struct associated_allocator_impl<T, E,
  typename void_type<typename T::allocator_type>::type>
 {
  typedef typename T::allocator_type type;
  static type get(const T& t, const E&) ASIO_NOEXCEPT
  {
    return t.get_allocator();
  }
 };
 } // namespace detail
 /// Traits type used to obtain the allocator associated with an object.
 /**
 * A program may specialise this traits type if the @c T template parameter in
 * the specialisation is a user-defined type. The template parameter @c
 * Allocator shall be a type meeting the Allocator requirements.
 *
 * Specialisations shall meet the following requirements, where @c t is a const
 * reference to an object of type @c T, and @c a is an object of type @c
 * Allocator.
 *
 * @li Provide a nested typedef @c type that identifies a type meeting the
 * Allocator requirements.
 *
 * @li Provide a noexcept static member function named @c get, callable as @c
 * get(t) and with return type @c type.
 *
 * @li Provide a noexcept static member function named @c get, callable as @c
 * get(t,a) and with return type @c type.
 */
 template <typename T, typename Allocator = std::allocator<void> >
 struct associated_allocator
 {
  /// If @c T has a nested type @c allocator_type, <tt>T::allocator_type</tt>.
  /// Otherwise @c Allocator.
 #if defined(GENERATING_DOCUMENTATION)
  typedef see_below type;
 #else // defined(GENERATING_DOCUMENTATION)
  typedef typename detail::associated_allocator_impl<T, Allocator>::type type;
 #endif // defined(GENERATING_DOCUMENTATION)
  /// If @c T has a nested type @c allocator_type, returns
  /// <tt>t.get_allocator()</tt>. Otherwise returns @c a.
  static type get(const T& t,
      const Allocator& a = Allocator()) ASIO_NOEXCEPT
  {
    return detail::associated_allocator_impl<T, Allocator>::get(t, a);
  }
 };
 /// Helper function to obtain an object's associated allocator.
 /**
 * @returns <tt>associated_allocator<T>::get(t)</tt>
 */
 template <typename T>
 inline typename associated_allocator<T>::type
 get_associated_allocator(const T& t) ASIO_NOEXCEPT
 {
  return associated_allocator<T>::get(t);
 }
 /// Helper function to obtain an object's associated allocator.
 /**
 * @returns <tt>associated_allocator<T, Allocator>::get(t, a)</tt>
 */
 template <typename T, typename Allocator>
 inline typename associated_allocator<T, Allocator>::type
 get_associated_allocator(const T& t, const Allocator& a) ASIO_NOEXCEPT
 {
  return associated_allocator<T, Allocator>::get(t, a);
 }
 #if defined(ASIO_HAS_ALIAS_TEMPLATES)
 template <typename T, typename Allocator = std::allocator<void> >
 using associated_allocator_t
  = typename associated_allocator<T, Allocator>::type;
 #endif // defined(ASIO_HAS_ALIAS_TEMPLATES)
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_ASSOCIATED_ALLOCATOR_HPP
--- a/module/Vendor/ASIO/include/asio/associated_executor.hpp
+++ b/module/Vendor/ASIO/include/asio/associated_executor.hpp
@ -0,0 +1,166 @@
 //
 // associated_executor.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_ASSOCIATED_EXECUTOR_HPP
 #define ASIO_ASSOCIATED_EXECUTOR_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/execution/executor.hpp"
 #include "asio/is_executor.hpp"
 #include "asio/system_executor.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 template <typename T, typename E, typename = void>
 struct associated_executor_impl
 {
  typedef void asio_associated_executor_is_unspecialised;
  typedef E type;
  static type get(const T&, const E& e = E()) ASIO_NOEXCEPT
  {
    return e;
  }
 };
 template <typename T, typename E>
 struct associated_executor_impl<T, E,
  typename void_type<typename T::executor_type>::type>
 {
  typedef typename T::executor_type type;
  static type get(const T& t, const E& = E()) ASIO_NOEXCEPT
  {
    return t.get_executor();
  }
 };
 } // namespace detail
 /// Traits type used to obtain the executor associated with an object.
 /**
 * A program may specialise this traits type if the @c T template parameter in
 * the specialisation is a user-defined type. The template parameter @c
 * Executor shall be a type meeting the Executor requirements.
 *
 * Specialisations shall meet the following requirements, where @c t is a const
 * reference to an object of type @c T, and @c e is an object of type @c
 * Executor.
 *
 * @li Provide a nested typedef @c type that identifies a type meeting the
 * Executor requirements.
 *
 * @li Provide a noexcept static member function named @c get, callable as @c
 * get(t) and with return type @c type.
 *
 * @li Provide a noexcept static member function named @c get, callable as @c
 * get(t,e) and with return type @c type.
 */
 template <typename T, typename Executor = system_executor>
 struct associated_executor
 #if !defined(GENERATING_DOCUMENTATION)
  : detail::associated_executor_impl<T, Executor>
 #endif // !defined(GENERATING_DOCUMENTATION)
 {
 #if defined(GENERATING_DOCUMENTATION)
  /// If @c T has a nested type @c executor_type, <tt>T::executor_type</tt>.
  /// Otherwise @c Executor.
  typedef see_below type;
  /// If @c T has a nested type @c executor_type, returns
  /// <tt>t.get_executor()</tt>. Otherwise returns @c ex.
  static type get(const T& t,
      const Executor& ex = Executor()) ASIO_NOEXCEPT;
 #endif // defined(GENERATING_DOCUMENTATION)
 };
 /// Helper function to obtain an object's associated executor.
 /**
 * @returns <tt>associated_executor<T>::get(t)</tt>
 */
 template <typename T>
 inline typename associated_executor<T>::type
 get_associated_executor(const T& t) ASIO_NOEXCEPT
 {
  return associated_executor<T>::get(t);
 }
 /// Helper function to obtain an object's associated executor.
 /**
 * @returns <tt>associated_executor<T, Executor>::get(t, ex)</tt>
 */
 template <typename T, typename Executor>
 inline typename associated_executor<T, Executor>::type
 get_associated_executor(const T& t, const Executor& ex,
    typename enable_if<
      is_executor<Executor>::value || execution::is_executor<Executor>::value
    >::type* = 0) ASIO_NOEXCEPT
 {
  return associated_executor<T, Executor>::get(t, ex);
 }
 /// Helper function to obtain an object's associated executor.
 /**
 * @returns <tt>associated_executor<T, typename
 * ExecutionContext::executor_type>::get(t, ctx.get_executor())</tt>
 */
 template <typename T, typename ExecutionContext>
 inline typename associated_executor<T,
  typename ExecutionContext::executor_type>::type
 get_associated_executor(const T& t, ExecutionContext& ctx,
    typename enable_if<is_convertible<ExecutionContext&,
      execution_context&>::value>::type* = 0) ASIO_NOEXCEPT
 {
  return associated_executor<T,
    typename ExecutionContext::executor_type>::get(t, ctx.get_executor());
 }
 #if defined(ASIO_HAS_ALIAS_TEMPLATES)
 template <typename T, typename Executor = system_executor>
 using associated_executor_t = typename associated_executor<T, Executor>::type;
 #endif // defined(ASIO_HAS_ALIAS_TEMPLATES)
 namespace detail {
 template <typename T, typename E, typename = void>
 struct associated_executor_forwarding_base
 {
 };
 template <typename T, typename E>
 struct associated_executor_forwarding_base<T, E,
    typename enable_if<
      is_same<
        typename associated_executor<T,
          E>::asio_associated_executor_is_unspecialised,
        void
      >::value
    >::type>
 {
  typedef void asio_associated_executor_is_unspecialised;
 };
 } // namespace detail
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_ASSOCIATED_EXECUTOR_HPP
--- a/module/Vendor/ASIO/include/asio/async_result.hpp
+++ b/module/Vendor/ASIO/include/asio/async_result.hpp
@ -0,0 +1,582 @@
 //
 // async_result.hpp
 // ~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_ASYNC_RESULT_HPP
 #define ASIO_ASYNC_RESULT_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/detail/variadic_templates.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 #if defined(ASIO_HAS_CONCEPTS) \
  && defined(ASIO_HAS_VARIADIC_TEMPLATES) \
  && defined(ASIO_HAS_DECLTYPE)
 namespace detail {
 template <typename T>
 struct is_completion_signature : false_type
 {
 };
 template <typename R, typename... Args>
 struct is_completion_signature<R(Args...)> : true_type
 {
 };
 template <typename T, typename... Args>
 ASIO_CONCEPT callable_with = requires(T t, Args&&... args)
 {
  t(static_cast<Args&&>(args)...);
 };
 template <typename T, typename Signature>
 struct is_completion_handler_for : false_type
 {
 };
 template <typename T, typename R, typename... Args>
 struct is_completion_handler_for<T, R(Args...)>
  : integral_constant<bool, (callable_with<T, Args...>)>
 {
 };
 } // namespace detail
 template <typename T>
 ASIO_CONCEPT completion_signature =
  detail::is_completion_signature<T>::value;
 #define ASIO_COMPLETION_SIGNATURE \
  ::asio::completion_signature
 template <typename T, typename Signature>
 ASIO_CONCEPT completion_handler_for =
  detail::is_completion_signature<Signature>::value
    && detail::is_completion_handler_for<T, Signature>::value;
 #define ASIO_COMPLETION_HANDLER_FOR(s) \
  ::asio::completion_handler_for<s>
 #else // defined(ASIO_HAS_CONCEPTS)
      //   && defined(ASIO_HAS_VARIADIC_TEMPLATES)
      //   && defined(ASIO_HAS_DECLTYPE)
 #define ASIO_COMPLETION_SIGNATURE typename
 #define ASIO_COMPLETION_HANDLER_FOR(s) typename
 #endif // defined(ASIO_HAS_CONCEPTS)
       //   && defined(ASIO_HAS_VARIADIC_TEMPLATES)
       //   && defined(ASIO_HAS_DECLTYPE)
 /// An interface for customising the behaviour of an initiating function.
 /**
 * The async_result traits class is used for determining:
 *
 * @li the concrete completion handler type to be called at the end of the
 * asynchronous operation;
 *
 * @li the initiating function return type; and
 *
 * @li how the return value of the initiating function is obtained.
 *
 * The trait allows the handler and return types to be determined at the point
 * where the specific completion handler signature is known.
 *
 * This template may be specialised for user-defined completion token types.
 * The primary template assumes that the CompletionToken is the completion
 * handler.
 */
 template <typename CompletionToken, ASIO_COMPLETION_SIGNATURE Signature>
 class async_result
 {
 public:
  /// The concrete completion handler type for the specific signature.
  typedef CompletionToken completion_handler_type;
  /// The return type of the initiating function.
  typedef void return_type;
  /// Construct an async result from a given handler.
  /**
   * When using a specalised async_result, the constructor has an opportunity
   * to initialise some state associated with the completion handler, which is
   * then returned from the initiating function.
   */
  explicit async_result(completion_handler_type& h)
  {
    (void)h;
  }
  /// Obtain the value to be returned from the initiating function.
  return_type get()
  {
  }
 #if defined(GENERATING_DOCUMENTATION)
  /// Initiate the asynchronous operation that will produce the result, and
  /// obtain the value to be returned from the initiating function.
  template <typename Initiation, typename RawCompletionToken, typename... Args>
  static return_type initiate(
      ASIO_MOVE_ARG(Initiation) initiation,
      ASIO_MOVE_ARG(RawCompletionToken) token,
      ASIO_MOVE_ARG(Args)... args);
 #elif defined(ASIO_HAS_VARIADIC_TEMPLATES)
  template <typename Initiation,
      ASIO_COMPLETION_HANDLER_FOR(Signature) RawCompletionToken,
      typename... Args>
  static return_type initiate(
      ASIO_MOVE_ARG(Initiation) initiation,
      ASIO_MOVE_ARG(RawCompletionToken) token,
      ASIO_MOVE_ARG(Args)... args)
  {
    ASIO_MOVE_CAST(Initiation)(initiation)(
        ASIO_MOVE_CAST(RawCompletionToken)(token),
        ASIO_MOVE_CAST(Args)(args)...);
  }
 #else // defined(ASIO_HAS_VARIADIC_TEMPLATES)
  template <typename Initiation,
      ASIO_COMPLETION_HANDLER_FOR(Signature) RawCompletionToken>
  static return_type initiate(
      ASIO_MOVE_ARG(Initiation) initiation,
      ASIO_MOVE_ARG(RawCompletionToken) token)
  {
    ASIO_MOVE_CAST(Initiation)(initiation)(
        ASIO_MOVE_CAST(RawCompletionToken)(token));
  }
 #define ASIO_PRIVATE_INITIATE_DEF(n) \
  template <typename Initiation, \
      ASIO_COMPLETION_HANDLER_FOR(Signature) RawCompletionToken, \
      ASIO_VARIADIC_TPARAMS(n)> \
  static return_type initiate( \
      ASIO_MOVE_ARG(Initiation) initiation, \
      ASIO_MOVE_ARG(RawCompletionToken) token, \
      ASIO_VARIADIC_MOVE_PARAMS(n)) \
  { \
    ASIO_MOVE_CAST(Initiation)(initiation)( \
        ASIO_MOVE_CAST(RawCompletionToken)(token), \
        ASIO_VARIADIC_MOVE_ARGS(n)); \
  } \
  /**/
  ASIO_VARIADIC_GENERATE(ASIO_PRIVATE_INITIATE_DEF)
 #undef ASIO_PRIVATE_INITIATE_DEF
 #endif // defined(ASIO_HAS_VARIADIC_TEMPLATES)
 private:
  async_result(const async_result&) ASIO_DELETED;
  async_result& operator=(const async_result&) ASIO_DELETED;
 };
 #if !defined(GENERATING_DOCUMENTATION)
 template <ASIO_COMPLETION_SIGNATURE Signature>
 class async_result<void, Signature>
 {
  // Empty.
 };
 #endif // !defined(GENERATING_DOCUMENTATION)
 /// Helper template to deduce the handler type from a CompletionToken, capture
 /// a local copy of the handler, and then create an async_result for the
 /// handler.
 template <typename CompletionToken, ASIO_COMPLETION_SIGNATURE Signature>
 struct async_completion
 {
  /// The real handler type to be used for the asynchronous operation.
  typedef typename asio::async_result<
    typename decay<CompletionToken>::type,
      Signature>::completion_handler_type completion_handler_type;
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Constructor.
  /**
   * The constructor creates the concrete completion handler and makes the link
   * between the handler and the asynchronous result.
   */
  explicit async_completion(CompletionToken& token)
    : completion_handler(static_cast<typename conditional<
        is_same<CompletionToken, completion_handler_type>::value,
        completion_handler_type&, CompletionToken&&>::type>(token)),
      result(completion_handler)
  {
  }
 #else // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  explicit async_completion(typename decay<CompletionToken>::type& token)
    : completion_handler(token),
      result(completion_handler)
  {
  }
  explicit async_completion(const typename decay<CompletionToken>::type& token)
    : completion_handler(token),
      result(completion_handler)
  {
  }
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// A copy of, or reference to, a real handler object.
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  typename conditional<
    is_same<CompletionToken, completion_handler_type>::value,
    completion_handler_type&, completion_handler_type>::type completion_handler;
 #else // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  completion_handler_type completion_handler;
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// The result of the asynchronous operation's initiating function.
  async_result<typename decay<CompletionToken>::type, Signature> result;
 };
 namespace detail {
 template <typename CompletionToken, typename Signature>
 struct async_result_helper
  : async_result<typename decay<CompletionToken>::type, Signature>
 {
 };
 struct async_result_memfns_base
 {
  void initiate();
 };
 template <typename T>
 struct async_result_memfns_derived
  : T, async_result_memfns_base
 {
 };
 template <typename T, T>
 struct async_result_memfns_check
 {
 };
 template <typename>
 char (&async_result_initiate_memfn_helper(...))[2];
 template <typename T>
 char async_result_initiate_memfn_helper(
    async_result_memfns_check<
      void (async_result_memfns_base::*)(),
      &async_result_memfns_derived<T>::initiate>*);
 template <typename CompletionToken, typename Signature>
 struct async_result_has_initiate_memfn
  : integral_constant<bool, sizeof(async_result_initiate_memfn_helper<
      async_result<typename decay<CompletionToken>::type, Signature>
    >(0)) != 1>
 {
 };
 } // namespace detail
 #if defined(GENERATING_DOCUMENTATION)
 # define ASIO_INITFN_RESULT_TYPE(ct, sig) \
  void_or_deduced
 #elif defined(_MSC_VER) && (_MSC_VER < 1500)
 # define ASIO_INITFN_RESULT_TYPE(ct, sig) \
  typename ::asio::detail::async_result_helper< \
    ct, sig>::return_type
 #define ASIO_HANDLER_TYPE(ct, sig) \
  typename ::asio::detail::async_result_helper< \
    ct, sig>::completion_handler_type
 #else
 # define ASIO_INITFN_RESULT_TYPE(ct, sig) \
  typename ::asio::async_result< \
    typename ::asio::decay<ct>::type, sig>::return_type
 #define ASIO_HANDLER_TYPE(ct, sig) \
  typename ::asio::async_result< \
    typename ::asio::decay<ct>::type, sig>::completion_handler_type
 #endif
 #if defined(GENERATING_DOCUMENTATION)
 # define ASIO_INITFN_AUTO_RESULT_TYPE(ct, sig) \
  auto
 #elif defined(ASIO_HAS_RETURN_TYPE_DEDUCTION)
 # define ASIO_INITFN_AUTO_RESULT_TYPE(ct, sig) \
  auto
 #else
 # define ASIO_INITFN_AUTO_RESULT_TYPE(ct, sig) \
  ASIO_INITFN_RESULT_TYPE(ct, sig)
 #endif
 #if defined(GENERATING_DOCUMENTATION)
 # define ASIO_INITFN_DEDUCED_RESULT_TYPE(ct, sig, expr) \
  void_or_deduced
 #elif defined(ASIO_HAS_DECLTYPE)
 # define ASIO_INITFN_DEDUCED_RESULT_TYPE(ct, sig, expr) \
  decltype expr
 #else
 # define ASIO_INITFN_DEDUCED_RESULT_TYPE(ct, sig, expr) \
  ASIO_INITFN_RESULT_TYPE(ct, sig)
 #endif
 #if defined(GENERATING_DOCUMENTATION)
 template <typename CompletionToken,
    completion_signature Signature,
    typename Initiation, typename... Args>
 void_or_deduced async_initiate(
    ASIO_MOVE_ARG(Initiation) initiation,
    ASIO_NONDEDUCED_MOVE_ARG(CompletionToken),
    ASIO_MOVE_ARG(Args)... args);
 #elif defined(ASIO_HAS_VARIADIC_TEMPLATES)
 template <typename CompletionToken,
    ASIO_COMPLETION_SIGNATURE Signature,
    typename Initiation, typename... Args>
 inline typename enable_if<
    detail::async_result_has_initiate_memfn<CompletionToken, Signature>::value,
    ASIO_INITFN_DEDUCED_RESULT_TYPE(CompletionToken, Signature,
      (async_result<typename decay<CompletionToken>::type,
        Signature>::initiate(declval<ASIO_MOVE_ARG(Initiation)>(),
          declval<ASIO_MOVE_ARG(CompletionToken)>(),
          declval<ASIO_MOVE_ARG(Args)>()...)))>::type
 async_initiate(ASIO_MOVE_ARG(Initiation) initiation,
    ASIO_NONDEDUCED_MOVE_ARG(CompletionToken) token,
    ASIO_MOVE_ARG(Args)... args)
 {
  return async_result<typename decay<CompletionToken>::type,
    Signature>::initiate(ASIO_MOVE_CAST(Initiation)(initiation),
      ASIO_MOVE_CAST(CompletionToken)(token),
      ASIO_MOVE_CAST(Args)(args)...);
 }
 template <typename CompletionToken,
    ASIO_COMPLETION_SIGNATURE Signature,
    typename Initiation, typename... Args>
 inline typename enable_if<
    !detail::async_result_has_initiate_memfn<CompletionToken, Signature>::value,
    ASIO_INITFN_RESULT_TYPE(CompletionToken, Signature)>::type
 async_initiate(ASIO_MOVE_ARG(Initiation) initiation,
    ASIO_NONDEDUCED_MOVE_ARG(CompletionToken) token,
    ASIO_MOVE_ARG(Args)... args)
 {
  async_completion<CompletionToken, Signature> completion(token);
  ASIO_MOVE_CAST(Initiation)(initiation)(
      ASIO_MOVE_CAST(ASIO_HANDLER_TYPE(CompletionToken,
        Signature))(completion.completion_handler),
      ASIO_MOVE_CAST(Args)(args)...);
  return completion.result.get();
 }
 #else // defined(ASIO_HAS_VARIADIC_TEMPLATES)
 template <typename CompletionToken,
    ASIO_COMPLETION_SIGNATURE Signature,
    typename Initiation>
 inline typename enable_if<
    detail::async_result_has_initiate_memfn<CompletionToken, Signature>::value,
    ASIO_INITFN_DEDUCED_RESULT_TYPE(CompletionToken, Signature,
      (async_result<typename decay<CompletionToken>::type,
        Signature>::initiate(declval<ASIO_MOVE_ARG(Initiation)>(),
          declval<ASIO_MOVE_ARG(CompletionToken)>())))>::type
 async_initiate(ASIO_MOVE_ARG(Initiation) initiation,
    ASIO_NONDEDUCED_MOVE_ARG(CompletionToken) token)
 {
  return async_result<typename decay<CompletionToken>::type,
    Signature>::initiate(ASIO_MOVE_CAST(Initiation)(initiation),
      ASIO_MOVE_CAST(CompletionToken)(token));
 }
 template <typename CompletionToken,
    ASIO_COMPLETION_SIGNATURE Signature,
    typename Initiation>
 inline typename enable_if<
    !detail::async_result_has_initiate_memfn<CompletionToken, Signature>::value,
    ASIO_INITFN_RESULT_TYPE(CompletionToken, Signature)>::type
 async_initiate(ASIO_MOVE_ARG(Initiation) initiation,
    ASIO_NONDEDUCED_MOVE_ARG(CompletionToken) token)
 {
  async_completion<CompletionToken, Signature> completion(token);
  ASIO_MOVE_CAST(Initiation)(initiation)(
      ASIO_MOVE_CAST(ASIO_HANDLER_TYPE(CompletionToken,
        Signature))(completion.completion_handler));
  return completion.result.get();
 }
 #define ASIO_PRIVATE_INITIATE_DEF(n) \
  template <typename CompletionToken, \
      ASIO_COMPLETION_SIGNATURE Signature, \
      typename Initiation, ASIO_VARIADIC_TPARAMS(n)> \
  inline typename enable_if< \
      detail::async_result_has_initiate_memfn< \
        CompletionToken, Signature>::value, \
      ASIO_INITFN_DEDUCED_RESULT_TYPE(CompletionToken, Signature, \
        (async_result<typename decay<CompletionToken>::type, \
          Signature>::initiate(declval<ASIO_MOVE_ARG(Initiation)>(), \
            declval<ASIO_MOVE_ARG(CompletionToken)>(), \
            ASIO_VARIADIC_MOVE_DECLVAL(n))))>::type \
  async_initiate(ASIO_MOVE_ARG(Initiation) initiation, \
      ASIO_NONDEDUCED_MOVE_ARG(CompletionToken) token, \
      ASIO_VARIADIC_MOVE_PARAMS(n)) \
  { \
    return async_result<typename decay<CompletionToken>::type, \
      Signature>::initiate(ASIO_MOVE_CAST(Initiation)(initiation), \
        ASIO_MOVE_CAST(CompletionToken)(token), \
        ASIO_VARIADIC_MOVE_ARGS(n)); \
  } \
  \
  template <typename CompletionToken, \
      ASIO_COMPLETION_SIGNATURE Signature, \
      typename Initiation, ASIO_VARIADIC_TPARAMS(n)> \
  inline typename enable_if< \
      !detail::async_result_has_initiate_memfn< \
        CompletionToken, Signature>::value, \
      ASIO_INITFN_RESULT_TYPE(CompletionToken, Signature)>::type \
  async_initiate(ASIO_MOVE_ARG(Initiation) initiation, \
      ASIO_NONDEDUCED_MOVE_ARG(CompletionToken) token, \
      ASIO_VARIADIC_MOVE_PARAMS(n)) \
  { \
    async_completion<CompletionToken, Signature> completion(token); \
  \
    ASIO_MOVE_CAST(Initiation)(initiation)( \
        ASIO_MOVE_CAST(ASIO_HANDLER_TYPE(CompletionToken, \
          Signature))(completion.completion_handler), \
        ASIO_VARIADIC_MOVE_ARGS(n)); \
  \
    return completion.result.get(); \
  } \
  /**/
  ASIO_VARIADIC_GENERATE(ASIO_PRIVATE_INITIATE_DEF)
 #undef ASIO_PRIVATE_INITIATE_DEF
 #endif // defined(ASIO_HAS_VARIADIC_TEMPLATES)
 #if defined(ASIO_HAS_CONCEPTS) \
  && defined(ASIO_HAS_VARIADIC_TEMPLATES) \
  && defined(ASIO_HAS_DECLTYPE)
 namespace detail {
 template <typename Signature>
 struct initiation_archetype
 {
  template <completion_handler_for<Signature> CompletionHandler>
  void operator()(CompletionHandler&&) const
  {
  }
 };
 } // namespace detail
 template <typename T, typename Signature>
 ASIO_CONCEPT completion_token_for =
  detail::is_completion_signature<Signature>::value
  &&
  requires(T&& t)
  {
    async_initiate<T, Signature>(detail::initiation_archetype<Signature>{}, t);
  };
 #define ASIO_COMPLETION_TOKEN_FOR(s) \
  ::asio::completion_token_for<s>
 #else // defined(ASIO_HAS_CONCEPTS)
      //   && defined(ASIO_HAS_VARIADIC_TEMPLATES)
      //   && defined(ASIO_HAS_DECLTYPE)
 #define ASIO_COMPLETION_TOKEN_FOR(s) typename
 #endif // defined(ASIO_HAS_CONCEPTS)
       //   && defined(ASIO_HAS_VARIADIC_TEMPLATES)
       //   && defined(ASIO_HAS_DECLTYPE)
 namespace detail {
 template <typename T, typename = void>
 struct default_completion_token_impl
 {
  typedef void type;
 };
 template <typename T>
 struct default_completion_token_impl<T,
  typename void_type<typename T::default_completion_token_type>::type>
 {
  typedef typename T::default_completion_token_type type;
 };
 } // namespace detail
 #if defined(GENERATING_DOCUMENTATION)
 /// Traits type used to determine the default completion token type associated
 /// with a type (such as an executor).
 /**
 * A program may specialise this traits type if the @c T template parameter in
 * the specialisation is a user-defined type.
 *
 * Specialisations of this trait may provide a nested typedef @c type, which is
 * a default-constructible completion token type.
 */
 template <typename T>
 struct default_completion_token
 {
  /// If @c T has a nested type @c default_completion_token_type,
  /// <tt>T::default_completion_token_type</tt>. Otherwise the typedef @c type
  /// is not defined.
  typedef see_below type;
 };
 #else
 template <typename T>
 struct default_completion_token
  : detail::default_completion_token_impl<T>
 {
 };
 #endif
 #if defined(ASIO_HAS_ALIAS_TEMPLATES)
 template <typename T>
 using default_completion_token_t = typename default_completion_token<T>::type;
 #endif // defined(ASIO_HAS_ALIAS_TEMPLATES)
 #if defined(ASIO_HAS_DEFAULT_FUNCTION_TEMPLATE_ARGUMENTS)
 #define ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(e) \
  = typename ::asio::default_completion_token<e>::type
 #define ASIO_DEFAULT_COMPLETION_TOKEN(e) \
  = typename ::asio::default_completion_token<e>::type()
 #else // defined(ASIO_HAS_DEFAULT_FUNCTION_TEMPLATE_ARGUMENTS)
 #define ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(e)
 #define ASIO_DEFAULT_COMPLETION_TOKEN(e)
 #endif // defined(ASIO_HAS_DEFAULT_FUNCTION_TEMPLATE_ARGUMENTS)
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_ASYNC_RESULT_HPP
--- a/module/Vendor/ASIO/include/asio/awaitable.hpp
+++ b/module/Vendor/ASIO/include/asio/awaitable.hpp
@ -0,0 +1,133 @@
 //
 // awaitable.hpp
 // ~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_AWAITABLE_HPP
 #define ASIO_AWAITABLE_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if defined(ASIO_HAS_CO_AWAIT) || defined(GENERATING_DOCUMENTATION)
 #if defined(ASIO_HAS_STD_COROUTINE)
 # include <coroutine>
 #else // defined(ASIO_HAS_STD_COROUTINE)
 # include <experimental/coroutine>
 #endif // defined(ASIO_HAS_STD_COROUTINE)
 #include "asio/any_io_executor.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 #if defined(ASIO_HAS_STD_COROUTINE)
 using std::coroutine_handle;
 using std::suspend_always;
 #else // defined(ASIO_HAS_STD_COROUTINE)
 using std::experimental::coroutine_handle;
 using std::experimental::suspend_always;
 #endif // defined(ASIO_HAS_STD_COROUTINE)
 template <typename> class awaitable_thread;
 template <typename, typename> class awaitable_frame;
 } // namespace detail
 /// The return type of a coroutine or asynchronous operation.
 template <typename T, typename Executor = any_io_executor>
 class awaitable
 {
 public:
  /// The type of the awaited value.
  typedef T value_type;
  /// The executor type that will be used for the coroutine.
  typedef Executor executor_type;
  /// Default constructor.
  constexpr awaitable() noexcept
    : frame_(nullptr)
  {
  }
  /// Move constructor.
  awaitable(awaitable&& other) noexcept
    : frame_(std::exchange(other.frame_, nullptr))
  {
  }
  /// Destructor
  ~awaitable()
  {
    if (frame_)
      frame_->destroy();
  }
  /// Checks if the awaitable refers to a future result.
  bool valid() const noexcept
  {
    return !!frame_;
  }
 #if !defined(GENERATING_DOCUMENTATION)
  // Support for co_await keyword.
  bool await_ready() const noexcept
  {
    return false;
  }
  // Support for co_await keyword.
  template <class U>
  void await_suspend(
      detail::coroutine_handle<detail::awaitable_frame<U, Executor>> h)
  {
    frame_->push_frame(&h.promise());
  }
  // Support for co_await keyword.
  T await_resume()
  {
    return awaitable(static_cast<awaitable&&>(*this)).frame_->get();
  }
 #endif // !defined(GENERATING_DOCUMENTATION)
 private:
  template <typename> friend class detail::awaitable_thread;
  template <typename, typename> friend class detail::awaitable_frame;
  // Not copy constructible or copy assignable.
  awaitable(const awaitable&) = delete;
  awaitable& operator=(const awaitable&) = delete;
  // Construct the awaitable from a coroutine's frame object.
  explicit awaitable(detail::awaitable_frame<T, Executor>* a)
    : frame_(a)
  {
  }
  detail::awaitable_frame<T, Executor>* frame_;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #include "asio/impl/awaitable.hpp"
 #endif // defined(ASIO_HAS_CO_AWAIT) || defined(GENERATING_DOCUMENTATION)
 #endif // ASIO_AWAITABLE_HPP
--- a/module/Vendor/ASIO/include/asio/basic_datagram_socket.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_datagram_socket.hpp
--- a/module/Vendor/ASIO/include/asio/basic_deadline_timer.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_deadline_timer.hpp
@ -0,0 +1,693 @@
 //
 // basic_deadline_timer.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_DEADLINE_TIMER_HPP
 #define ASIO_BASIC_DEADLINE_TIMER_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if defined(ASIO_HAS_BOOST_DATE_TIME) \
  || defined(GENERATING_DOCUMENTATION)
 #include <cstddef>
 #include "asio/any_io_executor.hpp"
 #include "asio/detail/deadline_timer_service.hpp"
 #include "asio/detail/handler_type_requirements.hpp"
 #include "asio/detail/io_object_impl.hpp"
 #include "asio/detail/non_const_lvalue.hpp"
 #include "asio/detail/throw_error.hpp"
 #include "asio/error.hpp"
 #include "asio/execution_context.hpp"
 #include "asio/time_traits.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 /// Provides waitable timer functionality.
 /**
 * The basic_deadline_timer class template provides the ability to perform a
 * blocking or asynchronous wait for a timer to expire.
 *
 * A deadline timer is always in one of two states: "expired" or "not expired".
 * If the wait() or async_wait() function is called on an expired timer, the
 * wait operation will complete immediately.
 *
 * Most applications will use the asio::deadline_timer typedef.
 *
 * @par Thread Safety
 * @e Distinct @e objects: Safe.@n
 * @e Shared @e objects: Unsafe.
 *
 * @par Examples
 * Performing a blocking wait:
 * @code
 * // Construct a timer without setting an expiry time.
 * asio::deadline_timer timer(my_context);
 *
 * // Set an expiry time relative to now.
 * timer.expires_from_now(boost::posix_time::seconds(5));
 *
 * // Wait for the timer to expire.
 * timer.wait();
 * @endcode
 *
 * @par 
 * Performing an asynchronous wait:
 * @code
 * void handler(const asio::error_code& error)
 * {
 *   if (!error)
 *   {
 *     // Timer expired.
 *   }
 * }
 *
 * ...
 *
 * // Construct a timer with an absolute expiry time.
 * asio::deadline_timer timer(my_context,
 *     boost::posix_time::time_from_string("2005-12-07 23:59:59.000"));
 *
 * // Start an asynchronous wait.
 * timer.async_wait(handler);
 * @endcode
 *
 * @par Changing an active deadline_timer's expiry time
 *
 * Changing the expiry time of a timer while there are pending asynchronous
 * waits causes those wait operations to be cancelled. To ensure that the action
 * associated with the timer is performed only once, use something like this:
 * used:
 *
 * @code
 * void on_some_event()
 * {
 *   if (my_timer.expires_from_now(seconds(5)) > 0)
 *   {
 *     // We managed to cancel the timer. Start new asynchronous wait.
 *     my_timer.async_wait(on_timeout);
 *   }
 *   else
 *   {
 *     // Too late, timer has already expired!
 *   }
 * }
 *
 * void on_timeout(const asio::error_code& e)
 * {
 *   if (e != asio::error::operation_aborted)
 *   {
 *     // Timer was not cancelled, take necessary action.
 *   }
 * }
 * @endcode
 *
 * @li The asio::basic_deadline_timer::expires_from_now() function
 * cancels any pending asynchronous waits, and returns the number of
 * asynchronous waits that were cancelled. If it returns 0 then you were too
 * late and the wait handler has already been executed, or will soon be
 * executed. If it returns 1 then the wait handler was successfully cancelled.
 *
 * @li If a wait handler is cancelled, the asio::error_code passed to
 * it contains the value asio::error::operation_aborted.
 */
 template <typename Time,
    typename TimeTraits = asio::time_traits<Time>,
    typename Executor = any_io_executor>
 class basic_deadline_timer
 {
 public:
  /// The type of the executor associated with the object.
  typedef Executor executor_type;
  /// Rebinds the timer type to another executor.
  template <typename Executor1>
  struct rebind_executor
  {
    /// The timer type when rebound to the specified executor.
    typedef basic_deadline_timer<Time, TimeTraits, Executor1> other;
  };
  /// The time traits type.
  typedef TimeTraits traits_type;
  /// The time type.
  typedef typename traits_type::time_type time_type;
  /// The duration type.
  typedef typename traits_type::duration_type duration_type;
  /// Constructor.
  /**
   * This constructor creates a timer without setting an expiry time. The
   * expires_at() or expires_from_now() functions must be called to set an
   * expiry time before the timer can be waited on.
   *
   * @param ex The I/O executor that the timer will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the timer.
   */
  explicit basic_deadline_timer(const executor_type& ex)
    : impl_(0, ex)
  {
  }
  /// Constructor.
  /**
   * This constructor creates a timer without setting an expiry time. The
   * expires_at() or expires_from_now() functions must be called to set an
   * expiry time before the timer can be waited on.
   *
   * @param context An execution context which provides the I/O executor that
   * the timer will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the timer.
   */
  template <typename ExecutionContext>
  explicit basic_deadline_timer(ExecutionContext& context,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
  }
  /// Constructor to set a particular expiry time as an absolute time.
  /**
   * This constructor creates a timer and sets the expiry time.
   *
   * @param ex The I/O executor that the timer will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the timer.
   *
   * @param expiry_time The expiry time to be used for the timer, expressed
   * as an absolute time.
   */
  basic_deadline_timer(const executor_type& ex, const time_type& expiry_time)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().expires_at(impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_at");
  }
  /// Constructor to set a particular expiry time as an absolute time.
  /**
   * This constructor creates a timer and sets the expiry time.
   *
   * @param context An execution context which provides the I/O executor that
   * the timer will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the timer.
   *
   * @param expiry_time The expiry time to be used for the timer, expressed
   * as an absolute time.
   */
  template <typename ExecutionContext>
  basic_deadline_timer(ExecutionContext& context, const time_type& expiry_time,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().expires_at(impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_at");
  }
  /// Constructor to set a particular expiry time relative to now.
  /**
   * This constructor creates a timer and sets the expiry time.
   *
   * @param ex The I/O executor that the timer will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the timer.
   *
   * @param expiry_time The expiry time to be used for the timer, relative to
   * now.
   */
  basic_deadline_timer(const executor_type& ex,
      const duration_type& expiry_time)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().expires_from_now(
        impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_from_now");
  }
  /// Constructor to set a particular expiry time relative to now.
  /**
   * This constructor creates a timer and sets the expiry time.
   *
   * @param context An execution context which provides the I/O executor that
   * the timer will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the timer.
   *
   * @param expiry_time The expiry time to be used for the timer, relative to
   * now.
   */
  template <typename ExecutionContext>
  basic_deadline_timer(ExecutionContext& context,
      const duration_type& expiry_time,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().expires_from_now(
        impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_from_now");
  }
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Move-construct a basic_deadline_timer from another.
  /**
   * This constructor moves a timer from one object to another.
   *
   * @param other The other basic_deadline_timer object from which the move will
   * occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_deadline_timer(const executor_type&)
   * constructor.
   */
  basic_deadline_timer(basic_deadline_timer&& other)
    : impl_(std::move(other.impl_))
  {
  }
  /// Move-assign a basic_deadline_timer from another.
  /**
   * This assignment operator moves a timer from one object to another. Cancels
   * any outstanding asynchronous operations associated with the target object.
   *
   * @param other The other basic_deadline_timer object from which the move will
   * occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_deadline_timer(const executor_type&)
   * constructor.
   */
  basic_deadline_timer& operator=(basic_deadline_timer&& other)
  {
    impl_ = std::move(other.impl_);
    return *this;
  }
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Destroys the timer.
  /**
   * This function destroys the timer, cancelling any outstanding asynchronous
   * wait operations associated with the timer as if by calling @c cancel.
   */
  ~basic_deadline_timer()
  {
  }
  /// Get the executor associated with the object.
  executor_type get_executor() ASIO_NOEXCEPT
  {
    return impl_.get_executor();
  }
  /// Cancel any asynchronous operations that are waiting on the timer.
  /**
   * This function forces the completion of any pending asynchronous wait
   * operations against the timer. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * Cancelling the timer does not change the expiry time.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If the timer has already expired when cancel() is called, then the
   * handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t cancel()
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().cancel(impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "cancel");
    return s;
  }
  /// Cancel any asynchronous operations that are waiting on the timer.
  /**
   * This function forces the completion of any pending asynchronous wait
   * operations against the timer. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * Cancelling the timer does not change the expiry time.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @note If the timer has already expired when cancel() is called, then the
   * handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t cancel(asio::error_code& ec)
  {
    return impl_.get_service().cancel(impl_.get_implementation(), ec);
  }
  /// Cancels one asynchronous operation that is waiting on the timer.
  /**
   * This function forces the completion of one pending asynchronous wait
   * operation against the timer. Handlers are cancelled in FIFO order. The
   * handler for the cancelled operation will be invoked with the
   * asio::error::operation_aborted error code.
   *
   * Cancelling the timer does not change the expiry time.
   *
   * @return The number of asynchronous operations that were cancelled. That is,
   * either 0 or 1.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If the timer has already expired when cancel_one() is called, then
   * the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t cancel_one()
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().cancel_one(
        impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "cancel_one");
    return s;
  }
  /// Cancels one asynchronous operation that is waiting on the timer.
  /**
   * This function forces the completion of one pending asynchronous wait
   * operation against the timer. Handlers are cancelled in FIFO order. The
   * handler for the cancelled operation will be invoked with the
   * asio::error::operation_aborted error code.
   *
   * Cancelling the timer does not change the expiry time.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @return The number of asynchronous operations that were cancelled. That is,
   * either 0 or 1.
   *
   * @note If the timer has already expired when cancel_one() is called, then
   * the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t cancel_one(asio::error_code& ec)
  {
    return impl_.get_service().cancel_one(impl_.get_implementation(), ec);
  }
  /// Get the timer's expiry time as an absolute time.
  /**
   * This function may be used to obtain the timer's current expiry time.
   * Whether the timer has expired or not does not affect this value.
   */
  time_type expires_at() const
  {
    return impl_.get_service().expires_at(impl_.get_implementation());
  }
  /// Set the timer's expiry time as an absolute time.
  /**
   * This function sets the expiry time. Any pending asynchronous wait
   * operations will be cancelled. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * @param expiry_time The expiry time to be used for the timer.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If the timer has already expired when expires_at() is called, then
   * the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t expires_at(const time_type& expiry_time)
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().expires_at(
        impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_at");
    return s;
  }
  /// Set the timer's expiry time as an absolute time.
  /**
   * This function sets the expiry time. Any pending asynchronous wait
   * operations will be cancelled. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * @param expiry_time The expiry time to be used for the timer.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @note If the timer has already expired when expires_at() is called, then
   * the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t expires_at(const time_type& expiry_time,
      asio::error_code& ec)
  {
    return impl_.get_service().expires_at(
        impl_.get_implementation(), expiry_time, ec);
  }
  /// Get the timer's expiry time relative to now.
  /**
   * This function may be used to obtain the timer's current expiry time.
   * Whether the timer has expired or not does not affect this value.
   */
  duration_type expires_from_now() const
  {
    return impl_.get_service().expires_from_now(impl_.get_implementation());
  }
  /// Set the timer's expiry time relative to now.
  /**
   * This function sets the expiry time. Any pending asynchronous wait
   * operations will be cancelled. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * @param expiry_time The expiry time to be used for the timer.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If the timer has already expired when expires_from_now() is called,
   * then the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t expires_from_now(const duration_type& expiry_time)
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().expires_from_now(
        impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_from_now");
    return s;
  }
  /// Set the timer's expiry time relative to now.
  /**
   * This function sets the expiry time. Any pending asynchronous wait
   * operations will be cancelled. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * @param expiry_time The expiry time to be used for the timer.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @note If the timer has already expired when expires_from_now() is called,
   * then the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t expires_from_now(const duration_type& expiry_time,
      asio::error_code& ec)
  {
    return impl_.get_service().expires_from_now(
        impl_.get_implementation(), expiry_time, ec);
  }
  /// Perform a blocking wait on the timer.
  /**
   * This function is used to wait for the timer to expire. This function
   * blocks and does not return until the timer has expired.
   *
   * @throws asio::system_error Thrown on failure.
   */
  void wait()
  {
    asio::error_code ec;
    impl_.get_service().wait(impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "wait");
  }
  /// Perform a blocking wait on the timer.
  /**
   * This function is used to wait for the timer to expire. This function
   * blocks and does not return until the timer has expired.
   *
   * @param ec Set to indicate what error occurred, if any.
   */
  void wait(asio::error_code& ec)
  {
    impl_.get_service().wait(impl_.get_implementation(), ec);
  }
  /// Start an asynchronous wait on the timer.
  /**
   * This function may be used to initiate an asynchronous wait against the
   * timer. It always returns immediately.
   *
   * For each call to async_wait(), the supplied handler will be called exactly
   * once. The handler will be called when:
   *
   * @li The timer has expired.
   *
   * @li The timer was cancelled, in which case the handler is passed the error
   * code asio::error::operation_aborted.
   *
   * @param handler The handler to be called when the timer expires. Copies
   * will be made of the handler as required. The function signature of the
   * handler must be:
   * @code void handler(
   *   const asio::error_code& error // Result of operation.
   * ); @endcode
   * Regardless of whether the asynchronous operation completes immediately or
   * not, the handler will not be invoked from within this function. On
   * immediate completion, invocation of the handler will be performed in a
   * manner equivalent to using asio::post().
   */
  template <
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code))
        WaitHandler ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(WaitHandler,
      void (asio::error_code))
  async_wait(
      ASIO_MOVE_ARG(WaitHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return async_initiate<WaitHandler, void (asio::error_code)>(
        initiate_async_wait(this), handler);
  }
 private:
  // Disallow copying and assignment.
  basic_deadline_timer(const basic_deadline_timer&) ASIO_DELETED;
  basic_deadline_timer& operator=(
      const basic_deadline_timer&) ASIO_DELETED;
  class initiate_async_wait
  {
  public:
    typedef Executor executor_type;
    explicit initiate_async_wait(basic_deadline_timer* self)
      : self_(self)
    {
    }
    executor_type get_executor() const ASIO_NOEXCEPT
    {
      return self_->get_executor();
    }
    template <typename WaitHandler>
    void operator()(ASIO_MOVE_ARG(WaitHandler) handler) const
    {
      // If you get an error on the following line it means that your handler
      // does not meet the documented type requirements for a WaitHandler.
      ASIO_WAIT_HANDLER_CHECK(WaitHandler, handler) type_check;
      detail::non_const_lvalue<WaitHandler> handler2(handler);
      self_->impl_.get_service().async_wait(
          self_->impl_.get_implementation(),
          handler2.value, self_->impl_.get_executor());
    }
  private:
    basic_deadline_timer* self_;
  };
  detail::io_object_impl<
    detail::deadline_timer_service<TimeTraits>, Executor> impl_;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // defined(ASIO_HAS_BOOST_DATE_TIME)
       // || defined(GENERATING_DOCUMENTATION)
 #endif // ASIO_BASIC_DEADLINE_TIMER_HPP
--- a/module/Vendor/ASIO/include/asio/basic_io_object.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_io_object.hpp
@ -0,0 +1,290 @@
 //
 // basic_io_object.hpp
 // ~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_IO_OBJECT_HPP
 #define ASIO_BASIC_IO_OBJECT_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/io_context.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 #if defined(ASIO_HAS_MOVE)
 namespace detail
 {
  // Type trait used to determine whether a service supports move.
  template <typename IoObjectService>
  class service_has_move
  {
  private:
    typedef IoObjectService service_type;
    typedef typename service_type::implementation_type implementation_type;
    template <typename T, typename U>
    static auto asio_service_has_move_eval(T* t, U* u)
      -> decltype(t->move_construct(*u, *u), char());
    static char (&asio_service_has_move_eval(...))[2];
  public:
    static const bool value =
      sizeof(asio_service_has_move_eval(
        static_cast<service_type*>(0),
        static_cast<implementation_type*>(0))) == 1;
  };
 }
 #endif // defined(ASIO_HAS_MOVE)
 /// Base class for all I/O objects.
 /**
 * @note All I/O objects are non-copyable. However, when using C++0x, certain
 * I/O objects do support move construction and move assignment.
 */
 #if !defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
 template <typename IoObjectService>
 #else
 template <typename IoObjectService,
    bool Movable = detail::service_has_move<IoObjectService>::value>
 #endif
 class basic_io_object
 {
 public:
  /// The type of the service that will be used to provide I/O operations.
  typedef IoObjectService service_type;
  /// The underlying implementation type of I/O object.
  typedef typename service_type::implementation_type implementation_type;
 #if !defined(ASIO_NO_DEPRECATED)
  /// (Deprecated: Use get_executor().) Get the io_context associated with the
  /// object.
  /**
   * This function may be used to obtain the io_context object that the I/O
   * object uses to dispatch handlers for asynchronous operations.
   *
   * @return A reference to the io_context object that the I/O object will use
   * to dispatch handlers. Ownership is not transferred to the caller.
   */
  asio::io_context& get_io_context()
  {
    return service_.get_io_context();
  }
  /// (Deprecated: Use get_executor().) Get the io_context associated with the
  /// object.
  /**
   * This function may be used to obtain the io_context object that the I/O
   * object uses to dispatch handlers for asynchronous operations.
   *
   * @return A reference to the io_context object that the I/O object will use
   * to dispatch handlers. Ownership is not transferred to the caller.
   */
  asio::io_context& get_io_service()
  {
    return service_.get_io_context();
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
  /// The type of the executor associated with the object.
  typedef asio::io_context::executor_type executor_type;
  /// Get the executor associated with the object.
  executor_type get_executor() ASIO_NOEXCEPT
  {
    return service_.get_io_context().get_executor();
  }
 protected:
  /// Construct a basic_io_object.
  /**
   * Performs:
   * @code get_service().construct(get_implementation()); @endcode
   */
  explicit basic_io_object(asio::io_context& io_context)
    : service_(asio::use_service<IoObjectService>(io_context))
  {
    service_.construct(implementation_);
  }
 #if defined(GENERATING_DOCUMENTATION)
  /// Move-construct a basic_io_object.
  /**
   * Performs:
   * @code get_service().move_construct(
   *     get_implementation(), other.get_implementation()); @endcode
   *
   * @note Available only for services that support movability,
   */
  basic_io_object(basic_io_object&& other);
  /// Move-assign a basic_io_object.
  /**
   * Performs:
   * @code get_service().move_assign(get_implementation(),
   *     other.get_service(), other.get_implementation()); @endcode
   *
   * @note Available only for services that support movability,
   */
  basic_io_object& operator=(basic_io_object&& other);
  /// Perform a converting move-construction of a basic_io_object.
  template <typename IoObjectService1>
  basic_io_object(IoObjectService1& other_service,
      typename IoObjectService1::implementation_type& other_implementation);
 #endif // defined(GENERATING_DOCUMENTATION)
  /// Protected destructor to prevent deletion through this type.
  /**
   * Performs:
   * @code get_service().destroy(get_implementation()); @endcode
   */
  ~basic_io_object()
  {
    service_.destroy(implementation_);
  }
  /// Get the service associated with the I/O object.
  service_type& get_service()
  {
    return service_;
  }
  /// Get the service associated with the I/O object.
  const service_type& get_service() const
  {
    return service_;
  }
  /// Get the underlying implementation of the I/O object.
  implementation_type& get_implementation()
  {
    return implementation_;
  }
  /// Get the underlying implementation of the I/O object.
  const implementation_type& get_implementation() const
  {
    return implementation_;
  }
 private:
  basic_io_object(const basic_io_object&);
  basic_io_object& operator=(const basic_io_object&);
  // The service associated with the I/O object.
  service_type& service_;
  /// The underlying implementation of the I/O object.
  implementation_type implementation_;
 };
 #if defined(ASIO_HAS_MOVE)
 // Specialisation for movable objects.
 template <typename IoObjectService>
 class basic_io_object<IoObjectService, true>
 {
 public:
  typedef IoObjectService service_type;
  typedef typename service_type::implementation_type implementation_type;
 #if !defined(ASIO_NO_DEPRECATED)
  asio::io_context& get_io_context()
  {
    return service_->get_io_context();
  }
  asio::io_context& get_io_service()
  {
    return service_->get_io_context();
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
  typedef asio::io_context::executor_type executor_type;
  executor_type get_executor() ASIO_NOEXCEPT
  {
    return service_->get_io_context().get_executor();
  }
 protected:
  explicit basic_io_object(asio::io_context& io_context)
    : service_(&asio::use_service<IoObjectService>(io_context))
  {
    service_->construct(implementation_);
  }
  basic_io_object(basic_io_object&& other)
    : service_(&other.get_service())
  {
    service_->move_construct(implementation_, other.implementation_);
  }
  template <typename IoObjectService1>
  basic_io_object(IoObjectService1& other_service,
      typename IoObjectService1::implementation_type& other_implementation)
    : service_(&asio::use_service<IoObjectService>(
          other_service.get_io_context()))
  {
    service_->converting_move_construct(implementation_,
        other_service, other_implementation);
  }
  ~basic_io_object()
  {
    service_->destroy(implementation_);
  }
  basic_io_object& operator=(basic_io_object&& other)
  {
    service_->move_assign(implementation_,
        *other.service_, other.implementation_);
    service_ = other.service_;
    return *this;
  }
  service_type& get_service()
  {
    return *service_;
  }
  const service_type& get_service() const
  {
    return *service_;
  }
  implementation_type& get_implementation()
  {
    return implementation_;
  }
  const implementation_type& get_implementation() const
  {
    return implementation_;
  }
 private:
  basic_io_object(const basic_io_object&);
  void operator=(const basic_io_object&);
  IoObjectService* service_;
  implementation_type implementation_;
 };
 #endif // defined(ASIO_HAS_MOVE)
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_BASIC_IO_OBJECT_HPP
--- a/module/Vendor/ASIO/include/asio/basic_raw_socket.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_raw_socket.hpp
--- a/module/Vendor/ASIO/include/asio/basic_seq_packet_socket.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_seq_packet_socket.hpp
@ -0,0 +1,767 @@
 //
 // basic_seq_packet_socket.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_SEQ_PACKET_SOCKET_HPP
 #define ASIO_BASIC_SEQ_PACKET_SOCKET_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include <cstddef>
 #include "asio/basic_socket.hpp"
 #include "asio/detail/handler_type_requirements.hpp"
 #include "asio/detail/throw_error.hpp"
 #include "asio/error.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 #if !defined(ASIO_BASIC_SEQ_PACKET_SOCKET_FWD_DECL)
 #define ASIO_BASIC_SEQ_PACKET_SOCKET_FWD_DECL
 // Forward declaration with defaulted arguments.
 template <typename Protocol, typename Executor = any_io_executor>
 class basic_seq_packet_socket;
 #endif // !defined(ASIO_BASIC_SEQ_PACKET_SOCKET_FWD_DECL)
 /// Provides sequenced packet socket functionality.
 /**
 * The basic_seq_packet_socket class template provides asynchronous and blocking
 * sequenced packet socket functionality.
 *
 * @par Thread Safety
 * @e Distinct @e objects: Safe.@n
 * @e Shared @e objects: Unsafe.
 *
 * Synchronous @c send, @c receive, and @c connect operations are thread safe
 * with respect to each other, if the underlying operating system calls are
 * also thread safe. This means that it is permitted to perform concurrent
 * calls to these synchronous operations on a single socket object. Other
 * synchronous operations, such as @c open or @c close, are not thread safe.
 */
 template <typename Protocol, typename Executor>
 class basic_seq_packet_socket
  : public basic_socket<Protocol, Executor>
 {
 public:
  /// The type of the executor associated with the object.
  typedef Executor executor_type;
  /// Rebinds the socket type to another executor.
  template <typename Executor1>
  struct rebind_executor
  {
    /// The socket type when rebound to the specified executor.
    typedef basic_seq_packet_socket<Protocol, Executor1> other;
  };
  /// The native representation of a socket.
 #if defined(GENERATING_DOCUMENTATION)
  typedef implementation_defined native_handle_type;
 #else
  typedef typename basic_socket<Protocol,
    Executor>::native_handle_type native_handle_type;
 #endif
  /// The protocol type.
  typedef Protocol protocol_type;
  /// The endpoint type.
  typedef typename Protocol::endpoint endpoint_type;
  /// Construct a basic_seq_packet_socket without opening it.
  /**
   * This constructor creates a sequenced packet socket without opening it. The
   * socket needs to be opened and then connected or accepted before data can
   * be sent or received on it.
   *
   * @param ex The I/O executor that the socket will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the socket.
   */
  explicit basic_seq_packet_socket(const executor_type& ex)
    : basic_socket<Protocol, Executor>(ex)
  {
  }
  /// Construct a basic_seq_packet_socket without opening it.
  /**
   * This constructor creates a sequenced packet socket without opening it. The
   * socket needs to be opened and then connected or accepted before data can
   * be sent or received on it.
   *
   * @param context An execution context which provides the I/O executor that
   * the socket will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the socket.
   */
  template <typename ExecutionContext>
  explicit basic_seq_packet_socket(ExecutionContext& context,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : basic_socket<Protocol, Executor>(context)
  {
  }
  /// Construct and open a basic_seq_packet_socket.
  /**
   * This constructor creates and opens a sequenced_packet socket. The socket
   * needs to be connected or accepted before data can be sent or received on
   * it.
   *
   * @param ex The I/O executor that the socket will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the socket.
   *
   * @param protocol An object specifying protocol parameters to be used.
   *
   * @throws asio::system_error Thrown on failure.
   */
  basic_seq_packet_socket(const executor_type& ex,
      const protocol_type& protocol)
    : basic_socket<Protocol, Executor>(ex, protocol)
  {
  }
  /// Construct and open a basic_seq_packet_socket.
  /**
   * This constructor creates and opens a sequenced_packet socket. The socket
   * needs to be connected or accepted before data can be sent or received on
   * it.
   *
   * @param context An execution context which provides the I/O executor that
   * the socket will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the socket.
   *
   * @param protocol An object specifying protocol parameters to be used.
   *
   * @throws asio::system_error Thrown on failure.
   */
  template <typename ExecutionContext>
  basic_seq_packet_socket(ExecutionContext& context,
      const protocol_type& protocol,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : basic_socket<Protocol, Executor>(context, protocol)
  {
  }
  /// Construct a basic_seq_packet_socket, opening it and binding it to the
  /// given local endpoint.
  /**
   * This constructor creates a sequenced packet socket and automatically opens
   * it bound to the specified endpoint on the local machine. The protocol used
   * is the protocol associated with the given endpoint.
   *
   * @param ex The I/O executor that the socket will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the socket.
   *
   * @param endpoint An endpoint on the local machine to which the sequenced
   * packet socket will be bound.
   *
   * @throws asio::system_error Thrown on failure.
   */
  basic_seq_packet_socket(const executor_type& ex,
      const endpoint_type& endpoint)
    : basic_socket<Protocol, Executor>(ex, endpoint)
  {
  }
  /// Construct a basic_seq_packet_socket, opening it and binding it to the
  /// given local endpoint.
  /**
   * This constructor creates a sequenced packet socket and automatically opens
   * it bound to the specified endpoint on the local machine. The protocol used
   * is the protocol associated with the given endpoint.
   *
   * @param context An execution context which provides the I/O executor that
   * the socket will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the socket.
   *
   * @param endpoint An endpoint on the local machine to which the sequenced
   * packet socket will be bound.
   *
   * @throws asio::system_error Thrown on failure.
   */
  template <typename ExecutionContext>
  basic_seq_packet_socket(ExecutionContext& context,
      const endpoint_type& endpoint,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : basic_socket<Protocol, Executor>(context, endpoint)
  {
  }
  /// Construct a basic_seq_packet_socket on an existing native socket.
  /**
   * This constructor creates a sequenced packet socket object to hold an
   * existing native socket.
   *
   * @param ex The I/O executor that the socket will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the socket.
   *
   * @param protocol An object specifying protocol parameters to be used.
   *
   * @param native_socket The new underlying socket implementation.
   *
   * @throws asio::system_error Thrown on failure.
   */
  basic_seq_packet_socket(const executor_type& ex,
      const protocol_type& protocol, const native_handle_type& native_socket)
    : basic_socket<Protocol, Executor>(ex, protocol, native_socket)
  {
  }
  /// Construct a basic_seq_packet_socket on an existing native socket.
  /**
   * This constructor creates a sequenced packet socket object to hold an
   * existing native socket.
   *
   * @param context An execution context which provides the I/O executor that
   * the socket will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the socket.
   *
   * @param protocol An object specifying protocol parameters to be used.
   *
   * @param native_socket The new underlying socket implementation.
   *
   * @throws asio::system_error Thrown on failure.
   */
  template <typename ExecutionContext>
  basic_seq_packet_socket(ExecutionContext& context,
      const protocol_type& protocol, const native_handle_type& native_socket,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : basic_socket<Protocol, Executor>(context, protocol, native_socket)
  {
  }
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Move-construct a basic_seq_packet_socket from another.
  /**
   * This constructor moves a sequenced packet socket from one object to
   * another.
   *
   * @param other The other basic_seq_packet_socket object from which the move
   * will occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_seq_packet_socket(const executor_type&)
   * constructor.
   */
  basic_seq_packet_socket(basic_seq_packet_socket&& other) ASIO_NOEXCEPT
    : basic_socket<Protocol, Executor>(std::move(other))
  {
  }
  /// Move-assign a basic_seq_packet_socket from another.
  /**
   * This assignment operator moves a sequenced packet socket from one object to
   * another.
   *
   * @param other The other basic_seq_packet_socket object from which the move
   * will occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_seq_packet_socket(const executor_type&)
   * constructor.
   */
  basic_seq_packet_socket& operator=(basic_seq_packet_socket&& other)
  {
    basic_socket<Protocol, Executor>::operator=(std::move(other));
    return *this;
  }
  /// Move-construct a basic_seq_packet_socket from a socket of another protocol
  /// type.
  /**
   * This constructor moves a sequenced packet socket from one object to
   * another.
   *
   * @param other The other basic_seq_packet_socket object from which the move
   * will occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_seq_packet_socket(const executor_type&)
   * constructor.
   */
  template <typename Protocol1, typename Executor1>
  basic_seq_packet_socket(basic_seq_packet_socket<Protocol1, Executor1>&& other,
      typename enable_if<
        is_convertible<Protocol1, Protocol>::value
          && is_convertible<Executor1, Executor>::value
      >::type* = 0)
    : basic_socket<Protocol, Executor>(std::move(other))
  {
  }
  /// Move-assign a basic_seq_packet_socket from a socket of another protocol
  /// type.
  /**
   * This assignment operator moves a sequenced packet socket from one object to
   * another.
   *
   * @param other The other basic_seq_packet_socket object from which the move
   * will occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_seq_packet_socket(const executor_type&)
   * constructor.
   */
  template <typename Protocol1, typename Executor1>
  typename enable_if<
    is_convertible<Protocol1, Protocol>::value
      && is_convertible<Executor1, Executor>::value,
    basic_seq_packet_socket&
  >::type operator=(basic_seq_packet_socket<Protocol1, Executor1>&& other)
  {
    basic_socket<Protocol, Executor>::operator=(std::move(other));
    return *this;
  }
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Destroys the socket.
  /**
   * This function destroys the socket, cancelling any outstanding asynchronous
   * operations associated with the socket as if by calling @c cancel.
   */
  ~basic_seq_packet_socket()
  {
  }
  /// Send some data on the socket.
  /**
   * This function is used to send data on the sequenced packet socket. The
   * function call will block until the data has been sent successfully, or an
   * until error occurs.
   *
   * @param buffers One or more data buffers to be sent on the socket.
   *
   * @param flags Flags specifying how the send call is to be made.
   *
   * @returns The number of bytes sent.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @par Example
   * To send a single data buffer use the @ref buffer function as follows:
   * @code
   * socket.send(asio::buffer(data, size), 0);
   * @endcode
   * See the @ref buffer documentation for information on sending multiple
   * buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename ConstBufferSequence>
  std::size_t send(const ConstBufferSequence& buffers,
      socket_base::message_flags flags)
  {
    asio::error_code ec;
    std::size_t s = this->impl_.get_service().send(
        this->impl_.get_implementation(), buffers, flags, ec);
    asio::detail::throw_error(ec, "send");
    return s;
  }
  /// Send some data on the socket.
  /**
   * This function is used to send data on the sequenced packet socket. The
   * function call will block the data has been sent successfully, or an until
   * error occurs.
   *
   * @param buffers One or more data buffers to be sent on the socket.
   *
   * @param flags Flags specifying how the send call is to be made.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @returns The number of bytes sent. Returns 0 if an error occurred.
   *
   * @note The send operation may not transmit all of the data to the peer.
   * Consider using the @ref write function if you need to ensure that all data
   * is written before the blocking operation completes.
   */
  template <typename ConstBufferSequence>
  std::size_t send(const ConstBufferSequence& buffers,
      socket_base::message_flags flags, asio::error_code& ec)
  {
    return this->impl_.get_service().send(
        this->impl_.get_implementation(), buffers, flags, ec);
  }
  /// Start an asynchronous send.
  /**
   * This function is used to asynchronously send data on the sequenced packet
   * socket. The function call always returns immediately.
   *
   * @param buffers One or more data buffers to be sent on the socket. Although
   * the buffers object may be copied as necessary, ownership of the underlying
   * memory blocks is retained by the caller, which must guarantee that they
   * remain valid until the handler is called.
   *
   * @param flags Flags specifying how the send call is to be made.
   *
   * @param handler The handler to be called when the send operation completes.
   * Copies will be made of the handler as required. The function signature of
   * the handler must be:
   * @code void handler(
   *   const asio::error_code& error, // Result of operation.
   *   std::size_t bytes_transferred           // Number of bytes sent.
   * ); @endcode
   * Regardless of whether the asynchronous operation completes immediately or
   * not, the handler will not be invoked from within this function. On
   * immediate completion, invocation of the handler will be performed in a
   * manner equivalent to using asio::post().
   *
   * @par Example
   * To send a single data buffer use the @ref buffer function as follows:
   * @code
   * socket.async_send(asio::buffer(data, size), 0, handler);
   * @endcode
   * See the @ref buffer documentation for information on sending multiple
   * buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename ConstBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) WriteHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(WriteHandler,
      void (asio::error_code, std::size_t))
  async_send(const ConstBufferSequence& buffers,
      socket_base::message_flags flags,
      ASIO_MOVE_ARG(WriteHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return async_initiate<WriteHandler,
      void (asio::error_code, std::size_t)>(
        initiate_async_send(this), handler, buffers, flags);
  }
  /// Receive some data on the socket.
  /**
   * This function is used to receive data on the sequenced packet socket. The
   * function call will block until data has been received successfully, or
   * until an error occurs.
   *
   * @param buffers One or more buffers into which the data will be received.
   *
   * @param out_flags After the receive call completes, contains flags
   * associated with the received data. For example, if the
   * socket_base::message_end_of_record bit is set then the received data marks
   * the end of a record.
   *
   * @returns The number of bytes received.
   *
   * @throws asio::system_error Thrown on failure. An error code of
   * asio::error::eof indicates that the connection was closed by the
   * peer.
   *
   * @par Example
   * To receive into a single data buffer use the @ref buffer function as
   * follows:
   * @code
   * socket.receive(asio::buffer(data, size), out_flags);
   * @endcode
   * See the @ref buffer documentation for information on receiving into
   * multiple buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename MutableBufferSequence>
  std::size_t receive(const MutableBufferSequence& buffers,
      socket_base::message_flags& out_flags)
  {
    asio::error_code ec;
    std::size_t s = this->impl_.get_service().receive_with_flags(
        this->impl_.get_implementation(), buffers, 0, out_flags, ec);
    asio::detail::throw_error(ec, "receive");
    return s;
  }
  /// Receive some data on the socket.
  /**
   * This function is used to receive data on the sequenced packet socket. The
   * function call will block until data has been received successfully, or
   * until an error occurs.
   *
   * @param buffers One or more buffers into which the data will be received.
   *
   * @param in_flags Flags specifying how the receive call is to be made.
   *
   * @param out_flags After the receive call completes, contains flags
   * associated with the received data. For example, if the
   * socket_base::message_end_of_record bit is set then the received data marks
   * the end of a record.
   *
   * @returns The number of bytes received.
   *
   * @throws asio::system_error Thrown on failure. An error code of
   * asio::error::eof indicates that the connection was closed by the
   * peer.
   *
   * @note The receive operation may not receive all of the requested number of
   * bytes. Consider using the @ref read function if you need to ensure that the
   * requested amount of data is read before the blocking operation completes.
   *
   * @par Example
   * To receive into a single data buffer use the @ref buffer function as
   * follows:
   * @code
   * socket.receive(asio::buffer(data, size), 0, out_flags);
   * @endcode
   * See the @ref buffer documentation for information on receiving into
   * multiple buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename MutableBufferSequence>
  std::size_t receive(const MutableBufferSequence& buffers,
      socket_base::message_flags in_flags,
      socket_base::message_flags& out_flags)
  {
    asio::error_code ec;
    std::size_t s = this->impl_.get_service().receive_with_flags(
        this->impl_.get_implementation(), buffers, in_flags, out_flags, ec);
    asio::detail::throw_error(ec, "receive");
    return s;
  }
  /// Receive some data on a connected socket.
  /**
   * This function is used to receive data on the sequenced packet socket. The
   * function call will block until data has been received successfully, or
   * until an error occurs.
   *
   * @param buffers One or more buffers into which the data will be received.
   *
   * @param in_flags Flags specifying how the receive call is to be made.
   *
   * @param out_flags After the receive call completes, contains flags
   * associated with the received data. For example, if the
   * socket_base::message_end_of_record bit is set then the received data marks
   * the end of a record.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @returns The number of bytes received. Returns 0 if an error occurred.
   *
   * @note The receive operation may not receive all of the requested number of
   * bytes. Consider using the @ref read function if you need to ensure that the
   * requested amount of data is read before the blocking operation completes.
   */
  template <typename MutableBufferSequence>
  std::size_t receive(const MutableBufferSequence& buffers,
      socket_base::message_flags in_flags,
      socket_base::message_flags& out_flags, asio::error_code& ec)
  {
    return this->impl_.get_service().receive_with_flags(
        this->impl_.get_implementation(), buffers, in_flags, out_flags, ec);
  }
  /// Start an asynchronous receive.
  /**
   * This function is used to asynchronously receive data from the sequenced
   * packet socket. The function call always returns immediately.
   *
   * @param buffers One or more buffers into which the data will be received.
   * Although the buffers object may be copied as necessary, ownership of the
   * underlying memory blocks is retained by the caller, which must guarantee
   * that they remain valid until the handler is called.
   *
   * @param out_flags Once the asynchronous operation completes, contains flags
   * associated with the received data. For example, if the
   * socket_base::message_end_of_record bit is set then the received data marks
   * the end of a record. The caller must guarantee that the referenced
   * variable remains valid until the handler is called.
   *
   * @param handler The handler to be called when the receive operation
   * completes. Copies will be made of the handler as required. The function
   * signature of the handler must be:
   * @code void handler(
   *   const asio::error_code& error, // Result of operation.
   *   std::size_t bytes_transferred           // Number of bytes received.
   * ); @endcode
   * Regardless of whether the asynchronous operation completes immediately or
   * not, the handler will not be invoked from within this function. On
   * immediate completion, invocation of the handler will be performed in a
   * manner equivalent to using asio::post().
   *
   * @par Example
   * To receive into a single data buffer use the @ref buffer function as
   * follows:
   * @code
   * socket.async_receive(asio::buffer(data, size), out_flags, handler);
   * @endcode
   * See the @ref buffer documentation for information on receiving into
   * multiple buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename MutableBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) ReadHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(ReadHandler,
      void (asio::error_code, std::size_t))
  async_receive(const MutableBufferSequence& buffers,
      socket_base::message_flags& out_flags,
      ASIO_MOVE_ARG(ReadHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return async_initiate<ReadHandler,
      void (asio::error_code, std::size_t)>(
        initiate_async_receive_with_flags(this), handler,
        buffers, socket_base::message_flags(0), &out_flags);
  }
  /// Start an asynchronous receive.
  /**
   * This function is used to asynchronously receive data from the sequenced
   * data socket. The function call always returns immediately.
   *
   * @param buffers One or more buffers into which the data will be received.
   * Although the buffers object may be copied as necessary, ownership of the
   * underlying memory blocks is retained by the caller, which must guarantee
   * that they remain valid until the handler is called.
   *
   * @param in_flags Flags specifying how the receive call is to be made.
   *
   * @param out_flags Once the asynchronous operation completes, contains flags
   * associated with the received data. For example, if the
   * socket_base::message_end_of_record bit is set then the received data marks
   * the end of a record. The caller must guarantee that the referenced
   * variable remains valid until the handler is called.
   *
   * @param handler The handler to be called when the receive operation
   * completes. Copies will be made of the handler as required. The function
   * signature of the handler must be:
   * @code void handler(
   *   const asio::error_code& error, // Result of operation.
   *   std::size_t bytes_transferred           // Number of bytes received.
   * ); @endcode
   * Regardless of whether the asynchronous operation completes immediately or
   * not, the handler will not be invoked from within this function. On
   * immediate completion, invocation of the handler will be performed in a
   * manner equivalent to using asio::post().
   *
   * @par Example
   * To receive into a single data buffer use the @ref buffer function as
   * follows:
   * @code
   * socket.async_receive(
   *     asio::buffer(data, size),
   *     0, out_flags, handler);
   * @endcode
   * See the @ref buffer documentation for information on receiving into
   * multiple buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename MutableBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) ReadHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(ReadHandler,
      void (asio::error_code, std::size_t))
  async_receive(const MutableBufferSequence& buffers,
      socket_base::message_flags in_flags,
      socket_base::message_flags& out_flags,
      ASIO_MOVE_ARG(ReadHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return async_initiate<ReadHandler,
      void (asio::error_code, std::size_t)>(
        initiate_async_receive_with_flags(this),
        handler, buffers, in_flags, &out_flags);
  }
 private:
  // Disallow copying and assignment.
  basic_seq_packet_socket(const basic_seq_packet_socket&) ASIO_DELETED;
  basic_seq_packet_socket& operator=(
      const basic_seq_packet_socket&) ASIO_DELETED;
  class initiate_async_send
  {
  public:
    typedef Executor executor_type;
    explicit initiate_async_send(basic_seq_packet_socket* self)
      : self_(self)
    {
    }
    executor_type get_executor() const ASIO_NOEXCEPT
    {
      return self_->get_executor();
    }
    template <typename WriteHandler, typename ConstBufferSequence>
    void operator()(ASIO_MOVE_ARG(WriteHandler) handler,
        const ConstBufferSequence& buffers,
        socket_base::message_flags flags) const
    {
      // If you get an error on the following line it means that your handler
      // does not meet the documented type requirements for a WriteHandler.
      ASIO_WRITE_HANDLER_CHECK(WriteHandler, handler) type_check;
      detail::non_const_lvalue<WriteHandler> handler2(handler);
      self_->impl_.get_service().async_send(
          self_->impl_.get_implementation(), buffers, flags,
          handler2.value, self_->impl_.get_executor());
    }
  private:
    basic_seq_packet_socket* self_;
  };
  class initiate_async_receive_with_flags
  {
  public:
    typedef Executor executor_type;
    explicit initiate_async_receive_with_flags(basic_seq_packet_socket* self)
      : self_(self)
    {
    }
    executor_type get_executor() const ASIO_NOEXCEPT
    {
      return self_->get_executor();
    }
    template <typename ReadHandler, typename MutableBufferSequence>
    void operator()(ASIO_MOVE_ARG(ReadHandler) handler,
        const MutableBufferSequence& buffers,
        socket_base::message_flags in_flags,
        socket_base::message_flags* out_flags) const
    {
      // If you get an error on the following line it means that your handler
      // does not meet the documented type requirements for a ReadHandler.
      ASIO_READ_HANDLER_CHECK(ReadHandler, handler) type_check;
      detail::non_const_lvalue<ReadHandler> handler2(handler);
      self_->impl_.get_service().async_receive_with_flags(
          self_->impl_.get_implementation(), buffers, in_flags,
          *out_flags, handler2.value, self_->impl_.get_executor());
    }
  private:
    basic_seq_packet_socket* self_;
  };
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_BASIC_SEQ_PACKET_SOCKET_HPP
--- a/module/Vendor/ASIO/include/asio/basic_serial_port.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_serial_port.hpp
@ -0,0 +1,907 @@
 //
 // basic_serial_port.hpp
 // ~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 // Copyright (c) 2008 Rep Invariant Systems, Inc. (info@repinvariant.com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_SERIAL_PORT_HPP
 #define ASIO_BASIC_SERIAL_PORT_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if defined(ASIO_HAS_SERIAL_PORT) \
  || defined(GENERATING_DOCUMENTATION)
 #include <string>
 #include "asio/any_io_executor.hpp"
 #include "asio/async_result.hpp"
 #include "asio/detail/handler_type_requirements.hpp"
 #include "asio/detail/io_object_impl.hpp"
 #include "asio/detail/non_const_lvalue.hpp"
 #include "asio/detail/throw_error.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/error.hpp"
 #include "asio/execution_context.hpp"
 #include "asio/serial_port_base.hpp"
 #if defined(ASIO_HAS_IOCP)
 # include "asio/detail/win_iocp_serial_port_service.hpp"
 #else
 # include "asio/detail/reactive_serial_port_service.hpp"
 #endif
 #if defined(ASIO_HAS_MOVE)
 # include <utility>
 #endif // defined(ASIO_HAS_MOVE)
 #include "asio/detail/push_options.hpp"
 namespace asio {
 /// Provides serial port functionality.
 /**
 * The basic_serial_port class provides a wrapper over serial port
 * functionality.
 *
 * @par Thread Safety
 * @e Distinct @e objects: Safe.@n
 * @e Shared @e objects: Unsafe.
 */
 template <typename Executor = any_io_executor>
 class basic_serial_port
  : public serial_port_base
 {
 public:
  /// The type of the executor associated with the object.
  typedef Executor executor_type;
  /// Rebinds the serial port type to another executor.
  template <typename Executor1>
  struct rebind_executor
  {
    /// The serial port type when rebound to the specified executor.
    typedef basic_serial_port<Executor1> other;
  };
  /// The native representation of a serial port.
 #if defined(GENERATING_DOCUMENTATION)
  typedef implementation_defined native_handle_type;
 #elif defined(ASIO_HAS_IOCP)
  typedef detail::win_iocp_serial_port_service::native_handle_type
    native_handle_type;
 #else
  typedef detail::reactive_serial_port_service::native_handle_type
    native_handle_type;
 #endif
  /// A basic_basic_serial_port is always the lowest layer.
  typedef basic_serial_port lowest_layer_type;
  /// Construct a basic_serial_port without opening it.
  /**
   * This constructor creates a serial port without opening it.
   *
   * @param ex The I/O executor that the serial port will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the
   * serial port.
   */
  explicit basic_serial_port(const executor_type& ex)
    : impl_(0, ex)
  {
  }
  /// Construct a basic_serial_port without opening it.
  /**
   * This constructor creates a serial port without opening it.
   *
   * @param context An execution context which provides the I/O executor that
   * the serial port will use, by default, to dispatch handlers for any
   * asynchronous operations performed on the serial port.
   */
  template <typename ExecutionContext>
  explicit basic_serial_port(ExecutionContext& context,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value,
        basic_serial_port
      >::type* = 0)
    : impl_(0, 0, context)
  {
  }
  /// Construct and open a basic_serial_port.
  /**
   * This constructor creates and opens a serial port for the specified device
   * name.
   *
   * @param ex The I/O executor that the serial port will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the
   * serial port.
   *
   * @param device The platform-specific device name for this serial
   * port.
   */
  basic_serial_port(const executor_type& ex, const char* device)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().open(impl_.get_implementation(), device, ec);
    asio::detail::throw_error(ec, "open");
  }
  /// Construct and open a basic_serial_port.
  /**
   * This constructor creates and opens a serial port for the specified device
   * name.
   *
   * @param context An execution context which provides the I/O executor that
   * the serial port will use, by default, to dispatch handlers for any
   * asynchronous operations performed on the serial port.
   *
   * @param device The platform-specific device name for this serial
   * port.
   */
  template <typename ExecutionContext>
  basic_serial_port(ExecutionContext& context, const char* device,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().open(impl_.get_implementation(), device, ec);
    asio::detail::throw_error(ec, "open");
  }
  /// Construct and open a basic_serial_port.
  /**
   * This constructor creates and opens a serial port for the specified device
   * name.
   *
   * @param ex The I/O executor that the serial port will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the
   * serial port.
   *
   * @param device The platform-specific device name for this serial
   * port.
   */
  basic_serial_port(const executor_type& ex, const std::string& device)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().open(impl_.get_implementation(), device, ec);
    asio::detail::throw_error(ec, "open");
  }
  /// Construct and open a basic_serial_port.
  /**
   * This constructor creates and opens a serial port for the specified device
   * name.
   *
   * @param context An execution context which provides the I/O executor that
   * the serial port will use, by default, to dispatch handlers for any
   * asynchronous operations performed on the serial port.
   *
   * @param device The platform-specific device name for this serial
   * port.
   */
  template <typename ExecutionContext>
  basic_serial_port(ExecutionContext& context, const std::string& device,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().open(impl_.get_implementation(), device, ec);
    asio::detail::throw_error(ec, "open");
  }
  /// Construct a basic_serial_port on an existing native serial port.
  /**
   * This constructor creates a serial port object to hold an existing native
   * serial port.
   *
   * @param ex The I/O executor that the serial port will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the
   * serial port.
   *
   * @param native_serial_port A native serial port.
   *
   * @throws asio::system_error Thrown on failure.
   */
  basic_serial_port(const executor_type& ex,
      const native_handle_type& native_serial_port)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().assign(impl_.get_implementation(),
        native_serial_port, ec);
    asio::detail::throw_error(ec, "assign");
  }
  /// Construct a basic_serial_port on an existing native serial port.
  /**
   * This constructor creates a serial port object to hold an existing native
   * serial port.
   *
   * @param context An execution context which provides the I/O executor that
   * the serial port will use, by default, to dispatch handlers for any
   * asynchronous operations performed on the serial port.
   *
   * @param native_serial_port A native serial port.
   *
   * @throws asio::system_error Thrown on failure.
   */
  template <typename ExecutionContext>
  basic_serial_port(ExecutionContext& context,
      const native_handle_type& native_serial_port,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().assign(impl_.get_implementation(),
        native_serial_port, ec);
    asio::detail::throw_error(ec, "assign");
  }
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Move-construct a basic_serial_port from another.
  /**
   * This constructor moves a serial port from one object to another.
   *
   * @param other The other basic_serial_port object from which the move will
   * occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_serial_port(const executor_type&)
   * constructor.
   */
  basic_serial_port(basic_serial_port&& other)
    : impl_(std::move(other.impl_))
  {
  }
  /// Move-assign a basic_serial_port from another.
  /**
   * This assignment operator moves a serial port from one object to another.
   *
   * @param other The other basic_serial_port object from which the move will
   * occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_serial_port(const executor_type&)
   * constructor.
   */
  basic_serial_port& operator=(basic_serial_port&& other)
  {
    impl_ = std::move(other.impl_);
    return *this;
  }
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Destroys the serial port.
  /**
   * This function destroys the serial port, cancelling any outstanding
   * asynchronous wait operations associated with the serial port as if by
   * calling @c cancel.
   */
  ~basic_serial_port()
  {
  }
  /// Get the executor associated with the object.
  executor_type get_executor() ASIO_NOEXCEPT
  {
    return impl_.get_executor();
  }
  /// Get a reference to the lowest layer.
  /**
   * This function returns a reference to the lowest layer in a stack of
   * layers. Since a basic_serial_port cannot contain any further layers, it
   * simply returns a reference to itself.
   *
   * @return A reference to the lowest layer in the stack of layers. Ownership
   * is not transferred to the caller.
   */
  lowest_layer_type& lowest_layer()
  {
    return *this;
  }
  /// Get a const reference to the lowest layer.
  /**
   * This function returns a const reference to the lowest layer in a stack of
   * layers. Since a basic_serial_port cannot contain any further layers, it
   * simply returns a reference to itself.
   *
   * @return A const reference to the lowest layer in the stack of layers.
   * Ownership is not transferred to the caller.
   */
  const lowest_layer_type& lowest_layer() const
  {
    return *this;
  }
  /// Open the serial port using the specified device name.
  /**
   * This function opens the serial port for the specified device name.
   *
   * @param device The platform-specific device name.
   *
   * @throws asio::system_error Thrown on failure.
   */
  void open(const std::string& device)
  {
    asio::error_code ec;
    impl_.get_service().open(impl_.get_implementation(), device, ec);
    asio::detail::throw_error(ec, "open");
  }
  /// Open the serial port using the specified device name.
  /**
   * This function opens the serial port using the given platform-specific
   * device name.
   *
   * @param device The platform-specific device name.
   *
   * @param ec Set the indicate what error occurred, if any.
   */
  ASIO_SYNC_OP_VOID open(const std::string& device,
      asio::error_code& ec)
  {
    impl_.get_service().open(impl_.get_implementation(), device, ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Assign an existing native serial port to the serial port.
  /*
   * This function opens the serial port to hold an existing native serial port.
   *
   * @param native_serial_port A native serial port.
   *
   * @throws asio::system_error Thrown on failure.
   */
  void assign(const native_handle_type& native_serial_port)
  {
    asio::error_code ec;
    impl_.get_service().assign(impl_.get_implementation(),
        native_serial_port, ec);
    asio::detail::throw_error(ec, "assign");
  }
  /// Assign an existing native serial port to the serial port.
  /*
   * This function opens the serial port to hold an existing native serial port.
   *
   * @param native_serial_port A native serial port.
   *
   * @param ec Set to indicate what error occurred, if any.
   */
  ASIO_SYNC_OP_VOID assign(const native_handle_type& native_serial_port,
      asio::error_code& ec)
  {
    impl_.get_service().assign(impl_.get_implementation(),
        native_serial_port, ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Determine whether the serial port is open.
  bool is_open() const
  {
    return impl_.get_service().is_open(impl_.get_implementation());
  }
  /// Close the serial port.
  /**
   * This function is used to close the serial port. Any asynchronous read or
   * write operations will be cancelled immediately, and will complete with the
   * asio::error::operation_aborted error.
   *
   * @throws asio::system_error Thrown on failure.
   */
  void close()
  {
    asio::error_code ec;
    impl_.get_service().close(impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "close");
  }
  /// Close the serial port.
  /**
   * This function is used to close the serial port. Any asynchronous read or
   * write operations will be cancelled immediately, and will complete with the
   * asio::error::operation_aborted error.
   *
   * @param ec Set to indicate what error occurred, if any.
   */
  ASIO_SYNC_OP_VOID close(asio::error_code& ec)
  {
    impl_.get_service().close(impl_.get_implementation(), ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Get the native serial port representation.
  /**
   * This function may be used to obtain the underlying representation of the
   * serial port. This is intended to allow access to native serial port
   * functionality that is not otherwise provided.
   */
  native_handle_type native_handle()
  {
    return impl_.get_service().native_handle(impl_.get_implementation());
  }
  /// Cancel all asynchronous operations associated with the serial port.
  /**
   * This function causes all outstanding asynchronous read or write operations
   * to finish immediately, and the handlers for cancelled operations will be
   * passed the asio::error::operation_aborted error.
   *
   * @throws asio::system_error Thrown on failure.
   */
  void cancel()
  {
    asio::error_code ec;
    impl_.get_service().cancel(impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "cancel");
  }
  /// Cancel all asynchronous operations associated with the serial port.
  /**
   * This function causes all outstanding asynchronous read or write operations
   * to finish immediately, and the handlers for cancelled operations will be
   * passed the asio::error::operation_aborted error.
   *
   * @param ec Set to indicate what error occurred, if any.
   */
  ASIO_SYNC_OP_VOID cancel(asio::error_code& ec)
  {
    impl_.get_service().cancel(impl_.get_implementation(), ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Send a break sequence to the serial port.
  /**
   * This function causes a break sequence of platform-specific duration to be
   * sent out the serial port.
   *
   * @throws asio::system_error Thrown on failure.
   */
  void send_break()
  {
    asio::error_code ec;
    impl_.get_service().send_break(impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "send_break");
  }
  /// Send a break sequence to the serial port.
  /**
   * This function causes a break sequence of platform-specific duration to be
   * sent out the serial port.
   *
   * @param ec Set to indicate what error occurred, if any.
   */
  ASIO_SYNC_OP_VOID send_break(asio::error_code& ec)
  {
    impl_.get_service().send_break(impl_.get_implementation(), ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Set an option on the serial port.
  /**
   * This function is used to set an option on the serial port.
   *
   * @param option The option value to be set on the serial port.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @sa SettableSerialPortOption @n
   * asio::serial_port_base::baud_rate @n
   * asio::serial_port_base::flow_control @n
   * asio::serial_port_base::parity @n
   * asio::serial_port_base::stop_bits @n
   * asio::serial_port_base::character_size
   */
  template <typename SettableSerialPortOption>
  void set_option(const SettableSerialPortOption& option)
  {
    asio::error_code ec;
    impl_.get_service().set_option(impl_.get_implementation(), option, ec);
    asio::detail::throw_error(ec, "set_option");
  }
  /// Set an option on the serial port.
  /**
   * This function is used to set an option on the serial port.
   *
   * @param option The option value to be set on the serial port.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @sa SettableSerialPortOption @n
   * asio::serial_port_base::baud_rate @n
   * asio::serial_port_base::flow_control @n
   * asio::serial_port_base::parity @n
   * asio::serial_port_base::stop_bits @n
   * asio::serial_port_base::character_size
   */
  template <typename SettableSerialPortOption>
  ASIO_SYNC_OP_VOID set_option(const SettableSerialPortOption& option,
      asio::error_code& ec)
  {
    impl_.get_service().set_option(impl_.get_implementation(), option, ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Get an option from the serial port.
  /**
   * This function is used to get the current value of an option on the serial
   * port.
   *
   * @param option The option value to be obtained from the serial port.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @sa GettableSerialPortOption @n
   * asio::serial_port_base::baud_rate @n
   * asio::serial_port_base::flow_control @n
   * asio::serial_port_base::parity @n
   * asio::serial_port_base::stop_bits @n
   * asio::serial_port_base::character_size
   */
  template <typename GettableSerialPortOption>
  void get_option(GettableSerialPortOption& option) const
  {
    asio::error_code ec;
    impl_.get_service().get_option(impl_.get_implementation(), option, ec);
    asio::detail::throw_error(ec, "get_option");
  }
  /// Get an option from the serial port.
  /**
   * This function is used to get the current value of an option on the serial
   * port.
   *
   * @param option The option value to be obtained from the serial port.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @sa GettableSerialPortOption @n
   * asio::serial_port_base::baud_rate @n
   * asio::serial_port_base::flow_control @n
   * asio::serial_port_base::parity @n
   * asio::serial_port_base::stop_bits @n
   * asio::serial_port_base::character_size
   */
  template <typename GettableSerialPortOption>
  ASIO_SYNC_OP_VOID get_option(GettableSerialPortOption& option,
      asio::error_code& ec) const
  {
    impl_.get_service().get_option(impl_.get_implementation(), option, ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Write some data to the serial port.
  /**
   * This function is used to write data to the serial port. The function call
   * will block until one or more bytes of the data has been written
   * successfully, or until an error occurs.
   *
   * @param buffers One or more data buffers to be written to the serial port.
   *
   * @returns The number of bytes written.
   *
   * @throws asio::system_error Thrown on failure. An error code of
   * asio::error::eof indicates that the connection was closed by the
   * peer.
   *
   * @note The write_some operation may not transmit all of the data to the
   * peer. Consider using the @ref write function if you need to ensure that
   * all data is written before the blocking operation completes.
   *
   * @par Example
   * To write a single data buffer use the @ref buffer function as follows:
   * @code
   * basic_serial_port.write_some(asio::buffer(data, size));
   * @endcode
   * See the @ref buffer documentation for information on writing multiple
   * buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename ConstBufferSequence>
  std::size_t write_some(const ConstBufferSequence& buffers)
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().write_some(
        impl_.get_implementation(), buffers, ec);
    asio::detail::throw_error(ec, "write_some");
    return s;
  }
  /// Write some data to the serial port.
  /**
   * This function is used to write data to the serial port. The function call
   * will block until one or more bytes of the data has been written
   * successfully, or until an error occurs.
   *
   * @param buffers One or more data buffers to be written to the serial port.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @returns The number of bytes written. Returns 0 if an error occurred.
   *
   * @note The write_some operation may not transmit all of the data to the
   * peer. Consider using the @ref write function if you need to ensure that
   * all data is written before the blocking operation completes.
   */
  template <typename ConstBufferSequence>
  std::size_t write_some(const ConstBufferSequence& buffers,
      asio::error_code& ec)
  {
    return impl_.get_service().write_some(
        impl_.get_implementation(), buffers, ec);
  }
  /// Start an asynchronous write.
  /**
   * This function is used to asynchronously write data to the serial port.
   * The function call always returns immediately.
   *
   * @param buffers One or more data buffers to be written to the serial port.
   * Although the buffers object may be copied as necessary, ownership of the
   * underlying memory blocks is retained by the caller, which must guarantee
   * that they remain valid until the handler is called.
   *
   * @param handler The handler to be called when the write operation completes.
   * Copies will be made of the handler as required. The function signature of
   * the handler must be:
   * @code void handler(
   *   const asio::error_code& error, // Result of operation.
   *   std::size_t bytes_transferred           // Number of bytes written.
   * ); @endcode
   * Regardless of whether the asynchronous operation completes immediately or
   * not, the handler will not be invoked from within this function. On
   * immediate completion, invocation of the handler will be performed in a
   * manner equivalent to using asio::post().
   *
   * @note The write operation may not transmit all of the data to the peer.
   * Consider using the @ref async_write function if you need to ensure that all
   * data is written before the asynchronous operation completes.
   *
   * @par Example
   * To write a single data buffer use the @ref buffer function as follows:
   * @code
   * basic_serial_port.async_write_some(
   *     asio::buffer(data, size), handler);
   * @endcode
   * See the @ref buffer documentation for information on writing multiple
   * buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename ConstBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) WriteHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(WriteHandler,
      void (asio::error_code, std::size_t))
  async_write_some(const ConstBufferSequence& buffers,
      ASIO_MOVE_ARG(WriteHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return async_initiate<WriteHandler,
      void (asio::error_code, std::size_t)>(
        initiate_async_write_some(this), handler, buffers);
  }
  /// Read some data from the serial port.
  /**
   * This function is used to read data from the serial port. The function
   * call will block until one or more bytes of data has been read successfully,
   * or until an error occurs.
   *
   * @param buffers One or more buffers into which the data will be read.
   *
   * @returns The number of bytes read.
   *
   * @throws asio::system_error Thrown on failure. An error code of
   * asio::error::eof indicates that the connection was closed by the
   * peer.
   *
   * @note The read_some operation may not read all of the requested number of
   * bytes. Consider using the @ref read function if you need to ensure that
   * the requested amount of data is read before the blocking operation
   * completes.
   *
   * @par Example
   * To read into a single data buffer use the @ref buffer function as follows:
   * @code
   * basic_serial_port.read_some(asio::buffer(data, size));
   * @endcode
   * See the @ref buffer documentation for information on reading into multiple
   * buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename MutableBufferSequence>
  std::size_t read_some(const MutableBufferSequence& buffers)
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().read_some(
        impl_.get_implementation(), buffers, ec);
    asio::detail::throw_error(ec, "read_some");
    return s;
  }
  /// Read some data from the serial port.
  /**
   * This function is used to read data from the serial port. The function
   * call will block until one or more bytes of data has been read successfully,
   * or until an error occurs.
   *
   * @param buffers One or more buffers into which the data will be read.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @returns The number of bytes read. Returns 0 if an error occurred.
   *
   * @note The read_some operation may not read all of the requested number of
   * bytes. Consider using the @ref read function if you need to ensure that
   * the requested amount of data is read before the blocking operation
   * completes.
   */
  template <typename MutableBufferSequence>
  std::size_t read_some(const MutableBufferSequence& buffers,
      asio::error_code& ec)
  {
    return impl_.get_service().read_some(
        impl_.get_implementation(), buffers, ec);
  }
  /// Start an asynchronous read.
  /**
   * This function is used to asynchronously read data from the serial port.
   * The function call always returns immediately.
   *
   * @param buffers One or more buffers into which the data will be read.
   * Although the buffers object may be copied as necessary, ownership of the
   * underlying memory blocks is retained by the caller, which must guarantee
   * that they remain valid until the handler is called.
   *
   * @param handler The handler to be called when the read operation completes.
   * Copies will be made of the handler as required. The function signature of
   * the handler must be:
   * @code void handler(
   *   const asio::error_code& error, // Result of operation.
   *   std::size_t bytes_transferred           // Number of bytes read.
   * ); @endcode
   * Regardless of whether the asynchronous operation completes immediately or
   * not, the handler will not be invoked from within this function. On
   * immediate completion, invocation of the handler will be performed in a
   * manner equivalent to using asio::post().
   *
   * @note The read operation may not read all of the requested number of bytes.
   * Consider using the @ref async_read function if you need to ensure that the
   * requested amount of data is read before the asynchronous operation
   * completes.
   *
   * @par Example
   * To read into a single data buffer use the @ref buffer function as follows:
   * @code
   * basic_serial_port.async_read_some(
   *     asio::buffer(data, size), handler);
   * @endcode
   * See the @ref buffer documentation for information on reading into multiple
   * buffers in one go, and how to use it with arrays, boost::array or
   * std::vector.
   */
  template <typename MutableBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) ReadHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(ReadHandler,
      void (asio::error_code, std::size_t))
  async_read_some(const MutableBufferSequence& buffers,
      ASIO_MOVE_ARG(ReadHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return async_initiate<ReadHandler,
      void (asio::error_code, std::size_t)>(
        initiate_async_read_some(this), handler, buffers);
  }
 private:
  // Disallow copying and assignment.
  basic_serial_port(const basic_serial_port&) ASIO_DELETED;
  basic_serial_port& operator=(const basic_serial_port&) ASIO_DELETED;
  class initiate_async_write_some
  {
  public:
    typedef Executor executor_type;
    explicit initiate_async_write_some(basic_serial_port* self)
      : self_(self)
    {
    }
    executor_type get_executor() const ASIO_NOEXCEPT
    {
      return self_->get_executor();
    }
    template <typename WriteHandler, typename ConstBufferSequence>
    void operator()(ASIO_MOVE_ARG(WriteHandler) handler,
        const ConstBufferSequence& buffers) const
    {
      // If you get an error on the following line it means that your handler
      // does not meet the documented type requirements for a WriteHandler.
      ASIO_WRITE_HANDLER_CHECK(WriteHandler, handler) type_check;
      detail::non_const_lvalue<WriteHandler> handler2(handler);
      self_->impl_.get_service().async_write_some(
          self_->impl_.get_implementation(), buffers,
          handler2.value, self_->impl_.get_executor());
    }
  private:
    basic_serial_port* self_;
  };
  class initiate_async_read_some
  {
  public:
    typedef Executor executor_type;
    explicit initiate_async_read_some(basic_serial_port* self)
      : self_(self)
    {
    }
    executor_type get_executor() const ASIO_NOEXCEPT
    {
      return self_->get_executor();
    }
    template <typename ReadHandler, typename MutableBufferSequence>
    void operator()(ASIO_MOVE_ARG(ReadHandler) handler,
        const MutableBufferSequence& buffers) const
    {
      // If you get an error on the following line it means that your handler
      // does not meet the documented type requirements for a ReadHandler.
      ASIO_READ_HANDLER_CHECK(ReadHandler, handler) type_check;
      detail::non_const_lvalue<ReadHandler> handler2(handler);
      self_->impl_.get_service().async_read_some(
          self_->impl_.get_implementation(), buffers,
          handler2.value, self_->impl_.get_executor());
    }
  private:
    basic_serial_port* self_;
  };
 #if defined(ASIO_HAS_IOCP)
  detail::io_object_impl<detail::win_iocp_serial_port_service, Executor> impl_;
 #else
  detail::io_object_impl<detail::reactive_serial_port_service, Executor> impl_;
 #endif
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // defined(ASIO_HAS_SERIAL_PORT)
       //   || defined(GENERATING_DOCUMENTATION)
 #endif // ASIO_BASIC_SERIAL_PORT_HPP
--- a/module/Vendor/ASIO/include/asio/basic_signal_set.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_signal_set.hpp
@ -0,0 +1,572 @@
 //
 // basic_signal_set.hpp
 // ~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_SIGNAL_SET_HPP
 #define ASIO_BASIC_SIGNAL_SET_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/any_io_executor.hpp"
 #include "asio/async_result.hpp"
 #include "asio/detail/handler_type_requirements.hpp"
 #include "asio/detail/io_object_impl.hpp"
 #include "asio/detail/non_const_lvalue.hpp"
 #include "asio/detail/signal_set_service.hpp"
 #include "asio/detail/throw_error.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/error.hpp"
 #include "asio/execution_context.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 /// Provides signal functionality.
 /**
 * The basic_signal_set class provides the ability to perform an asynchronous
 * wait for one or more signals to occur.
 *
 * @par Thread Safety
 * @e Distinct @e objects: Safe.@n
 * @e Shared @e objects: Unsafe.
 *
 * @par Example
 * Performing an asynchronous wait:
 * @code
 * void handler(
 *     const asio::error_code& error,
 *     int signal_number)
 * {
 *   if (!error)
 *   {
 *     // A signal occurred.
 *   }
 * }
 *
 * ...
 *
 * // Construct a signal set registered for process termination.
 * asio::signal_set signals(my_context, SIGINT, SIGTERM);
 *
 * // Start an asynchronous wait for one of the signals to occur.
 * signals.async_wait(handler);
 * @endcode
 *
 * @par Queueing of signal notifications
 *
 * If a signal is registered with a signal_set, and the signal occurs when
 * there are no waiting handlers, then the signal notification is queued. The
 * next async_wait operation on that signal_set will dequeue the notification.
 * If multiple notifications are queued, subsequent async_wait operations
 * dequeue them one at a time. Signal notifications are dequeued in order of
 * ascending signal number.
 *
 * If a signal number is removed from a signal_set (using the @c remove or @c
 * erase member functions) then any queued notifications for that signal are
 * discarded.
 *
 * @par Multiple registration of signals
 *
 * The same signal number may be registered with different signal_set objects.
 * When the signal occurs, one handler is called for each signal_set object.
 *
 * Note that multiple registration only works for signals that are registered
 * using Asio. The application must not also register a signal handler using
 * functions such as @c signal() or @c sigaction().
 *
 * @par Signal masking on POSIX platforms
 *
 * POSIX allows signals to be blocked using functions such as @c sigprocmask()
 * and @c pthread_sigmask(). For signals to be delivered, programs must ensure
 * that any signals registered using signal_set objects are unblocked in at
 * least one thread.
 */
 template <typename Executor = any_io_executor>
 class basic_signal_set
 {
 public:
  /// The type of the executor associated with the object.
  typedef Executor executor_type;
  /// Rebinds the signal set type to another executor.
  template <typename Executor1>
  struct rebind_executor
  {
    /// The signal set type when rebound to the specified executor.
    typedef basic_signal_set<Executor1> other;
  };
  /// Construct a signal set without adding any signals.
  /**
   * This constructor creates a signal set without registering for any signals.
   *
   * @param ex The I/O executor that the signal set will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the
   * signal set.
   */
  explicit basic_signal_set(const executor_type& ex)
    : impl_(0, ex)
  {
  }
  /// Construct a signal set without adding any signals.
  /**
   * This constructor creates a signal set without registering for any signals.
   *
   * @param context An execution context which provides the I/O executor that
   * the signal set will use, by default, to dispatch handlers for any
   * asynchronous operations performed on the signal set.
   */
  template <typename ExecutionContext>
  explicit basic_signal_set(ExecutionContext& context,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
  }
  /// Construct a signal set and add one signal.
  /**
   * This constructor creates a signal set and registers for one signal.
   *
   * @param ex The I/O executor that the signal set will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the
   * signal set.
   *
   * @param signal_number_1 The signal number to be added.
   *
   * @note This constructor is equivalent to performing:
   * @code asio::signal_set signals(ex);
   * signals.add(signal_number_1); @endcode
   */
  basic_signal_set(const executor_type& ex, int signal_number_1)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().add(impl_.get_implementation(), signal_number_1, ec);
    asio::detail::throw_error(ec, "add");
  }
  /// Construct a signal set and add one signal.
  /**
   * This constructor creates a signal set and registers for one signal.
   *
   * @param context An execution context which provides the I/O executor that
   * the signal set will use, by default, to dispatch handlers for any
   * asynchronous operations performed on the signal set.
   *
   * @param signal_number_1 The signal number to be added.
   *
   * @note This constructor is equivalent to performing:
   * @code asio::signal_set signals(context);
   * signals.add(signal_number_1); @endcode
   */
  template <typename ExecutionContext>
  basic_signal_set(ExecutionContext& context, int signal_number_1,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().add(impl_.get_implementation(), signal_number_1, ec);
    asio::detail::throw_error(ec, "add");
  }
  /// Construct a signal set and add two signals.
  /**
   * This constructor creates a signal set and registers for two signals.
   *
   * @param ex The I/O executor that the signal set will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the
   * signal set.
   *
   * @param signal_number_1 The first signal number to be added.
   *
   * @param signal_number_2 The second signal number to be added.
   *
   * @note This constructor is equivalent to performing:
   * @code asio::signal_set signals(ex);
   * signals.add(signal_number_1);
   * signals.add(signal_number_2); @endcode
   */
  basic_signal_set(const executor_type& ex, int signal_number_1,
      int signal_number_2)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().add(impl_.get_implementation(), signal_number_1, ec);
    asio::detail::throw_error(ec, "add");
    impl_.get_service().add(impl_.get_implementation(), signal_number_2, ec);
    asio::detail::throw_error(ec, "add");
  }
  /// Construct a signal set and add two signals.
  /**
   * This constructor creates a signal set and registers for two signals.
   *
   * @param context An execution context which provides the I/O executor that
   * the signal set will use, by default, to dispatch handlers for any
   * asynchronous operations performed on the signal set.
   *
   * @param signal_number_1 The first signal number to be added.
   *
   * @param signal_number_2 The second signal number to be added.
   *
   * @note This constructor is equivalent to performing:
   * @code asio::signal_set signals(context);
   * signals.add(signal_number_1);
   * signals.add(signal_number_2); @endcode
   */
  template <typename ExecutionContext>
  basic_signal_set(ExecutionContext& context, int signal_number_1,
      int signal_number_2,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().add(impl_.get_implementation(), signal_number_1, ec);
    asio::detail::throw_error(ec, "add");
    impl_.get_service().add(impl_.get_implementation(), signal_number_2, ec);
    asio::detail::throw_error(ec, "add");
  }
  /// Construct a signal set and add three signals.
  /**
   * This constructor creates a signal set and registers for three signals.
   *
   * @param ex The I/O executor that the signal set will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the
   * signal set.
   *
   * @param signal_number_1 The first signal number to be added.
   *
   * @param signal_number_2 The second signal number to be added.
   *
   * @param signal_number_3 The third signal number to be added.
   *
   * @note This constructor is equivalent to performing:
   * @code asio::signal_set signals(ex);
   * signals.add(signal_number_1);
   * signals.add(signal_number_2);
   * signals.add(signal_number_3); @endcode
   */
  basic_signal_set(const executor_type& ex, int signal_number_1,
      int signal_number_2, int signal_number_3)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().add(impl_.get_implementation(), signal_number_1, ec);
    asio::detail::throw_error(ec, "add");
    impl_.get_service().add(impl_.get_implementation(), signal_number_2, ec);
    asio::detail::throw_error(ec, "add");
    impl_.get_service().add(impl_.get_implementation(), signal_number_3, ec);
    asio::detail::throw_error(ec, "add");
  }
  /// Construct a signal set and add three signals.
  /**
   * This constructor creates a signal set and registers for three signals.
   *
   * @param context An execution context which provides the I/O executor that
   * the signal set will use, by default, to dispatch handlers for any
   * asynchronous operations performed on the signal set.
   *
   * @param signal_number_1 The first signal number to be added.
   *
   * @param signal_number_2 The second signal number to be added.
   *
   * @param signal_number_3 The third signal number to be added.
   *
   * @note This constructor is equivalent to performing:
   * @code asio::signal_set signals(context);
   * signals.add(signal_number_1);
   * signals.add(signal_number_2);
   * signals.add(signal_number_3); @endcode
   */
  template <typename ExecutionContext>
  basic_signal_set(ExecutionContext& context, int signal_number_1,
      int signal_number_2, int signal_number_3,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().add(impl_.get_implementation(), signal_number_1, ec);
    asio::detail::throw_error(ec, "add");
    impl_.get_service().add(impl_.get_implementation(), signal_number_2, ec);
    asio::detail::throw_error(ec, "add");
    impl_.get_service().add(impl_.get_implementation(), signal_number_3, ec);
    asio::detail::throw_error(ec, "add");
  }
  /// Destroys the signal set.
  /**
   * This function destroys the signal set, cancelling any outstanding
   * asynchronous wait operations associated with the signal set as if by
   * calling @c cancel.
   */
  ~basic_signal_set()
  {
  }
  /// Get the executor associated with the object.
  executor_type get_executor() ASIO_NOEXCEPT
  {
    return impl_.get_executor();
  }
  /// Add a signal to a signal_set.
  /**
   * This function adds the specified signal to the set. It has no effect if the
   * signal is already in the set.
   *
   * @param signal_number The signal to be added to the set.
   *
   * @throws asio::system_error Thrown on failure.
   */
  void add(int signal_number)
  {
    asio::error_code ec;
    impl_.get_service().add(impl_.get_implementation(), signal_number, ec);
    asio::detail::throw_error(ec, "add");
  }
  /// Add a signal to a signal_set.
  /**
   * This function adds the specified signal to the set. It has no effect if the
   * signal is already in the set.
   *
   * @param signal_number The signal to be added to the set.
   *
   * @param ec Set to indicate what error occurred, if any.
   */
  ASIO_SYNC_OP_VOID add(int signal_number,
      asio::error_code& ec)
  {
    impl_.get_service().add(impl_.get_implementation(), signal_number, ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Remove a signal from a signal_set.
  /**
   * This function removes the specified signal from the set. It has no effect
   * if the signal is not in the set.
   *
   * @param signal_number The signal to be removed from the set.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note Removes any notifications that have been queued for the specified
   * signal number.
   */
  void remove(int signal_number)
  {
    asio::error_code ec;
    impl_.get_service().remove(impl_.get_implementation(), signal_number, ec);
    asio::detail::throw_error(ec, "remove");
  }
  /// Remove a signal from a signal_set.
  /**
   * This function removes the specified signal from the set. It has no effect
   * if the signal is not in the set.
   *
   * @param signal_number The signal to be removed from the set.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @note Removes any notifications that have been queued for the specified
   * signal number.
   */
  ASIO_SYNC_OP_VOID remove(int signal_number,
      asio::error_code& ec)
  {
    impl_.get_service().remove(impl_.get_implementation(), signal_number, ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Remove all signals from a signal_set.
  /**
   * This function removes all signals from the set. It has no effect if the set
   * is already empty.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note Removes all queued notifications.
   */
  void clear()
  {
    asio::error_code ec;
    impl_.get_service().clear(impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "clear");
  }
  /// Remove all signals from a signal_set.
  /**
   * This function removes all signals from the set. It has no effect if the set
   * is already empty.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @note Removes all queued notifications.
   */
  ASIO_SYNC_OP_VOID clear(asio::error_code& ec)
  {
    impl_.get_service().clear(impl_.get_implementation(), ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Cancel all operations associated with the signal set.
  /**
   * This function forces the completion of any pending asynchronous wait
   * operations against the signal set. The handler for each cancelled
   * operation will be invoked with the asio::error::operation_aborted
   * error code.
   *
   * Cancellation does not alter the set of registered signals.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If a registered signal occurred before cancel() is called, then the
   * handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  void cancel()
  {
    asio::error_code ec;
    impl_.get_service().cancel(impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "cancel");
  }
  /// Cancel all operations associated with the signal set.
  /**
   * This function forces the completion of any pending asynchronous wait
   * operations against the signal set. The handler for each cancelled
   * operation will be invoked with the asio::error::operation_aborted
   * error code.
   *
   * Cancellation does not alter the set of registered signals.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @note If a registered signal occurred before cancel() is called, then the
   * handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  ASIO_SYNC_OP_VOID cancel(asio::error_code& ec)
  {
    impl_.get_service().cancel(impl_.get_implementation(), ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Start an asynchronous operation to wait for a signal to be delivered.
  /**
   * This function may be used to initiate an asynchronous wait against the
   * signal set. It always returns immediately.
   *
   * For each call to async_wait(), the supplied handler will be called exactly
   * once. The handler will be called when:
   *
   * @li One of the registered signals in the signal set occurs; or
   *
   * @li The signal set was cancelled, in which case the handler is passed the
   * error code asio::error::operation_aborted.
   *
   * @param handler The handler to be called when the signal occurs. Copies
   * will be made of the handler as required. The function signature of the
   * handler must be:
   * @code void handler(
   *   const asio::error_code& error, // Result of operation.
   *   int signal_number // Indicates which signal occurred.
   * ); @endcode
   * Regardless of whether the asynchronous operation completes immediately or
   * not, the handler will not be invoked from within this function. On
   * immediate completion, invocation of the handler will be performed in a
   * manner equivalent to using asio::post().
   */
  template <
    ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code, int))
      SignalHandler ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(SignalHandler,
      void (asio::error_code, int))
  async_wait(
      ASIO_MOVE_ARG(SignalHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return async_initiate<SignalHandler, void (asio::error_code, int)>(
        initiate_async_wait(this), handler);
  }
 private:
  // Disallow copying and assignment.
  basic_signal_set(const basic_signal_set&) ASIO_DELETED;
  basic_signal_set& operator=(const basic_signal_set&) ASIO_DELETED;
  class initiate_async_wait
  {
  public:
    typedef Executor executor_type;
    explicit initiate_async_wait(basic_signal_set* self)
      : self_(self)
    {
    }
    executor_type get_executor() const ASIO_NOEXCEPT
    {
      return self_->get_executor();
    }
    template <typename SignalHandler>
    void operator()(ASIO_MOVE_ARG(SignalHandler) handler) const
    {
      // If you get an error on the following line it means that your handler
      // does not meet the documented type requirements for a SignalHandler.
      ASIO_SIGNAL_HANDLER_CHECK(SignalHandler, handler) type_check;
      detail::non_const_lvalue<SignalHandler> handler2(handler);
      self_->impl_.get_service().async_wait(
          self_->impl_.get_implementation(),
          handler2.value, self_->impl_.get_executor());
    }
  private:
    basic_signal_set* self_;
  };
  detail::io_object_impl<detail::signal_set_service, Executor> impl_;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_BASIC_SIGNAL_SET_HPP
--- a/module/Vendor/ASIO/include/asio/basic_socket.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_socket.hpp
--- a/module/Vendor/ASIO/include/asio/basic_socket_acceptor.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_socket_acceptor.hpp
--- a/module/Vendor/ASIO/include/asio/basic_socket_iostream.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_socket_iostream.hpp
@ -0,0 +1,407 @@
 //
 // basic_socket_iostream.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_SOCKET_IOSTREAM_HPP
 #define ASIO_BASIC_SOCKET_IOSTREAM_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if !defined(ASIO_NO_IOSTREAM)
 #include <istream>
 #include <ostream>
 #include "asio/basic_socket_streambuf.hpp"
 #if !defined(ASIO_HAS_VARIADIC_TEMPLATES)
 # include "asio/detail/variadic_templates.hpp"
 // A macro that should expand to:
 //   template <typename T1, ..., typename Tn>
 //   explicit basic_socket_iostream(T1 x1, ..., Tn xn)
 //     : std::basic_iostream<char>(
 //         &this->detail::socket_iostream_base<
 //           Protocol, Clock, WaitTraits>::streambuf_)
 //   {
 //     if (rdbuf()->connect(x1, ..., xn) == 0)
 //       this->setstate(std::ios_base::failbit);
 //   }
 // This macro should only persist within this file.
 # define ASIO_PRIVATE_CTR_DEF(n) \
  template <ASIO_VARIADIC_TPARAMS(n)> \
  explicit basic_socket_iostream(ASIO_VARIADIC_BYVAL_PARAMS(n)) \
    : std::basic_iostream<char>( \
        &this->detail::socket_iostream_base< \
          Protocol, Clock, WaitTraits>::streambuf_) \
  { \
    this->setf(std::ios_base::unitbuf); \
    if (rdbuf()->connect(ASIO_VARIADIC_BYVAL_ARGS(n)) == 0) \
      this->setstate(std::ios_base::failbit); \
  } \
  /**/
 // A macro that should expand to:
 //   template <typename T1, ..., typename Tn>
 //   void connect(T1 x1, ..., Tn xn)
 //   {
 //     if (rdbuf()->connect(x1, ..., xn) == 0)
 //       this->setstate(std::ios_base::failbit);
 //   }
 // This macro should only persist within this file.
 # define ASIO_PRIVATE_CONNECT_DEF(n) \
  template <ASIO_VARIADIC_TPARAMS(n)> \
  void connect(ASIO_VARIADIC_BYVAL_PARAMS(n)) \
  { \
    if (rdbuf()->connect(ASIO_VARIADIC_BYVAL_ARGS(n)) == 0) \
      this->setstate(std::ios_base::failbit); \
  } \
  /**/
 #endif // !defined(ASIO_HAS_VARIADIC_TEMPLATES)
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 // A separate base class is used to ensure that the streambuf is initialised
 // prior to the basic_socket_iostream's basic_iostream base class.
 template <typename Protocol, typename Clock, typename WaitTraits>
 class socket_iostream_base
 {
 protected:
  socket_iostream_base()
  {
  }
 #if defined(ASIO_HAS_MOVE)
  socket_iostream_base(socket_iostream_base&& other)
    : streambuf_(std::move(other.streambuf_))
  {
  }
  socket_iostream_base(basic_stream_socket<Protocol> s)
    : streambuf_(std::move(s))
  {
  }
  socket_iostream_base& operator=(socket_iostream_base&& other)
  {
    streambuf_ = std::move(other.streambuf_);
    return *this;
  }
 #endif // defined(ASIO_HAS_MOVE)
  basic_socket_streambuf<Protocol, Clock, WaitTraits> streambuf_;
 };
 } // namespace detail
 #if !defined(ASIO_BASIC_SOCKET_IOSTREAM_FWD_DECL)
 #define ASIO_BASIC_SOCKET_IOSTREAM_FWD_DECL
 // Forward declaration with defaulted arguments.
 template <typename Protocol,
 #if defined(ASIO_HAS_BOOST_DATE_TIME) \
  && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
    typename Clock = boost::posix_time::ptime,
    typename WaitTraits = time_traits<Clock> >
 #else // defined(ASIO_HAS_BOOST_DATE_TIME)
      // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
    typename Clock = chrono::steady_clock,
    typename WaitTraits = wait_traits<Clock> >
 #endif // defined(ASIO_HAS_BOOST_DATE_TIME)
       // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
 class basic_socket_iostream;
 #endif // !defined(ASIO_BASIC_SOCKET_IOSTREAM_FWD_DECL)
 /// Iostream interface for a socket.
 #if defined(GENERATING_DOCUMENTATION)
 template <typename Protocol,
    typename Clock = chrono::steady_clock,
    typename WaitTraits = wait_traits<Clock> >
 #else // defined(GENERATING_DOCUMENTATION)
 template <typename Protocol, typename Clock, typename WaitTraits>
 #endif // defined(GENERATING_DOCUMENTATION)
 class basic_socket_iostream
  : private detail::socket_iostream_base<Protocol, Clock, WaitTraits>,
    public std::basic_iostream<char>
 {
 private:
  // These typedefs are intended keep this class's implementation independent
  // of whether it's using Boost.DateClock, Boost.Chrono or std::chrono.
 #if defined(ASIO_HAS_BOOST_DATE_TIME) \
  && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
  typedef WaitTraits traits_helper;
 #else // defined(ASIO_HAS_BOOST_DATE_TIME)
      // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
  typedef detail::chrono_time_traits<Clock, WaitTraits> traits_helper;
 #endif // defined(ASIO_HAS_BOOST_DATE_TIME)
       // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
 public:
  /// The protocol type.
  typedef Protocol protocol_type;
  /// The endpoint type.
  typedef typename Protocol::endpoint endpoint_type;
  /// The clock type.
  typedef Clock clock_type;
 #if defined(GENERATING_DOCUMENTATION)
  /// (Deprecated: Use time_point.) The time type.
  typedef typename WaitTraits::time_type time_type;
  /// The time type.
  typedef typename WaitTraits::time_point time_point;
  /// (Deprecated: Use duration.) The duration type.
  typedef typename WaitTraits::duration_type duration_type;
  /// The duration type.
  typedef typename WaitTraits::duration duration;
 #else
 # if !defined(ASIO_NO_DEPRECATED)
  typedef typename traits_helper::time_type time_type;
  typedef typename traits_helper::duration_type duration_type;
 # endif // !defined(ASIO_NO_DEPRECATED)
  typedef typename traits_helper::time_type time_point;
  typedef typename traits_helper::duration_type duration;
 #endif
  /// Construct a basic_socket_iostream without establishing a connection.
  basic_socket_iostream()
    : std::basic_iostream<char>(
        &this->detail::socket_iostream_base<
          Protocol, Clock, WaitTraits>::streambuf_)
  {
    this->setf(std::ios_base::unitbuf);
  }
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Construct a basic_socket_iostream from the supplied socket.
  explicit basic_socket_iostream(basic_stream_socket<protocol_type> s)
    : detail::socket_iostream_base<
        Protocol, Clock, WaitTraits>(std::move(s)),
      std::basic_iostream<char>(
        &this->detail::socket_iostream_base<
          Protocol, Clock, WaitTraits>::streambuf_)
  {
    this->setf(std::ios_base::unitbuf);
  }
 #if defined(ASIO_HAS_STD_IOSTREAM_MOVE) \
  || defined(GENERATING_DOCUMENTATION)
  /// Move-construct a basic_socket_iostream from another.
  basic_socket_iostream(basic_socket_iostream&& other)
    : detail::socket_iostream_base<
        Protocol, Clock, WaitTraits>(std::move(other)),
      std::basic_iostream<char>(std::move(other))
  {
    this->set_rdbuf(&this->detail::socket_iostream_base<
          Protocol, Clock, WaitTraits>::streambuf_);
  }
  /// Move-assign a basic_socket_iostream from another.
  basic_socket_iostream& operator=(basic_socket_iostream&& other)
  {
    std::basic_iostream<char>::operator=(std::move(other));
    detail::socket_iostream_base<
        Protocol, Clock, WaitTraits>::operator=(std::move(other));
    return *this;
  }
 #endif // defined(ASIO_HAS_STD_IOSTREAM_MOVE)
       //   || defined(GENERATING_DOCUMENTATION)
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
 #if defined(GENERATING_DOCUMENTATION)
  /// Establish a connection to an endpoint corresponding to a resolver query.
  /**
   * This constructor automatically establishes a connection based on the
   * supplied resolver query parameters. The arguments are used to construct
   * a resolver query object.
   */
  template <typename T1, ..., typename TN>
  explicit basic_socket_iostream(T1 t1, ..., TN tn);
 #elif defined(ASIO_HAS_VARIADIC_TEMPLATES)
  template <typename... T>
  explicit basic_socket_iostream(T... x)
    : std::basic_iostream<char>(
        &this->detail::socket_iostream_base<
          Protocol, Clock, WaitTraits>::streambuf_)
  {
    this->setf(std::ios_base::unitbuf);
    if (rdbuf()->connect(x...) == 0)
      this->setstate(std::ios_base::failbit);
  }
 #else
  ASIO_VARIADIC_GENERATE(ASIO_PRIVATE_CTR_DEF)
 #endif
 #if defined(GENERATING_DOCUMENTATION)
  /// Establish a connection to an endpoint corresponding to a resolver query.
  /**
   * This function automatically establishes a connection based on the supplied
   * resolver query parameters. The arguments are used to construct a resolver
   * query object.
   */
  template <typename T1, ..., typename TN>
  void connect(T1 t1, ..., TN tn);
 #elif defined(ASIO_HAS_VARIADIC_TEMPLATES)
  template <typename... T>
  void connect(T... x)
  {
    if (rdbuf()->connect(x...) == 0)
      this->setstate(std::ios_base::failbit);
  }
 #else
  ASIO_VARIADIC_GENERATE(ASIO_PRIVATE_CONNECT_DEF)
 #endif
  /// Close the connection.
  void close()
  {
    if (rdbuf()->close() == 0)
      this->setstate(std::ios_base::failbit);
  }
  /// Return a pointer to the underlying streambuf.
  basic_socket_streambuf<Protocol, Clock, WaitTraits>* rdbuf() const
  {
    return const_cast<basic_socket_streambuf<Protocol, Clock, WaitTraits>*>(
        &this->detail::socket_iostream_base<
          Protocol, Clock, WaitTraits>::streambuf_);
  }
  /// Get a reference to the underlying socket.
  basic_socket<Protocol>& socket()
  {
    return rdbuf()->socket();
  }
  /// Get the last error associated with the stream.
  /**
   * @return An \c error_code corresponding to the last error from the stream.
   *
   * @par Example
   * To print the error associated with a failure to establish a connection:
   * @code tcp::iostream s("www.boost.org", "http");
   * if (!s)
   * {
   *   std::cout << "Error: " << s.error().message() << std::endl;
   * } @endcode
   */
  const asio::error_code& error() const
  {
    return rdbuf()->error();
  }
 #if !defined(ASIO_NO_DEPRECATED)
  /// (Deprecated: Use expiry().) Get the stream's expiry time as an absolute
  /// time.
  /**
   * @return An absolute time value representing the stream's expiry time.
   */
  time_point expires_at() const
  {
    return rdbuf()->expires_at();
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
  /// Get the stream's expiry time as an absolute time.
  /**
   * @return An absolute time value representing the stream's expiry time.
   */
  time_point expiry() const
  {
    return rdbuf()->expiry();
  }
  /// Set the stream's expiry time as an absolute time.
  /**
   * This function sets the expiry time associated with the stream. Stream
   * operations performed after this time (where the operations cannot be
   * completed using the internal buffers) will fail with the error
   * asio::error::operation_aborted.
   *
   * @param expiry_time The expiry time to be used for the stream.
   */
  void expires_at(const time_point& expiry_time)
  {
    rdbuf()->expires_at(expiry_time);
  }
  /// Set the stream's expiry time relative to now.
  /**
   * This function sets the expiry time associated with the stream. Stream
   * operations performed after this time (where the operations cannot be
   * completed using the internal buffers) will fail with the error
   * asio::error::operation_aborted.
   *
   * @param expiry_time The expiry time to be used for the timer.
   */
  void expires_after(const duration& expiry_time)
  {
    rdbuf()->expires_after(expiry_time);
  }
 #if !defined(ASIO_NO_DEPRECATED)
  /// (Deprecated: Use expiry().) Get the stream's expiry time relative to now.
  /**
   * @return A relative time value representing the stream's expiry time.
   */
  duration expires_from_now() const
  {
    return rdbuf()->expires_from_now();
  }
  /// (Deprecated: Use expires_after().) Set the stream's expiry time relative
  /// to now.
  /**
   * This function sets the expiry time associated with the stream. Stream
   * operations performed after this time (where the operations cannot be
   * completed using the internal buffers) will fail with the error
   * asio::error::operation_aborted.
   *
   * @param expiry_time The expiry time to be used for the timer.
   */
  void expires_from_now(const duration& expiry_time)
  {
    rdbuf()->expires_from_now(expiry_time);
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
 private:
  // Disallow copying and assignment.
  basic_socket_iostream(const basic_socket_iostream&) ASIO_DELETED;
  basic_socket_iostream& operator=(
      const basic_socket_iostream&) ASIO_DELETED;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #if !defined(ASIO_HAS_VARIADIC_TEMPLATES)
 # undef ASIO_PRIVATE_CTR_DEF
 # undef ASIO_PRIVATE_CONNECT_DEF
 #endif // !defined(ASIO_HAS_VARIADIC_TEMPLATES)
 #endif // !defined(ASIO_NO_IOSTREAM)
 #endif // ASIO_BASIC_SOCKET_IOSTREAM_HPP
--- a/module/Vendor/ASIO/include/asio/basic_socket_streambuf.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_socket_streambuf.hpp
@ -0,0 +1,687 @@
 //
 // basic_socket_streambuf.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_SOCKET_STREAMBUF_HPP
 #define ASIO_BASIC_SOCKET_STREAMBUF_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if !defined(ASIO_NO_IOSTREAM)
 #include <streambuf>
 #include <vector>
 #include "asio/basic_socket.hpp"
 #include "asio/basic_stream_socket.hpp"
 #include "asio/detail/buffer_sequence_adapter.hpp"
 #include "asio/detail/memory.hpp"
 #include "asio/detail/throw_error.hpp"
 #include "asio/io_context.hpp"
 #if defined(ASIO_HAS_BOOST_DATE_TIME) \
  && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
 # include "asio/detail/deadline_timer_service.hpp"
 #else // defined(ASIO_HAS_BOOST_DATE_TIME)
      // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
 # include "asio/steady_timer.hpp"
 #endif // defined(ASIO_HAS_BOOST_DATE_TIME)
       // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
 #if !defined(ASIO_HAS_VARIADIC_TEMPLATES)
 # include "asio/detail/variadic_templates.hpp"
 // A macro that should expand to:
 //   template <typename T1, ..., typename Tn>
 //   basic_socket_streambuf* connect(T1 x1, ..., Tn xn)
 //   {
 //     init_buffers();
 //     typedef typename Protocol::resolver resolver_type;
 //     resolver_type resolver(socket().get_executor());
 //     connect_to_endpoints(
 //         resolver.resolve(x1, ..., xn, ec_));
 //     return !ec_ ? this : 0;
 //   }
 // This macro should only persist within this file.
 # define ASIO_PRIVATE_CONNECT_DEF(n) \
  template <ASIO_VARIADIC_TPARAMS(n)> \
  basic_socket_streambuf* connect(ASIO_VARIADIC_BYVAL_PARAMS(n)) \
  { \
    init_buffers(); \
    typedef typename Protocol::resolver resolver_type; \
    resolver_type resolver(socket().get_executor()); \
    connect_to_endpoints( \
        resolver.resolve(ASIO_VARIADIC_BYVAL_ARGS(n), ec_)); \
    return !ec_ ? this : 0; \
  } \
  /**/
 #endif // !defined(ASIO_HAS_VARIADIC_TEMPLATES)
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 // A separate base class is used to ensure that the io_context member is
 // initialised prior to the basic_socket_streambuf's basic_socket base class.
 class socket_streambuf_io_context
 {
 protected:
  socket_streambuf_io_context(io_context* ctx)
    : default_io_context_(ctx)
  {
  }
  shared_ptr<io_context> default_io_context_;
 };
 // A separate base class is used to ensure that the dynamically allocated
 // buffers are constructed prior to the basic_socket_streambuf's basic_socket
 // base class. This makes moving the socket is the last potentially throwing
 // step in the streambuf's move constructor, giving the constructor a strong
 // exception safety guarantee.
 class socket_streambuf_buffers
 {
 protected:
  socket_streambuf_buffers()
    : get_buffer_(buffer_size),
      put_buffer_(buffer_size)
  {
  }
  enum { buffer_size = 512 };
  std::vector<char> get_buffer_;
  std::vector<char> put_buffer_;
 };
 } // namespace detail
 #if !defined(ASIO_BASIC_SOCKET_STREAMBUF_FWD_DECL)
 #define ASIO_BASIC_SOCKET_STREAMBUF_FWD_DECL
 // Forward declaration with defaulted arguments.
 template <typename Protocol,
 #if defined(ASIO_HAS_BOOST_DATE_TIME) \
  && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
    typename Clock = boost::posix_time::ptime,
    typename WaitTraits = time_traits<Clock> >
 #else // defined(ASIO_HAS_BOOST_DATE_TIME)
      // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
    typename Clock = chrono::steady_clock,
    typename WaitTraits = wait_traits<Clock> >
 #endif // defined(ASIO_HAS_BOOST_DATE_TIME)
       // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
 class basic_socket_streambuf;
 #endif // !defined(ASIO_BASIC_SOCKET_STREAMBUF_FWD_DECL)
 /// Iostream streambuf for a socket.
 #if defined(GENERATING_DOCUMENTATION)
 template <typename Protocol,
    typename Clock = chrono::steady_clock,
    typename WaitTraits = wait_traits<Clock> >
 #else // defined(GENERATING_DOCUMENTATION)
 template <typename Protocol, typename Clock, typename WaitTraits>
 #endif // defined(GENERATING_DOCUMENTATION)
 class basic_socket_streambuf
  : public std::streambuf,
    private detail::socket_streambuf_io_context,
    private detail::socket_streambuf_buffers,
 #if defined(ASIO_NO_DEPRECATED) || defined(GENERATING_DOCUMENTATION)
    private basic_socket<Protocol>
 #else // defined(ASIO_NO_DEPRECATED) || defined(GENERATING_DOCUMENTATION)
    public basic_socket<Protocol>
 #endif // defined(ASIO_NO_DEPRECATED) || defined(GENERATING_DOCUMENTATION)
 {
 private:
  // These typedefs are intended keep this class's implementation independent
  // of whether it's using Boost.DateClock, Boost.Chrono or std::chrono.
 #if defined(ASIO_HAS_BOOST_DATE_TIME) \
  && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
  typedef WaitTraits traits_helper;
 #else // defined(ASIO_HAS_BOOST_DATE_TIME)
      // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
  typedef detail::chrono_time_traits<Clock, WaitTraits> traits_helper;
 #endif // defined(ASIO_HAS_BOOST_DATE_TIME)
       // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
 public:
  /// The protocol type.
  typedef Protocol protocol_type;
  /// The endpoint type.
  typedef typename Protocol::endpoint endpoint_type;
  /// The clock type.
  typedef Clock clock_type;
 #if defined(GENERATING_DOCUMENTATION)
  /// (Deprecated: Use time_point.) The time type.
  typedef typename WaitTraits::time_type time_type;
  /// The time type.
  typedef typename WaitTraits::time_point time_point;
  /// (Deprecated: Use duration.) The duration type.
  typedef typename WaitTraits::duration_type duration_type;
  /// The duration type.
  typedef typename WaitTraits::duration duration;
 #else
 # if !defined(ASIO_NO_DEPRECATED)
  typedef typename traits_helper::time_type time_type;
  typedef typename traits_helper::duration_type duration_type;
 # endif // !defined(ASIO_NO_DEPRECATED)
  typedef typename traits_helper::time_type time_point;
  typedef typename traits_helper::duration_type duration;
 #endif
  /// Construct a basic_socket_streambuf without establishing a connection.
  basic_socket_streambuf()
    : detail::socket_streambuf_io_context(new io_context),
      basic_socket<Protocol>(*default_io_context_),
      expiry_time_(max_expiry_time())
  {
    init_buffers();
  }
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Construct a basic_socket_streambuf from the supplied socket.
  explicit basic_socket_streambuf(basic_stream_socket<protocol_type> s)
    : detail::socket_streambuf_io_context(0),
      basic_socket<Protocol>(std::move(s)),
      expiry_time_(max_expiry_time())
  {
    init_buffers();
  }
  /// Move-construct a basic_socket_streambuf from another.
  basic_socket_streambuf(basic_socket_streambuf&& other)
    : detail::socket_streambuf_io_context(other),
      basic_socket<Protocol>(std::move(other.socket())),
      ec_(other.ec_),
      expiry_time_(other.expiry_time_)
  {
    get_buffer_.swap(other.get_buffer_);
    put_buffer_.swap(other.put_buffer_);
    setg(other.eback(), other.gptr(), other.egptr());
    setp(other.pptr(), other.epptr());
    other.ec_ = asio::error_code();
    other.expiry_time_ = max_expiry_time();
    other.init_buffers();
  }
  /// Move-assign a basic_socket_streambuf from another.
  basic_socket_streambuf& operator=(basic_socket_streambuf&& other)
  {
    this->close();
    socket() = std::move(other.socket());
    detail::socket_streambuf_io_context::operator=(other);
    ec_ = other.ec_;
    expiry_time_ = other.expiry_time_;
    get_buffer_.swap(other.get_buffer_);
    put_buffer_.swap(other.put_buffer_);
    setg(other.eback(), other.gptr(), other.egptr());
    setp(other.pptr(), other.epptr());
    other.ec_ = asio::error_code();
    other.expiry_time_ = max_expiry_time();
    other.put_buffer_.resize(buffer_size);
    other.init_buffers();
    return *this;
  }
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Destructor flushes buffered data.
  virtual ~basic_socket_streambuf()
  {
    if (pptr() != pbase())
      overflow(traits_type::eof());
  }
  /// Establish a connection.
  /**
   * This function establishes a connection to the specified endpoint.
   *
   * @return \c this if a connection was successfully established, a null
   * pointer otherwise.
   */
  basic_socket_streambuf* connect(const endpoint_type& endpoint)
  {
    init_buffers();
    ec_ = asio::error_code();
    this->connect_to_endpoints(&endpoint, &endpoint + 1);
    return !ec_ ? this : 0;
  }
 #if defined(GENERATING_DOCUMENTATION)
  /// Establish a connection.
  /**
   * This function automatically establishes a connection based on the supplied
   * resolver query parameters. The arguments are used to construct a resolver
   * query object.
   *
   * @return \c this if a connection was successfully established, a null
   * pointer otherwise.
   */
  template <typename T1, ..., typename TN>
  basic_socket_streambuf* connect(T1 t1, ..., TN tn);
 #elif defined(ASIO_HAS_VARIADIC_TEMPLATES)
  template <typename... T>
  basic_socket_streambuf* connect(T... x)
  {
    init_buffers();
    typedef typename Protocol::resolver resolver_type;
    resolver_type resolver(socket().get_executor());
    connect_to_endpoints(resolver.resolve(x..., ec_));
    return !ec_ ? this : 0;
  }
 #else
  ASIO_VARIADIC_GENERATE(ASIO_PRIVATE_CONNECT_DEF)
 #endif
  /// Close the connection.
  /**
   * @return \c this if a connection was successfully established, a null
   * pointer otherwise.
   */
  basic_socket_streambuf* close()
  {
    sync();
    socket().close(ec_);
    if (!ec_)
      init_buffers();
    return !ec_ ? this : 0;
  }
  /// Get a reference to the underlying socket.
  basic_socket<Protocol>& socket()
  {
    return *this;
  }
  /// Get the last error associated with the stream buffer.
  /**
   * @return An \c error_code corresponding to the last error from the stream
   * buffer.
   */
  const asio::error_code& error() const
  {
    return ec_;
  }
 #if !defined(ASIO_NO_DEPRECATED)
  /// (Deprecated: Use error().) Get the last error associated with the stream
  /// buffer.
  /**
   * @return An \c error_code corresponding to the last error from the stream
   * buffer.
   */
  const asio::error_code& puberror() const
  {
    return error();
  }
  /// (Deprecated: Use expiry().) Get the stream buffer's expiry time as an
  /// absolute time.
  /**
   * @return An absolute time value representing the stream buffer's expiry
   * time.
   */
  time_point expires_at() const
  {
    return expiry_time_;
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
  /// Get the stream buffer's expiry time as an absolute time.
  /**
   * @return An absolute time value representing the stream buffer's expiry
   * time.
   */
  time_point expiry() const
  {
    return expiry_time_;
  }
  /// Set the stream buffer's expiry time as an absolute time.
  /**
   * This function sets the expiry time associated with the stream. Stream
   * operations performed after this time (where the operations cannot be
   * completed using the internal buffers) will fail with the error
   * asio::error::operation_aborted.
   *
   * @param expiry_time The expiry time to be used for the stream.
   */
  void expires_at(const time_point& expiry_time)
  {
    expiry_time_ = expiry_time;
  }
  /// Set the stream buffer's expiry time relative to now.
  /**
   * This function sets the expiry time associated with the stream. Stream
   * operations performed after this time (where the operations cannot be
   * completed using the internal buffers) will fail with the error
   * asio::error::operation_aborted.
   *
   * @param expiry_time The expiry time to be used for the timer.
   */
  void expires_after(const duration& expiry_time)
  {
    expiry_time_ = traits_helper::add(traits_helper::now(), expiry_time);
  }
 #if !defined(ASIO_NO_DEPRECATED)
  /// (Deprecated: Use expiry().) Get the stream buffer's expiry time relative
  /// to now.
  /**
   * @return A relative time value representing the stream buffer's expiry time.
   */
  duration expires_from_now() const
  {
    return traits_helper::subtract(expires_at(), traits_helper::now());
  }
  /// (Deprecated: Use expires_after().) Set the stream buffer's expiry time
  /// relative to now.
  /**
   * This function sets the expiry time associated with the stream. Stream
   * operations performed after this time (where the operations cannot be
   * completed using the internal buffers) will fail with the error
   * asio::error::operation_aborted.
   *
   * @param expiry_time The expiry time to be used for the timer.
   */
  void expires_from_now(const duration& expiry_time)
  {
    expiry_time_ = traits_helper::add(traits_helper::now(), expiry_time);
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
 protected:
  int_type underflow()
  {
 #if defined(ASIO_WINDOWS_RUNTIME)
    ec_ = asio::error::operation_not_supported;
    return traits_type::eof();
 #else // defined(ASIO_WINDOWS_RUNTIME)
    if (gptr() != egptr())
      return traits_type::eof();
    for (;;)
    {
      // Check if we are past the expiry time.
      if (traits_helper::less_than(expiry_time_, traits_helper::now()))
      {
        ec_ = asio::error::timed_out;
        return traits_type::eof();
      }
      // Try to complete the operation without blocking.
      if (!socket().native_non_blocking())
        socket().native_non_blocking(true, ec_);
      detail::buffer_sequence_adapter<mutable_buffer, mutable_buffer>
        bufs(asio::buffer(get_buffer_) + putback_max);
      detail::signed_size_type bytes = detail::socket_ops::recv(
          socket().native_handle(), bufs.buffers(), bufs.count(), 0, ec_);
      // Check if operation succeeded.
      if (bytes > 0)
      {
        setg(&get_buffer_[0], &get_buffer_[0] + putback_max,
            &get_buffer_[0] + putback_max + bytes);
        return traits_type::to_int_type(*gptr());
      }
      // Check for EOF.
      if (bytes == 0)
      {
        ec_ = asio::error::eof;
        return traits_type::eof();
      }
      // Operation failed.
      if (ec_ != asio::error::would_block
          && ec_ != asio::error::try_again)
        return traits_type::eof();
      // Wait for socket to become ready.
      if (detail::socket_ops::poll_read(
            socket().native_handle(), 0, timeout(), ec_) < 0)
        return traits_type::eof();
    }
 #endif // defined(ASIO_WINDOWS_RUNTIME)
  }
  int_type overflow(int_type c)
  {
 #if defined(ASIO_WINDOWS_RUNTIME)
    ec_ = asio::error::operation_not_supported;
    return traits_type::eof();
 #else // defined(ASIO_WINDOWS_RUNTIME)
    char_type ch = traits_type::to_char_type(c);
    // Determine what needs to be sent.
    const_buffer output_buffer;
    if (put_buffer_.empty())
    {
      if (traits_type::eq_int_type(c, traits_type::eof()))
        return traits_type::not_eof(c); // Nothing to do.
      output_buffer = asio::buffer(&ch, sizeof(char_type));
    }
    else
    {
      output_buffer = asio::buffer(pbase(),
          (pptr() - pbase()) * sizeof(char_type));
    }
    while (output_buffer.size() > 0)
    {
      // Check if we are past the expiry time.
      if (traits_helper::less_than(expiry_time_, traits_helper::now()))
      {
        ec_ = asio::error::timed_out;
        return traits_type::eof();
      }
      // Try to complete the operation without blocking.
      if (!socket().native_non_blocking())
        socket().native_non_blocking(true, ec_);
      detail::buffer_sequence_adapter<
        const_buffer, const_buffer> bufs(output_buffer);
      detail::signed_size_type bytes = detail::socket_ops::send(
          socket().native_handle(), bufs.buffers(), bufs.count(), 0, ec_);
      // Check if operation succeeded.
      if (bytes > 0)
      {
        output_buffer += static_cast<std::size_t>(bytes);
        continue;
      }
      // Operation failed.
      if (ec_ != asio::error::would_block
          && ec_ != asio::error::try_again)
        return traits_type::eof();
      // Wait for socket to become ready.
      if (detail::socket_ops::poll_write(
            socket().native_handle(), 0, timeout(), ec_) < 0)
        return traits_type::eof();
    }
    if (!put_buffer_.empty())
    {
      setp(&put_buffer_[0], &put_buffer_[0] + put_buffer_.size());
      // If the new character is eof then our work here is done.
      if (traits_type::eq_int_type(c, traits_type::eof()))
        return traits_type::not_eof(c);
      // Add the new character to the output buffer.
      *pptr() = ch;
      pbump(1);
    }
    return c;
 #endif // defined(ASIO_WINDOWS_RUNTIME)
  }
  int sync()
  {
    return overflow(traits_type::eof());
  }
  std::streambuf* setbuf(char_type* s, std::streamsize n)
  {
    if (pptr() == pbase() && s == 0 && n == 0)
    {
      put_buffer_.clear();
      setp(0, 0);
      sync();
      return this;
    }
    return 0;
  }
 private:
  // Disallow copying and assignment.
  basic_socket_streambuf(const basic_socket_streambuf&) ASIO_DELETED;
  basic_socket_streambuf& operator=(
      const basic_socket_streambuf&) ASIO_DELETED;
  void init_buffers()
  {
    setg(&get_buffer_[0],
        &get_buffer_[0] + putback_max,
        &get_buffer_[0] + putback_max);
    if (put_buffer_.empty())
      setp(0, 0);
    else
      setp(&put_buffer_[0], &put_buffer_[0] + put_buffer_.size());
  }
  int timeout() const
  {
    int64_t msec = traits_helper::to_posix_duration(
        traits_helper::subtract(expiry_time_,
          traits_helper::now())).total_milliseconds();
    if (msec > (std::numeric_limits<int>::max)())
      msec = (std::numeric_limits<int>::max)();
    else if (msec < 0)
      msec = 0;
    return static_cast<int>(msec);
  }
  template <typename EndpointSequence>
  void connect_to_endpoints(const EndpointSequence& endpoints)
  {
    this->connect_to_endpoints(endpoints.begin(), endpoints.end());
  }
  template <typename EndpointIterator>
  void connect_to_endpoints(EndpointIterator begin, EndpointIterator end)
  {
 #if defined(ASIO_WINDOWS_RUNTIME)
    ec_ = asio::error::operation_not_supported;
 #else // defined(ASIO_WINDOWS_RUNTIME)
    if (ec_)
      return;
    ec_ = asio::error::not_found;
    for (EndpointIterator i = begin; i != end; ++i)
    {
      // Check if we are past the expiry time.
      if (traits_helper::less_than(expiry_time_, traits_helper::now()))
      {
        ec_ = asio::error::timed_out;
        return;
      }
      // Close and reopen the socket.
      typename Protocol::endpoint ep(*i);
      socket().close(ec_);
      socket().open(ep.protocol(), ec_);
      if (ec_)
        continue;
      // Try to complete the operation without blocking.
      if (!socket().native_non_blocking())
        socket().native_non_blocking(true, ec_);
      detail::socket_ops::connect(socket().native_handle(),
          ep.data(), ep.size(), ec_);
      // Check if operation succeeded.
      if (!ec_)
        return;
      // Operation failed.
      if (ec_ != asio::error::in_progress
          && ec_ != asio::error::would_block)
        continue;
      // Wait for socket to become ready.
      if (detail::socket_ops::poll_connect(
            socket().native_handle(), timeout(), ec_) < 0)
        continue;
      // Get the error code from the connect operation.
      int connect_error = 0;
      size_t connect_error_len = sizeof(connect_error);
      if (detail::socket_ops::getsockopt(socket().native_handle(), 0,
            SOL_SOCKET, SO_ERROR, &connect_error, &connect_error_len, ec_)
          == detail::socket_error_retval)
        return;
      // Check the result of the connect operation.
      ec_ = asio::error_code(connect_error,
          asio::error::get_system_category());
      if (!ec_)
        return;
    }
 #endif // defined(ASIO_WINDOWS_RUNTIME)
  }
  // Helper function to get the maximum expiry time.
  static time_point max_expiry_time()
  {
 #if defined(ASIO_HAS_BOOST_DATE_TIME) \
  && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
    return boost::posix_time::pos_infin;
 #else // defined(ASIO_HAS_BOOST_DATE_TIME)
      // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
    return (time_point::max)();
 #endif // defined(ASIO_HAS_BOOST_DATE_TIME)
       // && defined(ASIO_USE_BOOST_DATE_TIME_FOR_SOCKET_IOSTREAM)
  }
  enum { putback_max = 8 };
  asio::error_code ec_;
  time_point expiry_time_;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #if !defined(ASIO_HAS_VARIADIC_TEMPLATES)
 # undef ASIO_PRIVATE_CONNECT_DEF
 #endif // !defined(ASIO_HAS_VARIADIC_TEMPLATES)
 #endif // !defined(ASIO_NO_IOSTREAM)
 #endif // ASIO_BASIC_SOCKET_STREAMBUF_HPP
--- a/module/Vendor/ASIO/include/asio/basic_stream_socket.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_stream_socket.hpp
--- a/module/Vendor/ASIO/include/asio/basic_streambuf.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_streambuf.hpp
@ -0,0 +1,452 @@
 //
 // basic_streambuf.hpp
 // ~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_STREAMBUF_HPP
 #define ASIO_BASIC_STREAMBUF_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if !defined(ASIO_NO_IOSTREAM)
 #include <algorithm>
 #include <cstring>
 #include <stdexcept>
 #include <streambuf>
 #include <vector>
 #include "asio/basic_streambuf_fwd.hpp"
 #include "asio/buffer.hpp"
 #include "asio/detail/limits.hpp"
 #include "asio/detail/noncopyable.hpp"
 #include "asio/detail/throw_exception.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 /// Automatically resizable buffer class based on std::streambuf.
 /**
 * The @c basic_streambuf class is derived from @c std::streambuf to associate
 * the streambuf's input and output sequences with one or more character
 * arrays. These character arrays are internal to the @c basic_streambuf
 * object, but direct access to the array elements is provided to permit them
 * to be used efficiently with I/O operations. Characters written to the output
 * sequence of a @c basic_streambuf object are appended to the input sequence
 * of the same object.
 *
 * The @c basic_streambuf class's public interface is intended to permit the
 * following implementation strategies:
 *
 * @li A single contiguous character array, which is reallocated as necessary
 * to accommodate changes in the size of the character sequence. This is the
 * implementation approach currently used in Asio.
 *
 * @li A sequence of one or more character arrays, where each array is of the
 * same size. Additional character array objects are appended to the sequence
 * to accommodate changes in the size of the character sequence.
 *
 * @li A sequence of one or more character arrays of varying sizes. Additional
 * character array objects are appended to the sequence to accommodate changes
 * in the size of the character sequence.
 *
 * The constructor for basic_streambuf accepts a @c size_t argument specifying
 * the maximum of the sum of the sizes of the input sequence and output
 * sequence. During the lifetime of the @c basic_streambuf object, the following
 * invariant holds:
 * @code size() <= max_size()@endcode
 * Any member function that would, if successful, cause the invariant to be
 * violated shall throw an exception of class @c std::length_error.
 *
 * The constructor for @c basic_streambuf takes an Allocator argument. A copy
 * of this argument is used for any memory allocation performed, by the
 * constructor and by all member functions, during the lifetime of each @c
 * basic_streambuf object.
 *
 * @par Examples
 * Writing directly from an streambuf to a socket:
 * @code
 * asio::streambuf b;
 * std::ostream os(&b);
 * os << "Hello, World!\n";
 *
 * // try sending some data in input sequence
 * size_t n = sock.send(b.data());
 *
 * b.consume(n); // sent data is removed from input sequence
 * @endcode
 *
 * Reading from a socket directly into a streambuf:
 * @code
 * asio::streambuf b;
 *
 * // reserve 512 bytes in output sequence
 * asio::streambuf::mutable_buffers_type bufs = b.prepare(512);
 *
 * size_t n = sock.receive(bufs);
 *
 * // received data is "committed" from output sequence to input sequence
 * b.commit(n);
 *
 * std::istream is(&b);
 * std::string s;
 * is >> s;
 * @endcode
 */
 #if defined(GENERATING_DOCUMENTATION)
 template <typename Allocator = std::allocator<char> >
 #else
 template <typename Allocator>
 #endif
 class basic_streambuf
  : public std::streambuf,
    private noncopyable
 {
 public:
 #if defined(GENERATING_DOCUMENTATION)
  /// The type used to represent the input sequence as a list of buffers.
  typedef implementation_defined const_buffers_type;
  /// The type used to represent the output sequence as a list of buffers.
  typedef implementation_defined mutable_buffers_type;
 #else
  typedef ASIO_CONST_BUFFER const_buffers_type;
  typedef ASIO_MUTABLE_BUFFER mutable_buffers_type;
 #endif
  /// Construct a basic_streambuf object.
  /**
   * Constructs a streambuf with the specified maximum size. The initial size
   * of the streambuf's input sequence is 0.
   */
  explicit basic_streambuf(
      std::size_t maximum_size = (std::numeric_limits<std::size_t>::max)(),
      const Allocator& allocator = Allocator())
    : max_size_(maximum_size),
      buffer_(allocator)
  {
    std::size_t pend = (std::min<std::size_t>)(max_size_, buffer_delta);
    buffer_.resize((std::max<std::size_t>)(pend, 1));
    setg(&buffer_[0], &buffer_[0], &buffer_[0]);
    setp(&buffer_[0], &buffer_[0] + pend);
  }
  /// Get the size of the input sequence.
  /**
   * @returns The size of the input sequence. The value is equal to that
   * calculated for @c s in the following code:
   * @code
   * size_t s = 0;
   * const_buffers_type bufs = data();
   * const_buffers_type::const_iterator i = bufs.begin();
   * while (i != bufs.end())
   * {
   *   const_buffer buf(*i++);
   *   s += buf.size();
   * }
   * @endcode
   */
  std::size_t size() const ASIO_NOEXCEPT
  {
    return pptr() - gptr();
  }
  /// Get the maximum size of the basic_streambuf.
  /**
   * @returns The allowed maximum of the sum of the sizes of the input sequence
   * and output sequence.
   */
  std::size_t max_size() const ASIO_NOEXCEPT
  {
    return max_size_;
  }
  /// Get the current capacity of the basic_streambuf.
  /**
   * @returns The current total capacity of the streambuf, i.e. for both the
   * input sequence and output sequence.
   */
  std::size_t capacity() const ASIO_NOEXCEPT
  {
    return buffer_.capacity();
  }
  /// Get a list of buffers that represents the input sequence.
  /**
   * @returns An object of type @c const_buffers_type that satisfies
   * ConstBufferSequence requirements, representing all character arrays in the
   * input sequence.
   *
   * @note The returned object is invalidated by any @c basic_streambuf member
   * function that modifies the input sequence or output sequence.
   */
  const_buffers_type data() const ASIO_NOEXCEPT
  {
    return asio::buffer(asio::const_buffer(gptr(),
          (pptr() - gptr()) * sizeof(char_type)));
  }
  /// Get a list of buffers that represents the output sequence, with the given
  /// size.
  /**
   * Ensures that the output sequence can accommodate @c n characters,
   * reallocating character array objects as necessary.
   *
   * @returns An object of type @c mutable_buffers_type that satisfies
   * MutableBufferSequence requirements, representing character array objects
   * at the start of the output sequence such that the sum of the buffer sizes
   * is @c n.
   *
   * @throws std::length_error If <tt>size() + n > max_size()</tt>.
   *
   * @note The returned object is invalidated by any @c basic_streambuf member
   * function that modifies the input sequence or output sequence.
   */
  mutable_buffers_type prepare(std::size_t n)
  {
    reserve(n);
    return asio::buffer(asio::mutable_buffer(
          pptr(), n * sizeof(char_type)));
  }
  /// Move characters from the output sequence to the input sequence.
  /**
   * Appends @c n characters from the start of the output sequence to the input
   * sequence. The beginning of the output sequence is advanced by @c n
   * characters.
   *
   * Requires a preceding call <tt>prepare(x)</tt> where <tt>x >= n</tt>, and
   * no intervening operations that modify the input or output sequence.
   *
   * @note If @c n is greater than the size of the output sequence, the entire
   * output sequence is moved to the input sequence and no error is issued.
   */
  void commit(std::size_t n)
  {
    n = std::min<std::size_t>(n, epptr() - pptr());
    pbump(static_cast<int>(n));
    setg(eback(), gptr(), pptr());
  }
  /// Remove characters from the input sequence.
  /**
   * Removes @c n characters from the beginning of the input sequence.
   *
   * @note If @c n is greater than the size of the input sequence, the entire
   * input sequence is consumed and no error is issued.
   */
  void consume(std::size_t n)
  {
    if (egptr() < pptr())
      setg(&buffer_[0], gptr(), pptr());
    if (gptr() + n > pptr())
      n = pptr() - gptr();
    gbump(static_cast<int>(n));
  }
 protected:
  enum { buffer_delta = 128 };
  /// Override std::streambuf behaviour.
  /**
   * Behaves according to the specification of @c std::streambuf::underflow().
   */
  int_type underflow()
  {
    if (gptr() < pptr())
    {
      setg(&buffer_[0], gptr(), pptr());
      return traits_type::to_int_type(*gptr());
    }
    else
    {
      return traits_type::eof();
    }
  }
  /// Override std::streambuf behaviour.
  /**
   * Behaves according to the specification of @c std::streambuf::overflow(),
   * with the specialisation that @c std::length_error is thrown if appending
   * the character to the input sequence would require the condition
   * <tt>size() > max_size()</tt> to be true.
   */
  int_type overflow(int_type c)
  {
    if (!traits_type::eq_int_type(c, traits_type::eof()))
    {
      if (pptr() == epptr())
      {
        std::size_t buffer_size = pptr() - gptr();
        if (buffer_size < max_size_ && max_size_ - buffer_size < buffer_delta)
        {
          reserve(max_size_ - buffer_size);
        }
        else
        {
          reserve(buffer_delta);
        }
      }
      *pptr() = traits_type::to_char_type(c);
      pbump(1);
      return c;
    }
    return traits_type::not_eof(c);
  }
  void reserve(std::size_t n)
  {
    // Get current stream positions as offsets.
    std::size_t gnext = gptr() - &buffer_[0];
    std::size_t pnext = pptr() - &buffer_[0];
    std::size_t pend = epptr() - &buffer_[0];
    // Check if there is already enough space in the put area.
    if (n <= pend - pnext)
    {
      return;
    }
    // Shift existing contents of get area to start of buffer.
    if (gnext > 0)
    {
      pnext -= gnext;
      std::memmove(&buffer_[0], &buffer_[0] + gnext, pnext);
    }
    // Ensure buffer is large enough to hold at least the specified size.
    if (n > pend - pnext)
    {
      if (n <= max_size_ && pnext <= max_size_ - n)
      {
        pend = pnext + n;
        buffer_.resize((std::max<std::size_t>)(pend, 1));
      }
      else
      {
        std::length_error ex("asio::streambuf too long");
        asio::detail::throw_exception(ex);
      }
    }
    // Update stream positions.
    setg(&buffer_[0], &buffer_[0], &buffer_[0] + pnext);
    setp(&buffer_[0] + pnext, &buffer_[0] + pend);
  }
 private:
  std::size_t max_size_;
  std::vector<char_type, Allocator> buffer_;
  // Helper function to get the preferred size for reading data.
  friend std::size_t read_size_helper(
      basic_streambuf& sb, std::size_t max_size)
  {
    return std::min<std::size_t>(
        std::max<std::size_t>(512, sb.buffer_.capacity() - sb.size()),
        std::min<std::size_t>(max_size, sb.max_size() - sb.size()));
  }
 };
 /// Adapts basic_streambuf to the dynamic buffer sequence type requirements.
 #if defined(GENERATING_DOCUMENTATION)
 template <typename Allocator = std::allocator<char> >
 #else
 template <typename Allocator>
 #endif
 class basic_streambuf_ref
 {
 public:
  /// The type used to represent the input sequence as a list of buffers.
  typedef typename basic_streambuf<Allocator>::const_buffers_type
    const_buffers_type;
  /// The type used to represent the output sequence as a list of buffers.
  typedef typename basic_streambuf<Allocator>::mutable_buffers_type
    mutable_buffers_type;
  /// Construct a basic_streambuf_ref for the given basic_streambuf object.
  explicit basic_streambuf_ref(basic_streambuf<Allocator>& sb)
    : sb_(sb)
  {
  }
  /// Copy construct a basic_streambuf_ref.
  basic_streambuf_ref(const basic_streambuf_ref& other) ASIO_NOEXCEPT
    : sb_(other.sb_)
  {
  }
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Move construct a basic_streambuf_ref.
  basic_streambuf_ref(basic_streambuf_ref&& other) ASIO_NOEXCEPT
    : sb_(other.sb_)
  {
  }
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Get the size of the input sequence.
  std::size_t size() const ASIO_NOEXCEPT
  {
    return sb_.size();
  }
  /// Get the maximum size of the dynamic buffer.
  std::size_t max_size() const ASIO_NOEXCEPT
  {
    return sb_.max_size();
  }
  /// Get the current capacity of the dynamic buffer.
  std::size_t capacity() const ASIO_NOEXCEPT
  {
    return sb_.capacity();
  }
  /// Get a list of buffers that represents the input sequence.
  const_buffers_type data() const ASIO_NOEXCEPT
  {
    return sb_.data();
  }
  /// Get a list of buffers that represents the output sequence, with the given
  /// size.
  mutable_buffers_type prepare(std::size_t n)
  {
    return sb_.prepare(n);
  }
  /// Move bytes from the output sequence to the input sequence.
  void commit(std::size_t n)
  {
    return sb_.commit(n);
  }
  /// Remove characters from the input sequence.
  void consume(std::size_t n)
  {
    return sb_.consume(n);
  }
 private:
  basic_streambuf<Allocator>& sb_;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // !defined(ASIO_NO_IOSTREAM)
 #endif // ASIO_BASIC_STREAMBUF_HPP
--- a/module/Vendor/ASIO/include/asio/basic_streambuf_fwd.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_streambuf_fwd.hpp
@ -0,0 +1,36 @@
 //
 // basic_streambuf_fwd.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_STREAMBUF_FWD_HPP
 #define ASIO_BASIC_STREAMBUF_FWD_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if !defined(ASIO_NO_IOSTREAM)
 #include <memory>
 namespace asio {
 template <typename Allocator = std::allocator<char> >
 class basic_streambuf;
 template <typename Allocator = std::allocator<char> >
 class basic_streambuf_ref;
 } // namespace asio
 #endif // !defined(ASIO_NO_IOSTREAM)
 #endif // ASIO_BASIC_STREAMBUF_FWD_HPP
--- a/module/Vendor/ASIO/include/asio/basic_waitable_timer.hpp
+++ b/module/Vendor/ASIO/include/asio/basic_waitable_timer.hpp
@ -0,0 +1,811 @@
 //
 // basic_waitable_timer.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BASIC_WAITABLE_TIMER_HPP
 #define ASIO_BASIC_WAITABLE_TIMER_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include <cstddef>
 #include "asio/any_io_executor.hpp"
 #include "asio/detail/chrono_time_traits.hpp"
 #include "asio/detail/deadline_timer_service.hpp"
 #include "asio/detail/handler_type_requirements.hpp"
 #include "asio/detail/io_object_impl.hpp"
 #include "asio/detail/non_const_lvalue.hpp"
 #include "asio/detail/throw_error.hpp"
 #include "asio/error.hpp"
 #include "asio/wait_traits.hpp"
 #if defined(ASIO_HAS_MOVE)
 # include <utility>
 #endif // defined(ASIO_HAS_MOVE)
 #include "asio/detail/push_options.hpp"
 namespace asio {
 #if !defined(ASIO_BASIC_WAITABLE_TIMER_FWD_DECL)
 #define ASIO_BASIC_WAITABLE_TIMER_FWD_DECL
 // Forward declaration with defaulted arguments.
 template <typename Clock,
    typename WaitTraits = asio::wait_traits<Clock>,
    typename Executor = any_io_executor>
 class basic_waitable_timer;
 #endif // !defined(ASIO_BASIC_WAITABLE_TIMER_FWD_DECL)
 /// Provides waitable timer functionality.
 /**
 * The basic_waitable_timer class template provides the ability to perform a
 * blocking or asynchronous wait for a timer to expire.
 *
 * A waitable timer is always in one of two states: "expired" or "not expired".
 * If the wait() or async_wait() function is called on an expired timer, the
 * wait operation will complete immediately.
 *
 * Most applications will use one of the asio::steady_timer,
 * asio::system_timer or asio::high_resolution_timer typedefs.
 *
 * @note This waitable timer functionality is for use with the C++11 standard
 * library's @c &lt;chrono&gt; facility, or with the Boost.Chrono library.
 *
 * @par Thread Safety
 * @e Distinct @e objects: Safe.@n
 * @e Shared @e objects: Unsafe.
 *
 * @par Examples
 * Performing a blocking wait (C++11):
 * @code
 * // Construct a timer without setting an expiry time.
 * asio::steady_timer timer(my_context);
 *
 * // Set an expiry time relative to now.
 * timer.expires_after(std::chrono::seconds(5));
 *
 * // Wait for the timer to expire.
 * timer.wait();
 * @endcode
 *
 * @par 
 * Performing an asynchronous wait (C++11):
 * @code
 * void handler(const asio::error_code& error)
 * {
 *   if (!error)
 *   {
 *     // Timer expired.
 *   }
 * }
 *
 * ...
 *
 * // Construct a timer with an absolute expiry time.
 * asio::steady_timer timer(my_context,
 *     std::chrono::steady_clock::now() + std::chrono::seconds(60));
 *
 * // Start an asynchronous wait.
 * timer.async_wait(handler);
 * @endcode
 *
 * @par Changing an active waitable timer's expiry time
 *
 * Changing the expiry time of a timer while there are pending asynchronous
 * waits causes those wait operations to be cancelled. To ensure that the action
 * associated with the timer is performed only once, use something like this:
 * used:
 *
 * @code
 * void on_some_event()
 * {
 *   if (my_timer.expires_after(seconds(5)) > 0)
 *   {
 *     // We managed to cancel the timer. Start new asynchronous wait.
 *     my_timer.async_wait(on_timeout);
 *   }
 *   else
 *   {
 *     // Too late, timer has already expired!
 *   }
 * }
 *
 * void on_timeout(const asio::error_code& e)
 * {
 *   if (e != asio::error::operation_aborted)
 *   {
 *     // Timer was not cancelled, take necessary action.
 *   }
 * }
 * @endcode
 *
 * @li The asio::basic_waitable_timer::expires_after() function
 * cancels any pending asynchronous waits, and returns the number of
 * asynchronous waits that were cancelled. If it returns 0 then you were too
 * late and the wait handler has already been executed, or will soon be
 * executed. If it returns 1 then the wait handler was successfully cancelled.
 *
 * @li If a wait handler is cancelled, the asio::error_code passed to
 * it contains the value asio::error::operation_aborted.
 */
 template <typename Clock, typename WaitTraits, typename Executor>
 class basic_waitable_timer
 {
 public:
  /// The type of the executor associated with the object.
  typedef Executor executor_type;
  /// Rebinds the timer type to another executor.
  template <typename Executor1>
  struct rebind_executor
  {
    /// The timer type when rebound to the specified executor.
    typedef basic_waitable_timer<Clock, WaitTraits, Executor1> other;
  };
  /// The clock type.
  typedef Clock clock_type;
  /// The duration type of the clock.
  typedef typename clock_type::duration duration;
  /// The time point type of the clock.
  typedef typename clock_type::time_point time_point;
  /// The wait traits type.
  typedef WaitTraits traits_type;
  /// Constructor.
  /**
   * This constructor creates a timer without setting an expiry time. The
   * expires_at() or expires_after() functions must be called to set an expiry
   * time before the timer can be waited on.
   *
   * @param ex The I/O executor that the timer will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the timer.
   */
  explicit basic_waitable_timer(const executor_type& ex)
    : impl_(0, ex)
  {
  }
  /// Constructor.
  /**
   * This constructor creates a timer without setting an expiry time. The
   * expires_at() or expires_after() functions must be called to set an expiry
   * time before the timer can be waited on.
   *
   * @param context An execution context which provides the I/O executor that
   * the timer will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the timer.
   */
  template <typename ExecutionContext>
  explicit basic_waitable_timer(ExecutionContext& context,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
  }
  /// Constructor to set a particular expiry time as an absolute time.
  /**
   * This constructor creates a timer and sets the expiry time.
   *
   * @param ex The I/O executor object that the timer will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the timer.
   *
   * @param expiry_time The expiry time to be used for the timer, expressed
   * as an absolute time.
   */
  basic_waitable_timer(const executor_type& ex, const time_point& expiry_time)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().expires_at(impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_at");
  }
  /// Constructor to set a particular expiry time as an absolute time.
  /**
   * This constructor creates a timer and sets the expiry time.
   *
   * @param context An execution context which provides the I/O executor that
   * the timer will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the timer.
   *
   * @param expiry_time The expiry time to be used for the timer, expressed
   * as an absolute time.
   */
  template <typename ExecutionContext>
  explicit basic_waitable_timer(ExecutionContext& context,
      const time_point& expiry_time,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().expires_at(impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_at");
  }
  /// Constructor to set a particular expiry time relative to now.
  /**
   * This constructor creates a timer and sets the expiry time.
   *
   * @param ex The I/O executor that the timer will use, by default, to
   * dispatch handlers for any asynchronous operations performed on the timer.
   *
   * @param expiry_time The expiry time to be used for the timer, relative to
   * now.
   */
  basic_waitable_timer(const executor_type& ex, const duration& expiry_time)
    : impl_(0, ex)
  {
    asio::error_code ec;
    impl_.get_service().expires_after(
        impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_after");
  }
  /// Constructor to set a particular expiry time relative to now.
  /**
   * This constructor creates a timer and sets the expiry time.
   *
   * @param context An execution context which provides the I/O executor that
   * the timer will use, by default, to dispatch handlers for any asynchronous
   * operations performed on the timer.
   *
   * @param expiry_time The expiry time to be used for the timer, relative to
   * now.
   */
  template <typename ExecutionContext>
  explicit basic_waitable_timer(ExecutionContext& context,
      const duration& expiry_time,
      typename enable_if<
        is_convertible<ExecutionContext&, execution_context&>::value
      >::type* = 0)
    : impl_(0, 0, context)
  {
    asio::error_code ec;
    impl_.get_service().expires_after(
        impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_after");
  }
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Move-construct a basic_waitable_timer from another.
  /**
   * This constructor moves a timer from one object to another.
   *
   * @param other The other basic_waitable_timer object from which the move will
   * occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_waitable_timer(const executor_type&)
   * constructor.
   */
  basic_waitable_timer(basic_waitable_timer&& other)
    : impl_(std::move(other.impl_))
  {
  }
  /// Move-assign a basic_waitable_timer from another.
  /**
   * This assignment operator moves a timer from one object to another. Cancels
   * any outstanding asynchronous operations associated with the target object.
   *
   * @param other The other basic_waitable_timer object from which the move will
   * occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_waitable_timer(const executor_type&)
   * constructor.
   */
  basic_waitable_timer& operator=(basic_waitable_timer&& other)
  {
    impl_ = std::move(other.impl_);
    return *this;
  }
  // All timers have access to each other's implementations.
  template <typename Clock1, typename WaitTraits1, typename Executor1>
  friend class basic_waitable_timer;
  /// Move-construct a basic_waitable_timer from another.
  /**
   * This constructor moves a timer from one object to another.
   *
   * @param other The other basic_waitable_timer object from which the move will
   * occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_waitable_timer(const executor_type&)
   * constructor.
   */
  template <typename Executor1>
  basic_waitable_timer(
      basic_waitable_timer<Clock, WaitTraits, Executor1>&& other,
      typename enable_if<
          is_convertible<Executor1, Executor>::value
      >::type* = 0)
    : impl_(std::move(other.impl_))
  {
  }
  /// Move-assign a basic_waitable_timer from another.
  /**
   * This assignment operator moves a timer from one object to another. Cancels
   * any outstanding asynchronous operations associated with the target object.
   *
   * @param other The other basic_waitable_timer object from which the move will
   * occur.
   *
   * @note Following the move, the moved-from object is in the same state as if
   * constructed using the @c basic_waitable_timer(const executor_type&)
   * constructor.
   */
  template <typename Executor1>
  typename enable_if<
    is_convertible<Executor1, Executor>::value,
    basic_waitable_timer&
  >::type operator=(basic_waitable_timer<Clock, WaitTraits, Executor1>&& other)
  {
    basic_waitable_timer tmp(std::move(other));
    impl_ = std::move(tmp.impl_);
    return *this;
  }
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Destroys the timer.
  /**
   * This function destroys the timer, cancelling any outstanding asynchronous
   * wait operations associated with the timer as if by calling @c cancel.
   */
  ~basic_waitable_timer()
  {
  }
  /// Get the executor associated with the object.
  executor_type get_executor() ASIO_NOEXCEPT
  {
    return impl_.get_executor();
  }
  /// Cancel any asynchronous operations that are waiting on the timer.
  /**
   * This function forces the completion of any pending asynchronous wait
   * operations against the timer. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * Cancelling the timer does not change the expiry time.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If the timer has already expired when cancel() is called, then the
   * handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t cancel()
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().cancel(impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "cancel");
    return s;
  }
 #if !defined(ASIO_NO_DEPRECATED)
  /// (Deprecated: Use non-error_code overload.) Cancel any asynchronous
  /// operations that are waiting on the timer.
  /**
   * This function forces the completion of any pending asynchronous wait
   * operations against the timer. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * Cancelling the timer does not change the expiry time.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @note If the timer has already expired when cancel() is called, then the
   * handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t cancel(asio::error_code& ec)
  {
    return impl_.get_service().cancel(impl_.get_implementation(), ec);
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
  /// Cancels one asynchronous operation that is waiting on the timer.
  /**
   * This function forces the completion of one pending asynchronous wait
   * operation against the timer. Handlers are cancelled in FIFO order. The
   * handler for the cancelled operation will be invoked with the
   * asio::error::operation_aborted error code.
   *
   * Cancelling the timer does not change the expiry time.
   *
   * @return The number of asynchronous operations that were cancelled. That is,
   * either 0 or 1.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If the timer has already expired when cancel_one() is called, then
   * the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t cancel_one()
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().cancel_one(
        impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "cancel_one");
    return s;
  }
 #if !defined(ASIO_NO_DEPRECATED)
  /// (Deprecated: Use non-error_code overload.) Cancels one asynchronous
  /// operation that is waiting on the timer.
  /**
   * This function forces the completion of one pending asynchronous wait
   * operation against the timer. Handlers are cancelled in FIFO order. The
   * handler for the cancelled operation will be invoked with the
   * asio::error::operation_aborted error code.
   *
   * Cancelling the timer does not change the expiry time.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @return The number of asynchronous operations that were cancelled. That is,
   * either 0 or 1.
   *
   * @note If the timer has already expired when cancel_one() is called, then
   * the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t cancel_one(asio::error_code& ec)
  {
    return impl_.get_service().cancel_one(impl_.get_implementation(), ec);
  }
  /// (Deprecated: Use expiry().) Get the timer's expiry time as an absolute
  /// time.
  /**
   * This function may be used to obtain the timer's current expiry time.
   * Whether the timer has expired or not does not affect this value.
   */
  time_point expires_at() const
  {
    return impl_.get_service().expires_at(impl_.get_implementation());
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
  /// Get the timer's expiry time as an absolute time.
  /**
   * This function may be used to obtain the timer's current expiry time.
   * Whether the timer has expired or not does not affect this value.
   */
  time_point expiry() const
  {
    return impl_.get_service().expiry(impl_.get_implementation());
  }
  /// Set the timer's expiry time as an absolute time.
  /**
   * This function sets the expiry time. Any pending asynchronous wait
   * operations will be cancelled. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * @param expiry_time The expiry time to be used for the timer.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If the timer has already expired when expires_at() is called, then
   * the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t expires_at(const time_point& expiry_time)
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().expires_at(
        impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_at");
    return s;
  }
 #if !defined(ASIO_NO_DEPRECATED)
  /// (Deprecated: Use non-error_code overload.) Set the timer's expiry time as
  /// an absolute time.
  /**
   * This function sets the expiry time. Any pending asynchronous wait
   * operations will be cancelled. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * @param expiry_time The expiry time to be used for the timer.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @note If the timer has already expired when expires_at() is called, then
   * the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t expires_at(const time_point& expiry_time,
      asio::error_code& ec)
  {
    return impl_.get_service().expires_at(
        impl_.get_implementation(), expiry_time, ec);
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
  /// Set the timer's expiry time relative to now.
  /**
   * This function sets the expiry time. Any pending asynchronous wait
   * operations will be cancelled. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * @param expiry_time The expiry time to be used for the timer.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If the timer has already expired when expires_after() is called,
   * then the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t expires_after(const duration& expiry_time)
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().expires_after(
        impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_after");
    return s;
  }
 #if !defined(ASIO_NO_DEPRECATED)
  /// (Deprecated: Use expiry().) Get the timer's expiry time relative to now.
  /**
   * This function may be used to obtain the timer's current expiry time.
   * Whether the timer has expired or not does not affect this value.
   */
  duration expires_from_now() const
  {
    return impl_.get_service().expires_from_now(impl_.get_implementation());
  }
  /// (Deprecated: Use expires_after().) Set the timer's expiry time relative
  /// to now.
  /**
   * This function sets the expiry time. Any pending asynchronous wait
   * operations will be cancelled. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * @param expiry_time The expiry time to be used for the timer.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @throws asio::system_error Thrown on failure.
   *
   * @note If the timer has already expired when expires_from_now() is called,
   * then the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t expires_from_now(const duration& expiry_time)
  {
    asio::error_code ec;
    std::size_t s = impl_.get_service().expires_from_now(
        impl_.get_implementation(), expiry_time, ec);
    asio::detail::throw_error(ec, "expires_from_now");
    return s;
  }
  /// (Deprecated: Use expires_after().) Set the timer's expiry time relative
  /// to now.
  /**
   * This function sets the expiry time. Any pending asynchronous wait
   * operations will be cancelled. The handler for each cancelled operation will
   * be invoked with the asio::error::operation_aborted error code.
   *
   * @param expiry_time The expiry time to be used for the timer.
   *
   * @param ec Set to indicate what error occurred, if any.
   *
   * @return The number of asynchronous operations that were cancelled.
   *
   * @note If the timer has already expired when expires_from_now() is called,
   * then the handlers for asynchronous wait operations will:
   *
   * @li have already been invoked; or
   *
   * @li have been queued for invocation in the near future.
   *
   * These handlers can no longer be cancelled, and therefore are passed an
   * error code that indicates the successful completion of the wait operation.
   */
  std::size_t expires_from_now(const duration& expiry_time,
      asio::error_code& ec)
  {
    return impl_.get_service().expires_from_now(
        impl_.get_implementation(), expiry_time, ec);
  }
 #endif // !defined(ASIO_NO_DEPRECATED)
  /// Perform a blocking wait on the timer.
  /**
   * This function is used to wait for the timer to expire. This function
   * blocks and does not return until the timer has expired.
   *
   * @throws asio::system_error Thrown on failure.
   */
  void wait()
  {
    asio::error_code ec;
    impl_.get_service().wait(impl_.get_implementation(), ec);
    asio::detail::throw_error(ec, "wait");
  }
  /// Perform a blocking wait on the timer.
  /**
   * This function is used to wait for the timer to expire. This function
   * blocks and does not return until the timer has expired.
   *
   * @param ec Set to indicate what error occurred, if any.
   */
  void wait(asio::error_code& ec)
  {
    impl_.get_service().wait(impl_.get_implementation(), ec);
  }
  /// Start an asynchronous wait on the timer.
  /**
   * This function may be used to initiate an asynchronous wait against the
   * timer. It always returns immediately.
   *
   * For each call to async_wait(), the supplied handler will be called exactly
   * once. The handler will be called when:
   *
   * @li The timer has expired.
   *
   * @li The timer was cancelled, in which case the handler is passed the error
   * code asio::error::operation_aborted.
   *
   * @param handler The handler to be called when the timer expires. Copies
   * will be made of the handler as required. The function signature of the
   * handler must be:
   * @code void handler(
   *   const asio::error_code& error // Result of operation.
   * ); @endcode
   * Regardless of whether the asynchronous operation completes immediately or
   * not, the handler will not be invoked from within this function. On
   * immediate completion, invocation of the handler will be performed in a
   * manner equivalent to using asio::post().
   */
  template <
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code))
        WaitHandler ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(WaitHandler,
      void (asio::error_code))
  async_wait(
      ASIO_MOVE_ARG(WaitHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return async_initiate<WaitHandler, void (asio::error_code)>(
        initiate_async_wait(this), handler);
  }
 private:
  // Disallow copying and assignment.
  basic_waitable_timer(const basic_waitable_timer&) ASIO_DELETED;
  basic_waitable_timer& operator=(
      const basic_waitable_timer&) ASIO_DELETED;
  class initiate_async_wait
  {
  public:
    typedef Executor executor_type;
    explicit initiate_async_wait(basic_waitable_timer* self)
      : self_(self)
    {
    }
    executor_type get_executor() const ASIO_NOEXCEPT
    {
      return self_->get_executor();
    }
    template <typename WaitHandler>
    void operator()(ASIO_MOVE_ARG(WaitHandler) handler) const
    {
      // If you get an error on the following line it means that your handler
      // does not meet the documented type requirements for a WaitHandler.
      ASIO_WAIT_HANDLER_CHECK(WaitHandler, handler) type_check;
      detail::non_const_lvalue<WaitHandler> handler2(handler);
      self_->impl_.get_service().async_wait(
          self_->impl_.get_implementation(),
          handler2.value, self_->impl_.get_executor());
    }
  private:
    basic_waitable_timer* self_;
  };
  detail::io_object_impl<
    detail::deadline_timer_service<
      detail::chrono_time_traits<Clock, WaitTraits> >,
    executor_type > impl_;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_BASIC_WAITABLE_TIMER_HPP
--- a/module/Vendor/ASIO/include/asio/bind_executor.hpp
+++ b/module/Vendor/ASIO/include/asio/bind_executor.hpp
@ -0,0 +1,575 @@
 //
 // bind_executor.hpp
 // ~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BIND_EXECUTOR_HPP
 #define ASIO_BIND_EXECUTOR_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/detail/variadic_templates.hpp"
 #include "asio/associated_executor.hpp"
 #include "asio/associated_allocator.hpp"
 #include "asio/async_result.hpp"
 #include "asio/execution/executor.hpp"
 #include "asio/execution_context.hpp"
 #include "asio/is_executor.hpp"
 #include "asio/uses_executor.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 // Helper to automatically define nested typedef result_type.
 template <typename T, typename = void>
 struct executor_binder_result_type
 {
 protected:
  typedef void result_type_or_void;
 };
 template <typename T>
 struct executor_binder_result_type<T,
  typename void_type<typename T::result_type>::type>
 {
  typedef typename T::result_type result_type;
 protected:
  typedef result_type result_type_or_void;
 };
 template <typename R>
 struct executor_binder_result_type<R(*)()>
 {
  typedef R result_type;
 protected:
  typedef result_type result_type_or_void;
 };
 template <typename R>
 struct executor_binder_result_type<R(&)()>
 {
  typedef R result_type;
 protected:
  typedef result_type result_type_or_void;
 };
 template <typename R, typename A1>
 struct executor_binder_result_type<R(*)(A1)>
 {
  typedef R result_type;
 protected:
  typedef result_type result_type_or_void;
 };
 template <typename R, typename A1>
 struct executor_binder_result_type<R(&)(A1)>
 {
  typedef R result_type;
 protected:
  typedef result_type result_type_or_void;
 };
 template <typename R, typename A1, typename A2>
 struct executor_binder_result_type<R(*)(A1, A2)>
 {
  typedef R result_type;
 protected:
  typedef result_type result_type_or_void;
 };
 template <typename R, typename A1, typename A2>
 struct executor_binder_result_type<R(&)(A1, A2)>
 {
  typedef R result_type;
 protected:
  typedef result_type result_type_or_void;
 };
 // Helper to automatically define nested typedef argument_type.
 template <typename T, typename = void>
 struct executor_binder_argument_type {};
 template <typename T>
 struct executor_binder_argument_type<T,
  typename void_type<typename T::argument_type>::type>
 {
  typedef typename T::argument_type argument_type;
 };
 template <typename R, typename A1>
 struct executor_binder_argument_type<R(*)(A1)>
 {
  typedef A1 argument_type;
 };
 template <typename R, typename A1>
 struct executor_binder_argument_type<R(&)(A1)>
 {
  typedef A1 argument_type;
 };
 // Helper to automatically define nested typedefs first_argument_type and
 // second_argument_type.
 template <typename T, typename = void>
 struct executor_binder_argument_types {};
 template <typename T>
 struct executor_binder_argument_types<T,
  typename void_type<typename T::first_argument_type>::type>
 {
  typedef typename T::first_argument_type first_argument_type;
  typedef typename T::second_argument_type second_argument_type;
 };
 template <typename R, typename A1, typename A2>
 struct executor_binder_argument_type<R(*)(A1, A2)>
 {
  typedef A1 first_argument_type;
  typedef A2 second_argument_type;
 };
 template <typename R, typename A1, typename A2>
 struct executor_binder_argument_type<R(&)(A1, A2)>
 {
  typedef A1 first_argument_type;
  typedef A2 second_argument_type;
 };
 // Helper to perform uses_executor construction of the target type, if
 // required.
 template <typename T, typename Executor, bool UsesExecutor>
 class executor_binder_base;
 template <typename T, typename Executor>
 class executor_binder_base<T, Executor, true>
 {
 protected:
  template <typename E, typename U>
  executor_binder_base(ASIO_MOVE_ARG(E) e, ASIO_MOVE_ARG(U) u)
    : executor_(ASIO_MOVE_CAST(E)(e)),
      target_(executor_arg_t(), executor_, ASIO_MOVE_CAST(U)(u))
  {
  }
  Executor executor_;
  T target_;
 };
 template <typename T, typename Executor>
 class executor_binder_base<T, Executor, false>
 {
 protected:
  template <typename E, typename U>
  executor_binder_base(ASIO_MOVE_ARG(E) e, ASIO_MOVE_ARG(U) u)
    : executor_(ASIO_MOVE_CAST(E)(e)),
      target_(ASIO_MOVE_CAST(U)(u))
  {
  }
  Executor executor_;
  T target_;
 };
 // Helper to enable SFINAE on zero-argument operator() below.
 template <typename T, typename = void>
 struct executor_binder_result_of0
 {
  typedef void type;
 };
 template <typename T>
 struct executor_binder_result_of0<T,
  typename void_type<typename result_of<T()>::type>::type>
 {
  typedef typename result_of<T()>::type type;
 };
 } // namespace detail
 /// A call wrapper type to bind an executor of type @c Executor to an object of
 /// type @c T.
 template <typename T, typename Executor>
 class executor_binder
 #if !defined(GENERATING_DOCUMENTATION)
  : public detail::executor_binder_result_type<T>,
    public detail::executor_binder_argument_type<T>,
    public detail::executor_binder_argument_types<T>,
    private detail::executor_binder_base<
      T, Executor, uses_executor<T, Executor>::value>
 #endif // !defined(GENERATING_DOCUMENTATION)
 {
 public:
  /// The type of the target object.
  typedef T target_type;
  /// The type of the associated executor.
  typedef Executor executor_type;
 #if defined(GENERATING_DOCUMENTATION)
  /// The return type if a function.
  /**
   * The type of @c result_type is based on the type @c T of the wrapper's
   * target object:
   *
   * @li if @c T is a pointer to function type, @c result_type is a synonym for
   * the return type of @c T;
   *
   * @li if @c T is a class type with a member type @c result_type, then @c
   * result_type is a synonym for @c T::result_type;
   *
   * @li otherwise @c result_type is not defined.
   */
  typedef see_below result_type;
  /// The type of the function's argument.
  /**
   * The type of @c argument_type is based on the type @c T of the wrapper's
   * target object:
   *
   * @li if @c T is a pointer to a function type accepting a single argument,
   * @c argument_type is a synonym for the return type of @c T;
   *
   * @li if @c T is a class type with a member type @c argument_type, then @c
   * argument_type is a synonym for @c T::argument_type;
   *
   * @li otherwise @c argument_type is not defined.
   */
  typedef see_below argument_type;
  /// The type of the function's first argument.
  /**
   * The type of @c first_argument_type is based on the type @c T of the
   * wrapper's target object:
   *
   * @li if @c T is a pointer to a function type accepting two arguments, @c
   * first_argument_type is a synonym for the return type of @c T;
   *
   * @li if @c T is a class type with a member type @c first_argument_type,
   * then @c first_argument_type is a synonym for @c T::first_argument_type;
   *
   * @li otherwise @c first_argument_type is not defined.
   */
  typedef see_below first_argument_type;
  /// The type of the function's second argument.
  /**
   * The type of @c second_argument_type is based on the type @c T of the
   * wrapper's target object:
   *
   * @li if @c T is a pointer to a function type accepting two arguments, @c
   * second_argument_type is a synonym for the return type of @c T;
   *
   * @li if @c T is a class type with a member type @c first_argument_type,
   * then @c second_argument_type is a synonym for @c T::second_argument_type;
   *
   * @li otherwise @c second_argument_type is not defined.
   */
  typedef see_below second_argument_type;
 #endif // defined(GENERATING_DOCUMENTATION)
  /// Construct an executor wrapper for the specified object.
  /**
   * This constructor is only valid if the type @c T is constructible from type
   * @c U.
   */
  template <typename U>
  executor_binder(executor_arg_t, const executor_type& e,
      ASIO_MOVE_ARG(U) u)
    : base_type(e, ASIO_MOVE_CAST(U)(u))
  {
  }
  /// Copy constructor.
  executor_binder(const executor_binder& other)
    : base_type(other.get_executor(), other.get())
  {
  }
  /// Construct a copy, but specify a different executor.
  executor_binder(executor_arg_t, const executor_type& e,
      const executor_binder& other)
    : base_type(e, other.get())
  {
  }
  /// Construct a copy of a different executor wrapper type.
  /**
   * This constructor is only valid if the @c Executor type is constructible
   * from type @c OtherExecutor, and the type @c T is constructible from type
   * @c U.
   */
  template <typename U, typename OtherExecutor>
  executor_binder(const executor_binder<U, OtherExecutor>& other)
    : base_type(other.get_executor(), other.get())
  {
  }
  /// Construct a copy of a different executor wrapper type, but specify a
  /// different executor.
  /**
   * This constructor is only valid if the type @c T is constructible from type
   * @c U.
   */
  template <typename U, typename OtherExecutor>
  executor_binder(executor_arg_t, const executor_type& e,
      const executor_binder<U, OtherExecutor>& other)
    : base_type(e, other.get())
  {
  }
 #if defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Move constructor.
  executor_binder(executor_binder&& other)
    : base_type(ASIO_MOVE_CAST(executor_type)(other.get_executor()),
        ASIO_MOVE_CAST(T)(other.get()))
  {
  }
  /// Move construct the target object, but specify a different executor.
  executor_binder(executor_arg_t, const executor_type& e,
      executor_binder&& other)
    : base_type(e, ASIO_MOVE_CAST(T)(other.get()))
  {
  }
  /// Move construct from a different executor wrapper type.
  template <typename U, typename OtherExecutor>
  executor_binder(executor_binder<U, OtherExecutor>&& other)
    : base_type(ASIO_MOVE_CAST(OtherExecutor)(other.get_executor()),
        ASIO_MOVE_CAST(U)(other.get()))
  {
  }
  /// Move construct from a different executor wrapper type, but specify a
  /// different executor.
  template <typename U, typename OtherExecutor>
  executor_binder(executor_arg_t, const executor_type& e,
      executor_binder<U, OtherExecutor>&& other)
    : base_type(e, ASIO_MOVE_CAST(U)(other.get()))
  {
  }
 #endif // defined(ASIO_HAS_MOVE) || defined(GENERATING_DOCUMENTATION)
  /// Destructor.
  ~executor_binder()
  {
  }
  /// Obtain a reference to the target object.
  target_type& get() ASIO_NOEXCEPT
  {
    return this->target_;
  }
  /// Obtain a reference to the target object.
  const target_type& get() const ASIO_NOEXCEPT
  {
    return this->target_;
  }
  /// Obtain the associated executor.
  executor_type get_executor() const ASIO_NOEXCEPT
  {
    return this->executor_;
  }
 #if defined(GENERATING_DOCUMENTATION)
  template <typename... Args> auto operator()(Args&& ...);
  template <typename... Args> auto operator()(Args&& ...) const;
 #elif defined(ASIO_HAS_VARIADIC_TEMPLATES)
  /// Forwarding function call operator.
  template <typename... Args>
  typename result_of<T(Args...)>::type operator()(
      ASIO_MOVE_ARG(Args)... args)
  {
    return this->target_(ASIO_MOVE_CAST(Args)(args)...);
  }
  /// Forwarding function call operator.
  template <typename... Args>
  typename result_of<T(Args...)>::type operator()(
      ASIO_MOVE_ARG(Args)... args) const
  {
    return this->target_(ASIO_MOVE_CAST(Args)(args)...);
  }
 #elif defined(ASIO_HAS_STD_TYPE_TRAITS) && !defined(_MSC_VER)
  typename detail::executor_binder_result_of0<T>::type operator()()
  {
    return this->target_();
  }
  typename detail::executor_binder_result_of0<T>::type operator()() const
  {
    return this->target_();
  }
 #define ASIO_PRIVATE_BIND_EXECUTOR_CALL_DEF(n) \
  template <ASIO_VARIADIC_TPARAMS(n)> \
  typename result_of<T(ASIO_VARIADIC_TARGS(n))>::type operator()( \
      ASIO_VARIADIC_MOVE_PARAMS(n)) \
  { \
    return this->target_(ASIO_VARIADIC_MOVE_ARGS(n)); \
  } \
  \
  template <ASIO_VARIADIC_TPARAMS(n)> \
  typename result_of<T(ASIO_VARIADIC_TARGS(n))>::type operator()( \
      ASIO_VARIADIC_MOVE_PARAMS(n)) const \
  { \
    return this->target_(ASIO_VARIADIC_MOVE_ARGS(n)); \
  } \
  /**/
  ASIO_VARIADIC_GENERATE(ASIO_PRIVATE_BIND_EXECUTOR_CALL_DEF)
 #undef ASIO_PRIVATE_BIND_EXECUTOR_CALL_DEF
 #else // defined(ASIO_HAS_STD_TYPE_TRAITS) && !defined(_MSC_VER)
  typedef typename detail::executor_binder_result_type<T>::result_type_or_void
    result_type_or_void;
  result_type_or_void operator()()
  {
    return this->target_();
  }
  result_type_or_void operator()() const
  {
    return this->target_();
  }
 #define ASIO_PRIVATE_BIND_EXECUTOR_CALL_DEF(n) \
  template <ASIO_VARIADIC_TPARAMS(n)> \
  result_type_or_void operator()( \
      ASIO_VARIADIC_MOVE_PARAMS(n)) \
  { \
    return this->target_(ASIO_VARIADIC_MOVE_ARGS(n)); \
  } \
  \
  template <ASIO_VARIADIC_TPARAMS(n)> \
  result_type_or_void operator()( \
      ASIO_VARIADIC_MOVE_PARAMS(n)) const \
  { \
    return this->target_(ASIO_VARIADIC_MOVE_ARGS(n)); \
  } \
  /**/
  ASIO_VARIADIC_GENERATE(ASIO_PRIVATE_BIND_EXECUTOR_CALL_DEF)
 #undef ASIO_PRIVATE_BIND_EXECUTOR_CALL_DEF
 #endif // defined(ASIO_HAS_STD_TYPE_TRAITS) && !defined(_MSC_VER)
 private:
  typedef detail::executor_binder_base<T, Executor,
    uses_executor<T, Executor>::value> base_type;
 };
 /// Associate an object of type @c T with an executor of type @c Executor.
 template <typename Executor, typename T>
 inline executor_binder<typename decay<T>::type, Executor>
 bind_executor(const Executor& ex, ASIO_MOVE_ARG(T) t,
    typename enable_if<
      is_executor<Executor>::value || execution::is_executor<Executor>::value
    >::type* = 0)
 {
  return executor_binder<typename decay<T>::type, Executor>(
      executor_arg_t(), ex, ASIO_MOVE_CAST(T)(t));
 }
 /// Associate an object of type @c T with an execution context's executor.
 template <typename ExecutionContext, typename T>
 inline executor_binder<typename decay<T>::type,
  typename ExecutionContext::executor_type>
 bind_executor(ExecutionContext& ctx, ASIO_MOVE_ARG(T) t,
    typename enable_if<is_convertible<
      ExecutionContext&, execution_context&>::value>::type* = 0)
 {
  return executor_binder<typename decay<T>::type,
    typename ExecutionContext::executor_type>(
      executor_arg_t(), ctx.get_executor(), ASIO_MOVE_CAST(T)(t));
 }
 #if !defined(GENERATING_DOCUMENTATION)
 template <typename T, typename Executor>
 struct uses_executor<executor_binder<T, Executor>, Executor>
  : true_type {};
 template <typename T, typename Executor, typename Signature>
 class async_result<executor_binder<T, Executor>, Signature>
 {
 public:
  typedef executor_binder<
    typename async_result<T, Signature>::completion_handler_type, Executor>
      completion_handler_type;
  typedef typename async_result<T, Signature>::return_type return_type;
  explicit async_result(executor_binder<T, Executor>& b)
    : target_(b.get())
  {
  }
  return_type get()
  {
    return target_.get();
  }
 private:
  async_result(const async_result&) ASIO_DELETED;
  async_result& operator=(const async_result&) ASIO_DELETED;
  async_result<T, Signature> target_;
 };
 template <typename T, typename Executor, typename Allocator>
 struct associated_allocator<executor_binder<T, Executor>, Allocator>
 {
  typedef typename associated_allocator<T, Allocator>::type type;
  static type get(const executor_binder<T, Executor>& b,
      const Allocator& a = Allocator()) ASIO_NOEXCEPT
  {
    return associated_allocator<T, Allocator>::get(b.get(), a);
  }
 };
 template <typename T, typename Executor, typename Executor1>
 struct associated_executor<executor_binder<T, Executor>, Executor1>
 {
  typedef Executor type;
  static type get(const executor_binder<T, Executor>& b,
      const Executor1& = Executor1()) ASIO_NOEXCEPT
  {
    return b.get_executor();
  }
 };
 #endif // !defined(GENERATING_DOCUMENTATION)
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_BIND_EXECUTOR_HPP
--- a/module/Vendor/ASIO/include/asio/buffer.hpp
+++ b/module/Vendor/ASIO/include/asio/buffer.hpp
--- a/module/Vendor/ASIO/include/asio/buffered_read_stream.hpp
+++ b/module/Vendor/ASIO/include/asio/buffered_read_stream.hpp
@ -0,0 +1,253 @@
 //
 // buffered_read_stream.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BUFFERED_READ_STREAM_HPP
 #define ASIO_BUFFERED_READ_STREAM_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include <cstddef>
 #include "asio/async_result.hpp"
 #include "asio/buffered_read_stream_fwd.hpp"
 #include "asio/buffer.hpp"
 #include "asio/detail/bind_handler.hpp"
 #include "asio/detail/buffer_resize_guard.hpp"
 #include "asio/detail/buffered_stream_storage.hpp"
 #include "asio/detail/noncopyable.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/error.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 /// Adds buffering to the read-related operations of a stream.
 /**
 * The buffered_read_stream class template can be used to add buffering to the
 * synchronous and asynchronous read operations of a stream.
 *
 * @par Thread Safety
 * @e Distinct @e objects: Safe.@n
 * @e Shared @e objects: Unsafe.
 *
 * @par Concepts:
 * AsyncReadStream, AsyncWriteStream, Stream, SyncReadStream, SyncWriteStream.
 */
 template <typename Stream>
 class buffered_read_stream
  : private noncopyable
 {
 public:
  /// The type of the next layer.
  typedef typename remove_reference<Stream>::type next_layer_type;
  /// The type of the lowest layer.
  typedef typename next_layer_type::lowest_layer_type lowest_layer_type;
  /// The type of the executor associated with the object.
  typedef typename lowest_layer_type::executor_type executor_type;
 #if defined(GENERATING_DOCUMENTATION)
  /// The default buffer size.
  static const std::size_t default_buffer_size = implementation_defined;
 #else
  ASIO_STATIC_CONSTANT(std::size_t, default_buffer_size = 1024);
 #endif
  /// Construct, passing the specified argument to initialise the next layer.
  template <typename Arg>
  explicit buffered_read_stream(Arg& a)
    : next_layer_(a),
      storage_(default_buffer_size)
  {
  }
  /// Construct, passing the specified argument to initialise the next layer.
  template <typename Arg>
  buffered_read_stream(Arg& a, std::size_t buffer_size)
    : next_layer_(a),
      storage_(buffer_size)
  {
  }
  /// Get a reference to the next layer.
  next_layer_type& next_layer()
  {
    return next_layer_;
  }
  /// Get a reference to the lowest layer.
  lowest_layer_type& lowest_layer()
  {
    return next_layer_.lowest_layer();
  }
  /// Get a const reference to the lowest layer.
  const lowest_layer_type& lowest_layer() const
  {
    return next_layer_.lowest_layer();
  }
  /// Get the executor associated with the object.
  executor_type get_executor() ASIO_NOEXCEPT
  {
    return next_layer_.lowest_layer().get_executor();
  }
  /// Close the stream.
  void close()
  {
    next_layer_.close();
  }
  /// Close the stream.
  ASIO_SYNC_OP_VOID close(asio::error_code& ec)
  {
    next_layer_.close(ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Write the given data to the stream. Returns the number of bytes written.
  /// Throws an exception on failure.
  template <typename ConstBufferSequence>
  std::size_t write_some(const ConstBufferSequence& buffers)
  {
    return next_layer_.write_some(buffers);
  }
  /// Write the given data to the stream. Returns the number of bytes written,
  /// or 0 if an error occurred.
  template <typename ConstBufferSequence>
  std::size_t write_some(const ConstBufferSequence& buffers,
      asio::error_code& ec)
  {
    return next_layer_.write_some(buffers, ec);
  }
  /// Start an asynchronous write. The data being written must be valid for the
  /// lifetime of the asynchronous operation.
  template <typename ConstBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) WriteHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(WriteHandler,
      void (asio::error_code, std::size_t))
  async_write_some(const ConstBufferSequence& buffers,
      ASIO_MOVE_ARG(WriteHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return next_layer_.async_write_some(buffers,
        ASIO_MOVE_CAST(WriteHandler)(handler));
  }
  /// Fill the buffer with some data. Returns the number of bytes placed in the
  /// buffer as a result of the operation. Throws an exception on failure.
  std::size_t fill();
  /// Fill the buffer with some data. Returns the number of bytes placed in the
  /// buffer as a result of the operation, or 0 if an error occurred.
  std::size_t fill(asio::error_code& ec);
  /// Start an asynchronous fill.
  template <
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) ReadHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(ReadHandler,
      void (asio::error_code, std::size_t))
  async_fill(
      ASIO_MOVE_ARG(ReadHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type));
  /// Read some data from the stream. Returns the number of bytes read. Throws
  /// an exception on failure.
  template <typename MutableBufferSequence>
  std::size_t read_some(const MutableBufferSequence& buffers);
  /// Read some data from the stream. Returns the number of bytes read or 0 if
  /// an error occurred.
  template <typename MutableBufferSequence>
  std::size_t read_some(const MutableBufferSequence& buffers,
      asio::error_code& ec);
  /// Start an asynchronous read. The buffer into which the data will be read
  /// must be valid for the lifetime of the asynchronous operation.
  template <typename MutableBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) ReadHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(ReadHandler,
      void (asio::error_code, std::size_t))
  async_read_some(const MutableBufferSequence& buffers,
      ASIO_MOVE_ARG(ReadHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type));
  /// Peek at the incoming data on the stream. Returns the number of bytes read.
  /// Throws an exception on failure.
  template <typename MutableBufferSequence>
  std::size_t peek(const MutableBufferSequence& buffers);
  /// Peek at the incoming data on the stream. Returns the number of bytes read,
  /// or 0 if an error occurred.
  template <typename MutableBufferSequence>
  std::size_t peek(const MutableBufferSequence& buffers,
      asio::error_code& ec);
  /// Determine the amount of data that may be read without blocking.
  std::size_t in_avail()
  {
    return storage_.size();
  }
  /// Determine the amount of data that may be read without blocking.
  std::size_t in_avail(asio::error_code& ec)
  {
    ec = asio::error_code();
    return storage_.size();
  }
 private:
  /// Copy data out of the internal buffer to the specified target buffer.
  /// Returns the number of bytes copied.
  template <typename MutableBufferSequence>
  std::size_t copy(const MutableBufferSequence& buffers)
  {
    std::size_t bytes_copied = asio::buffer_copy(
        buffers, storage_.data(), storage_.size());
    storage_.consume(bytes_copied);
    return bytes_copied;
  }
  /// Copy data from the internal buffer to the specified target buffer, without
  /// removing the data from the internal buffer. Returns the number of bytes
  /// copied.
  template <typename MutableBufferSequence>
  std::size_t peek_copy(const MutableBufferSequence& buffers)
  {
    return asio::buffer_copy(buffers, storage_.data(), storage_.size());
  }
  /// The next layer.
  Stream next_layer_;
  // The data in the buffer.
  detail::buffered_stream_storage storage_;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #include "asio/impl/buffered_read_stream.hpp"
 #endif // ASIO_BUFFERED_READ_STREAM_HPP
--- a/module/Vendor/ASIO/include/asio/buffered_read_stream_fwd.hpp
+++ b/module/Vendor/ASIO/include/asio/buffered_read_stream_fwd.hpp
@ -0,0 +1,25 @@
 //
 // buffered_read_stream_fwd.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BUFFERED_READ_STREAM_FWD_HPP
 #define ASIO_BUFFERED_READ_STREAM_FWD_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 namespace asio {
 template <typename Stream>
 class buffered_read_stream;
 } // namespace asio
 #endif // ASIO_BUFFERED_READ_STREAM_FWD_HPP
--- a/module/Vendor/ASIO/include/asio/buffered_stream.hpp
+++ b/module/Vendor/ASIO/include/asio/buffered_stream.hpp
@ -0,0 +1,279 @@
 //
 // buffered_stream.hpp
 // ~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BUFFERED_STREAM_HPP
 #define ASIO_BUFFERED_STREAM_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include <cstddef>
 #include "asio/async_result.hpp"
 #include "asio/buffered_read_stream.hpp"
 #include "asio/buffered_write_stream.hpp"
 #include "asio/buffered_stream_fwd.hpp"
 #include "asio/detail/noncopyable.hpp"
 #include "asio/error.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 /// Adds buffering to the read- and write-related operations of a stream.
 /**
 * The buffered_stream class template can be used to add buffering to the
 * synchronous and asynchronous read and write operations of a stream.
 *
 * @par Thread Safety
 * @e Distinct @e objects: Safe.@n
 * @e Shared @e objects: Unsafe.
 *
 * @par Concepts:
 * AsyncReadStream, AsyncWriteStream, Stream, SyncReadStream, SyncWriteStream.
 */
 template <typename Stream>
 class buffered_stream
  : private noncopyable
 {
 public:
  /// The type of the next layer.
  typedef typename remove_reference<Stream>::type next_layer_type;
  /// The type of the lowest layer.
  typedef typename next_layer_type::lowest_layer_type lowest_layer_type;
  /// The type of the executor associated with the object.
  typedef typename lowest_layer_type::executor_type executor_type;
  /// Construct, passing the specified argument to initialise the next layer.
  template <typename Arg>
  explicit buffered_stream(Arg& a)
    : inner_stream_impl_(a),
      stream_impl_(inner_stream_impl_)
  {
  }
  /// Construct, passing the specified argument to initialise the next layer.
  template <typename Arg>
  explicit buffered_stream(Arg& a, std::size_t read_buffer_size,
      std::size_t write_buffer_size)
    : inner_stream_impl_(a, write_buffer_size),
      stream_impl_(inner_stream_impl_, read_buffer_size)
  {
  }
  /// Get a reference to the next layer.
  next_layer_type& next_layer()
  {
    return stream_impl_.next_layer().next_layer();
  }
  /// Get a reference to the lowest layer.
  lowest_layer_type& lowest_layer()
  {
    return stream_impl_.lowest_layer();
  }
  /// Get a const reference to the lowest layer.
  const lowest_layer_type& lowest_layer() const
  {
    return stream_impl_.lowest_layer();
  }
  /// Get the executor associated with the object.
  executor_type get_executor() ASIO_NOEXCEPT
  {
    return stream_impl_.lowest_layer().get_executor();
  }
  /// Close the stream.
  void close()
  {
    stream_impl_.close();
  }
  /// Close the stream.
  ASIO_SYNC_OP_VOID close(asio::error_code& ec)
  {
    stream_impl_.close(ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Flush all data from the buffer to the next layer. Returns the number of
  /// bytes written to the next layer on the last write operation. Throws an
  /// exception on failure.
  std::size_t flush()
  {
    return stream_impl_.next_layer().flush();
  }
  /// Flush all data from the buffer to the next layer. Returns the number of
  /// bytes written to the next layer on the last write operation, or 0 if an
  /// error occurred.
  std::size_t flush(asio::error_code& ec)
  {
    return stream_impl_.next_layer().flush(ec);
  }
  /// Start an asynchronous flush.
  template <
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) WriteHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(WriteHandler,
      void (asio::error_code, std::size_t))
  async_flush(
      ASIO_MOVE_ARG(WriteHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return stream_impl_.next_layer().async_flush(
        ASIO_MOVE_CAST(WriteHandler)(handler));
  }
  /// Write the given data to the stream. Returns the number of bytes written.
  /// Throws an exception on failure.
  template <typename ConstBufferSequence>
  std::size_t write_some(const ConstBufferSequence& buffers)
  {
    return stream_impl_.write_some(buffers);
  }
  /// Write the given data to the stream. Returns the number of bytes written,
  /// or 0 if an error occurred.
  template <typename ConstBufferSequence>
  std::size_t write_some(const ConstBufferSequence& buffers,
      asio::error_code& ec)
  {
    return stream_impl_.write_some(buffers, ec);
  }
  /// Start an asynchronous write. The data being written must be valid for the
  /// lifetime of the asynchronous operation.
  template <typename ConstBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) WriteHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(WriteHandler,
      void (asio::error_code, std::size_t))
  async_write_some(const ConstBufferSequence& buffers,
      ASIO_MOVE_ARG(WriteHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return stream_impl_.async_write_some(buffers,
        ASIO_MOVE_CAST(WriteHandler)(handler));
  }
  /// Fill the buffer with some data. Returns the number of bytes placed in the
  /// buffer as a result of the operation. Throws an exception on failure.
  std::size_t fill()
  {
    return stream_impl_.fill();
  }
  /// Fill the buffer with some data. Returns the number of bytes placed in the
  /// buffer as a result of the operation, or 0 if an error occurred.
  std::size_t fill(asio::error_code& ec)
  {
    return stream_impl_.fill(ec);
  }
  /// Start an asynchronous fill.
  template <
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) ReadHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(ReadHandler,
      void (asio::error_code, std::size_t))
  async_fill(
      ASIO_MOVE_ARG(ReadHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return stream_impl_.async_fill(ASIO_MOVE_CAST(ReadHandler)(handler));
  }
  /// Read some data from the stream. Returns the number of bytes read. Throws
  /// an exception on failure.
  template <typename MutableBufferSequence>
  std::size_t read_some(const MutableBufferSequence& buffers)
  {
    return stream_impl_.read_some(buffers);
  }
  /// Read some data from the stream. Returns the number of bytes read or 0 if
  /// an error occurred.
  template <typename MutableBufferSequence>
  std::size_t read_some(const MutableBufferSequence& buffers,
      asio::error_code& ec)
  {
    return stream_impl_.read_some(buffers, ec);
  }
  /// Start an asynchronous read. The buffer into which the data will be read
  /// must be valid for the lifetime of the asynchronous operation.
  template <typename MutableBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) ReadHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(ReadHandler,
      void (asio::error_code, std::size_t))
  async_read_some(const MutableBufferSequence& buffers,
      ASIO_MOVE_ARG(ReadHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return stream_impl_.async_read_some(buffers,
        ASIO_MOVE_CAST(ReadHandler)(handler));
  }
  /// Peek at the incoming data on the stream. Returns the number of bytes read.
  /// Throws an exception on failure.
  template <typename MutableBufferSequence>
  std::size_t peek(const MutableBufferSequence& buffers)
  {
    return stream_impl_.peek(buffers);
  }
  /// Peek at the incoming data on the stream. Returns the number of bytes read,
  /// or 0 if an error occurred.
  template <typename MutableBufferSequence>
  std::size_t peek(const MutableBufferSequence& buffers,
      asio::error_code& ec)
  {
    return stream_impl_.peek(buffers, ec);
  }
  /// Determine the amount of data that may be read without blocking.
  std::size_t in_avail()
  {
    return stream_impl_.in_avail();
  }
  /// Determine the amount of data that may be read without blocking.
  std::size_t in_avail(asio::error_code& ec)
  {
    return stream_impl_.in_avail(ec);
  }
 private:
  // The buffered write stream.
  typedef buffered_write_stream<Stream> write_stream_type;
  write_stream_type inner_stream_impl_;
  // The buffered read stream.
  typedef buffered_read_stream<write_stream_type&> read_stream_type;
  read_stream_type stream_impl_;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_BUFFERED_STREAM_HPP
--- a/module/Vendor/ASIO/include/asio/buffered_stream_fwd.hpp
+++ b/module/Vendor/ASIO/include/asio/buffered_stream_fwd.hpp
@ -0,0 +1,25 @@
 //
 // buffered_stream_fwd.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BUFFERED_STREAM_FWD_HPP
 #define ASIO_BUFFERED_STREAM_FWD_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 namespace asio {
 template <typename Stream>
 class buffered_stream;
 } // namespace asio
 #endif // ASIO_BUFFERED_STREAM_FWD_HPP
--- a/module/Vendor/ASIO/include/asio/buffered_write_stream.hpp
+++ b/module/Vendor/ASIO/include/asio/buffered_write_stream.hpp
@ -0,0 +1,245 @@
 //
 // buffered_write_stream.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BUFFERED_WRITE_STREAM_HPP
 #define ASIO_BUFFERED_WRITE_STREAM_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include <cstddef>
 #include "asio/buffered_write_stream_fwd.hpp"
 #include "asio/buffer.hpp"
 #include "asio/completion_condition.hpp"
 #include "asio/detail/bind_handler.hpp"
 #include "asio/detail/buffered_stream_storage.hpp"
 #include "asio/detail/noncopyable.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/error.hpp"
 #include "asio/write.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 /// Adds buffering to the write-related operations of a stream.
 /**
 * The buffered_write_stream class template can be used to add buffering to the
 * synchronous and asynchronous write operations of a stream.
 *
 * @par Thread Safety
 * @e Distinct @e objects: Safe.@n
 * @e Shared @e objects: Unsafe.
 *
 * @par Concepts:
 * AsyncReadStream, AsyncWriteStream, Stream, SyncReadStream, SyncWriteStream.
 */
 template <typename Stream>
 class buffered_write_stream
  : private noncopyable
 {
 public:
  /// The type of the next layer.
  typedef typename remove_reference<Stream>::type next_layer_type;
  /// The type of the lowest layer.
  typedef typename next_layer_type::lowest_layer_type lowest_layer_type;
  /// The type of the executor associated with the object.
  typedef typename lowest_layer_type::executor_type executor_type;
 #if defined(GENERATING_DOCUMENTATION)
  /// The default buffer size.
  static const std::size_t default_buffer_size = implementation_defined;
 #else
  ASIO_STATIC_CONSTANT(std::size_t, default_buffer_size = 1024);
 #endif
  /// Construct, passing the specified argument to initialise the next layer.
  template <typename Arg>
  explicit buffered_write_stream(Arg& a)
    : next_layer_(a),
      storage_(default_buffer_size)
  {
  }
  /// Construct, passing the specified argument to initialise the next layer.
  template <typename Arg>
  buffered_write_stream(Arg& a, std::size_t buffer_size)
    : next_layer_(a),
      storage_(buffer_size)
  {
  }
  /// Get a reference to the next layer.
  next_layer_type& next_layer()
  {
    return next_layer_;
  }
  /// Get a reference to the lowest layer.
  lowest_layer_type& lowest_layer()
  {
    return next_layer_.lowest_layer();
  }
  /// Get a const reference to the lowest layer.
  const lowest_layer_type& lowest_layer() const
  {
    return next_layer_.lowest_layer();
  }
  /// Get the executor associated with the object.
  executor_type get_executor() ASIO_NOEXCEPT
  {
    return next_layer_.lowest_layer().get_executor();
  }
  /// Close the stream.
  void close()
  {
    next_layer_.close();
  }
  /// Close the stream.
  ASIO_SYNC_OP_VOID close(asio::error_code& ec)
  {
    next_layer_.close(ec);
    ASIO_SYNC_OP_VOID_RETURN(ec);
  }
  /// Flush all data from the buffer to the next layer. Returns the number of
  /// bytes written to the next layer on the last write operation. Throws an
  /// exception on failure.
  std::size_t flush();
  /// Flush all data from the buffer to the next layer. Returns the number of
  /// bytes written to the next layer on the last write operation, or 0 if an
  /// error occurred.
  std::size_t flush(asio::error_code& ec);
  /// Start an asynchronous flush.
  template <
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) WriteHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(WriteHandler,
      void (asio::error_code, std::size_t))
  async_flush(
      ASIO_MOVE_ARG(WriteHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type));
  /// Write the given data to the stream. Returns the number of bytes written.
  /// Throws an exception on failure.
  template <typename ConstBufferSequence>
  std::size_t write_some(const ConstBufferSequence& buffers);
  /// Write the given data to the stream. Returns the number of bytes written,
  /// or 0 if an error occurred and the error handler did not throw.
  template <typename ConstBufferSequence>
  std::size_t write_some(const ConstBufferSequence& buffers,
      asio::error_code& ec);
  /// Start an asynchronous write. The data being written must be valid for the
  /// lifetime of the asynchronous operation.
  template <typename ConstBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) WriteHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(WriteHandler,
      void (asio::error_code, std::size_t))
  async_write_some(const ConstBufferSequence& buffers,
      ASIO_MOVE_ARG(WriteHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type));
  /// Read some data from the stream. Returns the number of bytes read. Throws
  /// an exception on failure.
  template <typename MutableBufferSequence>
  std::size_t read_some(const MutableBufferSequence& buffers)
  {
    return next_layer_.read_some(buffers);
  }
  /// Read some data from the stream. Returns the number of bytes read or 0 if
  /// an error occurred.
  template <typename MutableBufferSequence>
  std::size_t read_some(const MutableBufferSequence& buffers,
      asio::error_code& ec)
  {
    return next_layer_.read_some(buffers, ec);
  }
  /// Start an asynchronous read. The buffer into which the data will be read
  /// must be valid for the lifetime of the asynchronous operation.
  template <typename MutableBufferSequence,
      ASIO_COMPLETION_TOKEN_FOR(void (asio::error_code,
        std::size_t)) ReadHandler
          ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(executor_type)>
  ASIO_INITFN_AUTO_RESULT_TYPE(ReadHandler,
      void (asio::error_code, std::size_t))
  async_read_some(const MutableBufferSequence& buffers,
      ASIO_MOVE_ARG(ReadHandler) handler
        ASIO_DEFAULT_COMPLETION_TOKEN(executor_type))
  {
    return next_layer_.async_read_some(buffers,
        ASIO_MOVE_CAST(ReadHandler)(handler));
  }
  /// Peek at the incoming data on the stream. Returns the number of bytes read.
  /// Throws an exception on failure.
  template <typename MutableBufferSequence>
  std::size_t peek(const MutableBufferSequence& buffers)
  {
    return next_layer_.peek(buffers);
  }
  /// Peek at the incoming data on the stream. Returns the number of bytes read,
  /// or 0 if an error occurred.
  template <typename MutableBufferSequence>
  std::size_t peek(const MutableBufferSequence& buffers,
      asio::error_code& ec)
  {
    return next_layer_.peek(buffers, ec);
  }
  /// Determine the amount of data that may be read without blocking.
  std::size_t in_avail()
  {
    return next_layer_.in_avail();
  }
  /// Determine the amount of data that may be read without blocking.
  std::size_t in_avail(asio::error_code& ec)
  {
    return next_layer_.in_avail(ec);
  }
 private:
  /// Copy data into the internal buffer from the specified source buffer.
  /// Returns the number of bytes copied.
  template <typename ConstBufferSequence>
  std::size_t copy(const ConstBufferSequence& buffers);
  /// The next layer.
  Stream next_layer_;
  // The data in the buffer.
  detail::buffered_stream_storage storage_;
 };
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #include "asio/impl/buffered_write_stream.hpp"
 #endif // ASIO_BUFFERED_WRITE_STREAM_HPP
--- a/module/Vendor/ASIO/include/asio/buffered_write_stream_fwd.hpp
+++ b/module/Vendor/ASIO/include/asio/buffered_write_stream_fwd.hpp
@ -0,0 +1,25 @@
 //
 // buffered_write_stream_fwd.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BUFFERED_WRITE_STREAM_FWD_HPP
 #define ASIO_BUFFERED_WRITE_STREAM_FWD_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 namespace asio {
 template <typename Stream>
 class buffered_write_stream;
 } // namespace asio
 #endif // ASIO_BUFFERED_WRITE_STREAM_FWD_HPP
--- a/module/Vendor/ASIO/include/asio/buffers_iterator.hpp
+++ b/module/Vendor/ASIO/include/asio/buffers_iterator.hpp
@ -0,0 +1,521 @@
 //
 // buffers_iterator.hpp
 // ~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_BUFFERS_ITERATOR_HPP
 #define ASIO_BUFFERS_ITERATOR_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include <cstddef>
 #include <iterator>
 #include "asio/buffer.hpp"
 #include "asio/detail/assert.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail
 {
  template <bool IsMutable>
  struct buffers_iterator_types_helper;
  template <>
  struct buffers_iterator_types_helper<false>
  {
    typedef const_buffer buffer_type;
    template <typename ByteType>
    struct byte_type
    {
      typedef typename add_const<ByteType>::type type;
    };
  };
  template <>
  struct buffers_iterator_types_helper<true>
  {
    typedef mutable_buffer buffer_type;
    template <typename ByteType>
    struct byte_type
    {
      typedef ByteType type;
    };
  };
  template <typename BufferSequence, typename ByteType>
  struct buffers_iterator_types
  {
    enum
    {
      is_mutable = is_convertible<
          typename BufferSequence::value_type,
          mutable_buffer>::value
    };
    typedef buffers_iterator_types_helper<is_mutable> helper;
    typedef typename helper::buffer_type buffer_type;
    typedef typename helper::template byte_type<ByteType>::type byte_type;
    typedef typename BufferSequence::const_iterator const_iterator;
  };
  template <typename ByteType>
  struct buffers_iterator_types<mutable_buffer, ByteType>
  {
    typedef mutable_buffer buffer_type;
    typedef ByteType byte_type;
    typedef const mutable_buffer* const_iterator;
  };
  template <typename ByteType>
  struct buffers_iterator_types<const_buffer, ByteType>
  {
    typedef const_buffer buffer_type;
    typedef typename add_const<ByteType>::type byte_type;
    typedef const const_buffer* const_iterator;
  };
 #if !defined(ASIO_NO_DEPRECATED)
  template <typename ByteType>
  struct buffers_iterator_types<mutable_buffers_1, ByteType>
  {
    typedef mutable_buffer buffer_type;
    typedef ByteType byte_type;
    typedef const mutable_buffer* const_iterator;
  };
  template <typename ByteType>
  struct buffers_iterator_types<const_buffers_1, ByteType>
  {
    typedef const_buffer buffer_type;
    typedef typename add_const<ByteType>::type byte_type;
    typedef const const_buffer* const_iterator;
  };
 #endif // !defined(ASIO_NO_DEPRECATED)
 }
 /// A random access iterator over the bytes in a buffer sequence.
 template <typename BufferSequence, typename ByteType = char>
 class buffers_iterator
 {
 private:
  typedef typename detail::buffers_iterator_types<
      BufferSequence, ByteType>::buffer_type buffer_type;
  typedef typename detail::buffers_iterator_types<BufferSequence,
          ByteType>::const_iterator buffer_sequence_iterator_type;
 public:
  /// The type used for the distance between two iterators.
  typedef std::ptrdiff_t difference_type;
  /// The type of the value pointed to by the iterator.
  typedef ByteType value_type;
 #if defined(GENERATING_DOCUMENTATION)
  /// The type of the result of applying operator->() to the iterator.
  /**
   * If the buffer sequence stores buffer objects that are convertible to
   * mutable_buffer, this is a pointer to a non-const ByteType. Otherwise, a
   * pointer to a const ByteType.
   */
  typedef const_or_non_const_ByteType* pointer;
 #else // defined(GENERATING_DOCUMENTATION)
  typedef typename detail::buffers_iterator_types<
      BufferSequence, ByteType>::byte_type* pointer;
 #endif // defined(GENERATING_DOCUMENTATION)
 #if defined(GENERATING_DOCUMENTATION)
  /// The type of the result of applying operator*() to the iterator.
  /**
   * If the buffer sequence stores buffer objects that are convertible to
   * mutable_buffer, this is a reference to a non-const ByteType. Otherwise, a
   * reference to a const ByteType.
   */
  typedef const_or_non_const_ByteType& reference;
 #else // defined(GENERATING_DOCUMENTATION)
  typedef typename detail::buffers_iterator_types<
      BufferSequence, ByteType>::byte_type& reference;
 #endif // defined(GENERATING_DOCUMENTATION)
  /// The iterator category.
  typedef std::random_access_iterator_tag iterator_category;
  /// Default constructor. Creates an iterator in an undefined state.
  buffers_iterator()
    : current_buffer_(),
      current_buffer_position_(0),
      begin_(),
      current_(),
      end_(),
      position_(0)
  {
  }
  /// Construct an iterator representing the beginning of the buffers' data.
  static buffers_iterator begin(const BufferSequence& buffers)
 #if defined(__GNUC__) && (__GNUC__ == 4) && (__GNUC_MINOR__ == 3)
    __attribute__ ((__noinline__))
 #endif // defined(__GNUC__) && (__GNUC__ == 4) && (__GNUC_MINOR__ == 3)
  {
    buffers_iterator new_iter;
    new_iter.begin_ = asio::buffer_sequence_begin(buffers);
    new_iter.current_ = asio::buffer_sequence_begin(buffers);
    new_iter.end_ = asio::buffer_sequence_end(buffers);
    while (new_iter.current_ != new_iter.end_)
    {
      new_iter.current_buffer_ = *new_iter.current_;
      if (new_iter.current_buffer_.size() > 0)
        break;
      ++new_iter.current_;
    }
    return new_iter;
  }
  /// Construct an iterator representing the end of the buffers' data.
  static buffers_iterator end(const BufferSequence& buffers)
 #if defined(__GNUC__) && (__GNUC__ == 4) && (__GNUC_MINOR__ == 3)
    __attribute__ ((__noinline__))
 #endif // defined(__GNUC__) && (__GNUC__ == 4) && (__GNUC_MINOR__ == 3)
  {
    buffers_iterator new_iter;
    new_iter.begin_ = asio::buffer_sequence_begin(buffers);
    new_iter.current_ = asio::buffer_sequence_begin(buffers);
    new_iter.end_ = asio::buffer_sequence_end(buffers);
    while (new_iter.current_ != new_iter.end_)
    {
      buffer_type buffer = *new_iter.current_;
      new_iter.position_ += buffer.size();
      ++new_iter.current_;
    }
    return new_iter;
  }
  /// Dereference an iterator.
  reference operator*() const
  {
    return dereference();
  }
  /// Dereference an iterator.
  pointer operator->() const
  {
    return &dereference();
  }
  /// Access an individual element.
  reference operator[](std::ptrdiff_t difference) const
  {
    buffers_iterator tmp(*this);
    tmp.advance(difference);
    return *tmp;
  }
  /// Increment operator (prefix).
  buffers_iterator& operator++()
  {
    increment();
    return *this;
  }
  /// Increment operator (postfix).
  buffers_iterator operator++(int)
  {
    buffers_iterator tmp(*this);
    ++*this;
    return tmp;
  }
  /// Decrement operator (prefix).
  buffers_iterator& operator--()
  {
    decrement();
    return *this;
  }
  /// Decrement operator (postfix).
  buffers_iterator operator--(int)
  {
    buffers_iterator tmp(*this);
    --*this;
    return tmp;
  }
  /// Addition operator.
  buffers_iterator& operator+=(std::ptrdiff_t difference)
  {
    advance(difference);
    return *this;
  }
  /// Subtraction operator.
  buffers_iterator& operator-=(std::ptrdiff_t difference)
  {
    advance(-difference);
    return *this;
  }
  /// Addition operator.
  friend buffers_iterator operator+(const buffers_iterator& iter,
      std::ptrdiff_t difference)
  {
    buffers_iterator tmp(iter);
    tmp.advance(difference);
    return tmp;
  }
  /// Addition operator.
  friend buffers_iterator operator+(std::ptrdiff_t difference,
      const buffers_iterator& iter)
  {
    buffers_iterator tmp(iter);
    tmp.advance(difference);
    return tmp;
  }
  /// Subtraction operator.
  friend buffers_iterator operator-(const buffers_iterator& iter,
      std::ptrdiff_t difference)
  {
    buffers_iterator tmp(iter);
    tmp.advance(-difference);
    return tmp;
  }
  /// Subtraction operator.
  friend std::ptrdiff_t operator-(const buffers_iterator& a,
      const buffers_iterator& b)
  {
    return b.distance_to(a);
  }
  /// Test two iterators for equality.
  friend bool operator==(const buffers_iterator& a, const buffers_iterator& b)
  {
    return a.equal(b);
  }
  /// Test two iterators for inequality.
  friend bool operator!=(const buffers_iterator& a, const buffers_iterator& b)
  {
    return !a.equal(b);
  }
  /// Compare two iterators.
  friend bool operator<(const buffers_iterator& a, const buffers_iterator& b)
  {
    return a.distance_to(b) > 0;
  }
  /// Compare two iterators.
  friend bool operator<=(const buffers_iterator& a, const buffers_iterator& b)
  {
    return !(b < a);
  }
  /// Compare two iterators.
  friend bool operator>(const buffers_iterator& a, const buffers_iterator& b)
  {
    return b < a;
  }
  /// Compare two iterators.
  friend bool operator>=(const buffers_iterator& a, const buffers_iterator& b)
  {
    return !(a < b);
  }
 private:
  // Dereference the iterator.
  reference dereference() const
  {
    return static_cast<pointer>(
        current_buffer_.data())[current_buffer_position_];
  }
  // Compare two iterators for equality.
  bool equal(const buffers_iterator& other) const
  {
    return position_ == other.position_;
  }
  // Increment the iterator.
  void increment()
  {
    ASIO_ASSERT(current_ != end_ && "iterator out of bounds");
    ++position_;
    // Check if the increment can be satisfied by the current buffer.
    ++current_buffer_position_;
    if (current_buffer_position_ != current_buffer_.size())
      return;
    // Find the next non-empty buffer.
    ++current_;
    current_buffer_position_ = 0;
    while (current_ != end_)
    {
      current_buffer_ = *current_;
      if (current_buffer_.size() > 0)
        return;
      ++current_;
    }
  }
  // Decrement the iterator.
  void decrement()
  {
    ASIO_ASSERT(position_ > 0 && "iterator out of bounds");
    --position_;
    // Check if the decrement can be satisfied by the current buffer.
    if (current_buffer_position_ != 0)
    {
      --current_buffer_position_;
      return;
    }
    // Find the previous non-empty buffer.
    buffer_sequence_iterator_type iter = current_;
    while (iter != begin_)
    {
      --iter;
      buffer_type buffer = *iter;
      std::size_t buffer_size = buffer.size();
      if (buffer_size > 0)
      {
        current_ = iter;
        current_buffer_ = buffer;
        current_buffer_position_ = buffer_size - 1;
        return;
      }
    }
  }
  // Advance the iterator by the specified distance.
  void advance(std::ptrdiff_t n)
  {
    if (n > 0)
    {
      ASIO_ASSERT(current_ != end_ && "iterator out of bounds");
      for (;;)
      {
        std::ptrdiff_t current_buffer_balance
          = current_buffer_.size() - current_buffer_position_;
        // Check if the advance can be satisfied by the current buffer.
        if (current_buffer_balance > n)
        {
          position_ += n;
          current_buffer_position_ += n;
          return;
        }
        // Update position.
        n -= current_buffer_balance;
        position_ += current_buffer_balance;
        // Move to next buffer. If it is empty then it will be skipped on the
        // next iteration of this loop.
        if (++current_ == end_)
        {
          ASIO_ASSERT(n == 0 && "iterator out of bounds");
          current_buffer_ = buffer_type();
          current_buffer_position_ = 0;
          return;
        }
        current_buffer_ = *current_;
        current_buffer_position_ = 0;
      }
    }
    else if (n < 0)
    {
      std::size_t abs_n = -n;
      ASIO_ASSERT(position_ >= abs_n && "iterator out of bounds");
      for (;;)
      {
        // Check if the advance can be satisfied by the current buffer.
        if (current_buffer_position_ >= abs_n)
        {
          position_ -= abs_n;
          current_buffer_position_ -= abs_n;
          return;
        }
        // Update position.
        abs_n -= current_buffer_position_;
        position_ -= current_buffer_position_;
        // Check if we've reached the beginning of the buffers.
        if (current_ == begin_)
        {
          ASIO_ASSERT(abs_n == 0 && "iterator out of bounds");
          current_buffer_position_ = 0;
          return;
        }
        // Find the previous non-empty buffer.
        buffer_sequence_iterator_type iter = current_;
        while (iter != begin_)
        {
          --iter;
          buffer_type buffer = *iter;
          std::size_t buffer_size = buffer.size();
          if (buffer_size > 0)
          {
            current_ = iter;
            current_buffer_ = buffer;
            current_buffer_position_ = buffer_size;
            break;
          }
        }
      }
    }
  }
  // Determine the distance between two iterators.
  std::ptrdiff_t distance_to(const buffers_iterator& other) const
  {
    return other.position_ - position_;
  }
  buffer_type current_buffer_;
  std::size_t current_buffer_position_;
  buffer_sequence_iterator_type begin_;
  buffer_sequence_iterator_type current_;
  buffer_sequence_iterator_type end_;
  std::size_t position_;
 };
 /// Construct an iterator representing the beginning of the buffers' data.
 template <typename BufferSequence>
 inline buffers_iterator<BufferSequence> buffers_begin(
    const BufferSequence& buffers)
 {
  return buffers_iterator<BufferSequence>::begin(buffers);
 }
 /// Construct an iterator representing the end of the buffers' data.
 template <typename BufferSequence>
 inline buffers_iterator<BufferSequence> buffers_end(
    const BufferSequence& buffers)
 {
  return buffers_iterator<BufferSequence>::end(buffers);
 }
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_BUFFERS_ITERATOR_HPP
--- a/module/Vendor/ASIO/include/asio/co_spawn.hpp
+++ b/module/Vendor/ASIO/include/asio/co_spawn.hpp
@ -0,0 +1,471 @@
 //
 // co_spawn.hpp
 // ~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_CO_SPAWN_HPP
 #define ASIO_CO_SPAWN_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if defined(ASIO_HAS_CO_AWAIT) || defined(GENERATING_DOCUMENTATION)
 #include "asio/awaitable.hpp"
 #include "asio/execution/executor.hpp"
 #include "asio/execution_context.hpp"
 #include "asio/is_executor.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 template <typename T>
 struct awaitable_signature;
 template <typename T, typename Executor>
 struct awaitable_signature<awaitable<T, Executor>>
 {
  typedef void type(std::exception_ptr, T);
 };
 template <typename Executor>
 struct awaitable_signature<awaitable<void, Executor>>
 {
  typedef void type(std::exception_ptr);
 };
 } // namespace detail
 /// Spawn a new coroutined-based thread of execution.
 /**
 * @param ex The executor that will be used to schedule the new thread of
 * execution.
 *
 * @param a The asio::awaitable object that is the result of calling the
 * coroutine's entry point function.
 *
 * @param token The completion token that will handle the notification that
 * the thread of execution has completed. The function signature of the
 * completion handler must be:
 * @code void handler(std::exception_ptr, T); @endcode
 *
 * @par Example
 * @code
 * asio::awaitable<std::size_t> echo(tcp::socket socket)
 * {
 *   std::size_t bytes_transferred = 0;
 *
 *   try
 *   {
 *     char data[1024];
 *     for (;;)
 *     {
 *       std::size_t n = co_await socket.async_read_some(
 *           asio::buffer(data), asio::use_awaitable);
 *
 *       co_await asio::async_write(socket,
 *           asio::buffer(data, n), asio::use_awaitable);
 *
 *       bytes_transferred += n;
 *     }
 *   }
 *   catch (const std::exception&)
 *   {
 *   }
 *
 *   co_return bytes_transferred;
 * }
 *
 * // ...
 *
 * asio::co_spawn(my_executor,
 *   echo(std::move(my_tcp_socket)),
 *   [](std::exception_ptr e, std::size_t n)
 *   {
 *     std::cout << "transferred " << n << "\n";
 *   });
 * @endcode
 */
 template <typename Executor, typename T, typename AwaitableExecutor,
    ASIO_COMPLETION_TOKEN_FOR(
      void(std::exception_ptr, T)) CompletionToken
        ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(Executor)>
 inline ASIO_INITFN_AUTO_RESULT_TYPE(
    CompletionToken, void(std::exception_ptr, T))
 co_spawn(const Executor& ex, awaitable<T, AwaitableExecutor> a,
    CompletionToken&& token
      ASIO_DEFAULT_COMPLETION_TOKEN(Executor),
    typename enable_if<
      (is_executor<Executor>::value || execution::is_executor<Executor>::value)
        && is_convertible<Executor, AwaitableExecutor>::value
    >::type* = 0);
 /// Spawn a new coroutined-based thread of execution.
 /**
 * @param ex The executor that will be used to schedule the new thread of
 * execution.
 *
 * @param a The asio::awaitable object that is the result of calling the
 * coroutine's entry point function.
 *
 * @param token The completion token that will handle the notification that
 * the thread of execution has completed. The function signature of the
 * completion handler must be:
 * @code void handler(std::exception_ptr); @endcode
 *
 * @par Example
 * @code
 * asio::awaitable<void> echo(tcp::socket socket)
 * {
 *   try
 *   {
 *     char data[1024];
 *     for (;;)
 *     {
 *       std::size_t n = co_await socket.async_read_some(
 *           asio::buffer(data), asio::use_awaitable);
 *
 *       co_await asio::async_write(socket,
 *           asio::buffer(data, n), asio::use_awaitable);
 *     }
 *   }
 *   catch (const std::exception& e)
 *   {
 *     std::cerr << "Exception: " << e.what() << "\n";
 *   }
 * }
 *
 * // ...
 *
 * asio::co_spawn(my_executor,
 *   echo(std::move(my_tcp_socket)),
 *   asio::detached);
 * @endcode
 */
 template <typename Executor, typename AwaitableExecutor,
    ASIO_COMPLETION_TOKEN_FOR(
      void(std::exception_ptr)) CompletionToken
        ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(Executor)>
 inline ASIO_INITFN_AUTO_RESULT_TYPE(
    CompletionToken, void(std::exception_ptr))
 co_spawn(const Executor& ex, awaitable<void, AwaitableExecutor> a,
    CompletionToken&& token
      ASIO_DEFAULT_COMPLETION_TOKEN(Executor),
    typename enable_if<
      (is_executor<Executor>::value || execution::is_executor<Executor>::value)
        && is_convertible<Executor, AwaitableExecutor>::value
    >::type* = 0);
 /// Spawn a new coroutined-based thread of execution.
 /**
 * @param ctx An execution context that will provide the executor to be used to
 * schedule the new thread of execution.
 *
 * @param a The asio::awaitable object that is the result of calling the
 * coroutine's entry point function.
 *
 * @param token The completion token that will handle the notification that
 * the thread of execution has completed. The function signature of the
 * completion handler must be:
 * @code void handler(std::exception_ptr); @endcode
 *
 * @par Example
 * @code
 * asio::awaitable<std::size_t> echo(tcp::socket socket)
 * {
 *   std::size_t bytes_transferred = 0;
 *
 *   try
 *   {
 *     char data[1024];
 *     for (;;)
 *     {
 *       std::size_t n = co_await socket.async_read_some(
 *           asio::buffer(data), asio::use_awaitable);
 *
 *       co_await asio::async_write(socket,
 *           asio::buffer(data, n), asio::use_awaitable);
 *
 *       bytes_transferred += n;
 *     }
 *   }
 *   catch (const std::exception&)
 *   {
 *   }
 *
 *   co_return bytes_transferred;
 * }
 *
 * // ...
 *
 * asio::co_spawn(my_io_context,
 *   echo(std::move(my_tcp_socket)),
 *   [](std::exception_ptr e, std::size_t n)
 *   {
 *     std::cout << "transferred " << n << "\n";
 *   });
 * @endcode
 */
 template <typename ExecutionContext, typename T, typename AwaitableExecutor,
    ASIO_COMPLETION_TOKEN_FOR(
      void(std::exception_ptr, T)) CompletionToken
        ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(
          typename ExecutionContext::executor_type)>
 inline ASIO_INITFN_AUTO_RESULT_TYPE(
    CompletionToken, void(std::exception_ptr, T))
 co_spawn(ExecutionContext& ctx, awaitable<T, AwaitableExecutor> a,
    CompletionToken&& token
      ASIO_DEFAULT_COMPLETION_TOKEN(
        typename ExecutionContext::executor_type),
    typename enable_if<
      is_convertible<ExecutionContext&, execution_context&>::value
        && is_convertible<typename ExecutionContext::executor_type,
          AwaitableExecutor>::value
    >::type* = 0);
 /// Spawn a new coroutined-based thread of execution.
 /**
 * @param ctx An execution context that will provide the executor to be used to
 * schedule the new thread of execution.
 *
 * @param a The asio::awaitable object that is the result of calling the
 * coroutine's entry point function.
 *
 * @param token The completion token that will handle the notification that
 * the thread of execution has completed. The function signature of the
 * completion handler must be:
 * @code void handler(std::exception_ptr); @endcode
 *
 * @par Example
 * @code
 * asio::awaitable<void> echo(tcp::socket socket)
 * {
 *   try
 *   {
 *     char data[1024];
 *     for (;;)
 *     {
 *       std::size_t n = co_await socket.async_read_some(
 *           asio::buffer(data), asio::use_awaitable);
 *
 *       co_await asio::async_write(socket,
 *           asio::buffer(data, n), asio::use_awaitable);
 *     }
 *   }
 *   catch (const std::exception& e)
 *   {
 *     std::cerr << "Exception: " << e.what() << "\n";
 *   }
 * }
 *
 * // ...
 *
 * asio::co_spawn(my_io_context,
 *   echo(std::move(my_tcp_socket)),
 *   asio::detached);
 * @endcode
 */
 template <typename ExecutionContext, typename AwaitableExecutor,
    ASIO_COMPLETION_TOKEN_FOR(
      void(std::exception_ptr)) CompletionToken
        ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(
          typename ExecutionContext::executor_type)>
 inline ASIO_INITFN_AUTO_RESULT_TYPE(
    CompletionToken, void(std::exception_ptr))
 co_spawn(ExecutionContext& ctx, awaitable<void, AwaitableExecutor> a,
    CompletionToken&& token
      ASIO_DEFAULT_COMPLETION_TOKEN(
        typename ExecutionContext::executor_type),
    typename enable_if<
      is_convertible<ExecutionContext&, execution_context&>::value
        && is_convertible<typename ExecutionContext::executor_type,
          AwaitableExecutor>::value
    >::type* = 0);
 /// Spawn a new coroutined-based thread of execution.
 /**
 * @param ex The executor that will be used to schedule the new thread of
 * execution.
 *
 * @param f A nullary function object with a return type of the form
 * @c asio::awaitable<R,E> that will be used as the coroutine's entry
 * point.
 *
 * @param token The completion token that will handle the notification that the
 * thread of execution has completed. If @c R is @c void, the function
 * signature of the completion handler must be:
 *
 * @code void handler(std::exception_ptr); @endcode
 * Otherwise, the function signature of the completion handler must be:
 * @code void handler(std::exception_ptr, R); @endcode
 *
 *
 * @par Example
 * @code
 * asio::awaitable<std::size_t> echo(tcp::socket socket)
 * {
 *   std::size_t bytes_transferred = 0;
 *
 *   try
 *   {
 *     char data[1024];
 *     for (;;)
 *     {
 *       std::size_t n = co_await socket.async_read_some(
 *           asio::buffer(data), asio::use_awaitable);
 *
 *       co_await asio::async_write(socket,
 *           asio::buffer(data, n), asio::use_awaitable);
 *
 *       bytes_transferred += n;
 *     }
 *   }
 *   catch (const std::exception&)
 *   {
 *   }
 *
 *   co_return bytes_transferred;
 * }
 *
 * // ...
 *
 * asio::co_spawn(my_executor,
 *   [socket = std::move(my_tcp_socket)]() mutable
 *     -> asio::awaitable<void>
 *   {
 *     try
 *     {
 *       char data[1024];
 *       for (;;)
 *       {
 *         std::size_t n = co_await socket.async_read_some(
 *             asio::buffer(data), asio::use_awaitable);
 *
 *         co_await asio::async_write(socket,
 *             asio::buffer(data, n), asio::use_awaitable);
 *       }
 *     }
 *     catch (const std::exception& e)
 *     {
 *       std::cerr << "Exception: " << e.what() << "\n";
 *     }
 *   }, asio::detached);
 * @endcode
 */
 template <typename Executor, typename F,
    ASIO_COMPLETION_TOKEN_FOR(typename detail::awaitable_signature<
      typename result_of<F()>::type>::type) CompletionToken
        ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(Executor)>
 ASIO_INITFN_AUTO_RESULT_TYPE(CompletionToken,
    typename detail::awaitable_signature<typename result_of<F()>::type>::type)
 co_spawn(const Executor& ex, F&& f,
    CompletionToken&& token
      ASIO_DEFAULT_COMPLETION_TOKEN(Executor),
    typename enable_if<
      is_executor<Executor>::value || execution::is_executor<Executor>::value
    >::type* = 0);
 /// Spawn a new coroutined-based thread of execution.
 /**
 * @param ctx An execution context that will provide the executor to be used to
 * schedule the new thread of execution.
 *
 * @param f A nullary function object with a return type of the form
 * @c asio::awaitable<R,E> that will be used as the coroutine's entry
 * point.
 *
 * @param token The completion token that will handle the notification that the
 * thread of execution has completed. If @c R is @c void, the function
 * signature of the completion handler must be:
 *
 * @code void handler(std::exception_ptr); @endcode
 * Otherwise, the function signature of the completion handler must be:
 * @code void handler(std::exception_ptr, R); @endcode
 *
 *
 * @par Example
 * @code
 * asio::awaitable<std::size_t> echo(tcp::socket socket)
 * {
 *   std::size_t bytes_transferred = 0;
 *
 *   try
 *   {
 *     char data[1024];
 *     for (;;)
 *     {
 *       std::size_t n = co_await socket.async_read_some(
 *           asio::buffer(data), asio::use_awaitable);
 *
 *       co_await asio::async_write(socket,
 *           asio::buffer(data, n), asio::use_awaitable);
 *
 *       bytes_transferred += n;
 *     }
 *   }
 *   catch (const std::exception&)
 *   {
 *   }
 *
 *   co_return bytes_transferred;
 * }
 *
 * // ...
 *
 * asio::co_spawn(my_io_context,
 *   [socket = std::move(my_tcp_socket)]() mutable
 *     -> asio::awaitable<void>
 *   {
 *     try
 *     {
 *       char data[1024];
 *       for (;;)
 *       {
 *         std::size_t n = co_await socket.async_read_some(
 *             asio::buffer(data), asio::use_awaitable);
 *
 *         co_await asio::async_write(socket,
 *             asio::buffer(data, n), asio::use_awaitable);
 *       }
 *     }
 *     catch (const std::exception& e)
 *     {
 *       std::cerr << "Exception: " << e.what() << "\n";
 *     }
 *   }, asio::detached);
 * @endcode
 */
 template <typename ExecutionContext, typename F,
    ASIO_COMPLETION_TOKEN_FOR(typename detail::awaitable_signature<
      typename result_of<F()>::type>::type) CompletionToken
        ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(
          typename ExecutionContext::executor_type)>
 ASIO_INITFN_AUTO_RESULT_TYPE(CompletionToken,
    typename detail::awaitable_signature<typename result_of<F()>::type>::type)
 co_spawn(ExecutionContext& ctx, F&& f,
    CompletionToken&& token
      ASIO_DEFAULT_COMPLETION_TOKEN(
        typename ExecutionContext::executor_type),
    typename enable_if<
      is_convertible<ExecutionContext&, execution_context&>::value
    >::type* = 0);
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #include "asio/impl/co_spawn.hpp"
 #endif // defined(ASIO_HAS_CO_AWAIT) || defined(GENERATING_DOCUMENTATION)
 #endif // ASIO_CO_SPAWN_HPP
--- a/module/Vendor/ASIO/include/asio/completion_condition.hpp
+++ b/module/Vendor/ASIO/include/asio/completion_condition.hpp
@ -0,0 +1,218 @@
 //
 // completion_condition.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_COMPLETION_CONDITION_HPP
 #define ASIO_COMPLETION_CONDITION_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include <cstddef>
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 // The default maximum number of bytes to transfer in a single operation.
 enum default_max_transfer_size_t { default_max_transfer_size = 65536 };
 // Adapt result of old-style completion conditions (which had a bool result
 // where true indicated that the operation was complete).
 inline std::size_t adapt_completion_condition_result(bool result)
 {
  return result ? 0 : default_max_transfer_size;
 }
 // Adapt result of current completion conditions (which have a size_t result
 // where 0 means the operation is complete, and otherwise the result is the
 // maximum number of bytes to transfer on the next underlying operation).
 inline std::size_t adapt_completion_condition_result(std::size_t result)
 {
  return result;
 }
 class transfer_all_t
 {
 public:
  typedef std::size_t result_type;
  template <typename Error>
  std::size_t operator()(const Error& err, std::size_t)
  {
    return !!err ? 0 : default_max_transfer_size;
  }
 };
 class transfer_at_least_t
 {
 public:
  typedef std::size_t result_type;
  explicit transfer_at_least_t(std::size_t minimum)
    : minimum_(minimum)
  {
  }
  template <typename Error>
  std::size_t operator()(const Error& err, std::size_t bytes_transferred)
  {
    return (!!err || bytes_transferred >= minimum_)
      ? 0 : default_max_transfer_size;
  }
 private:
  std::size_t minimum_;
 };
 class transfer_exactly_t
 {
 public:
  typedef std::size_t result_type;
  explicit transfer_exactly_t(std::size_t size)
    : size_(size)
  {
  }
  template <typename Error>
  std::size_t operator()(const Error& err, std::size_t bytes_transferred)
  {
    return (!!err || bytes_transferred >= size_) ? 0 :
      (size_ - bytes_transferred < default_max_transfer_size
        ? size_ - bytes_transferred : std::size_t(default_max_transfer_size));
  }
 private:
  std::size_t size_;
 };
 } // namespace detail
 /**
 * @defgroup completion_condition Completion Condition Function Objects
 *
 * Function objects used for determining when a read or write operation should
 * complete.
 */
 /*@{*/
 /// Return a completion condition function object that indicates that a read or
 /// write operation should continue until all of the data has been transferred,
 /// or until an error occurs.
 /**
 * This function is used to create an object, of unspecified type, that meets
 * CompletionCondition requirements.
 *
 * @par Example
 * Reading until a buffer is full:
 * @code
 * boost::array<char, 128> buf;
 * asio::error_code ec;
 * std::size_t n = asio::read(
 *     sock, asio::buffer(buf),
 *     asio::transfer_all(), ec);
 * if (ec)
 * {
 *   // An error occurred.
 * }
 * else
 * {
 *   // n == 128
 * }
 * @endcode
 */
 #if defined(GENERATING_DOCUMENTATION)
 unspecified transfer_all();
 #else
 inline detail::transfer_all_t transfer_all()
 {
  return detail::transfer_all_t();
 }
 #endif
 /// Return a completion condition function object that indicates that a read or
 /// write operation should continue until a minimum number of bytes has been
 /// transferred, or until an error occurs.
 /**
 * This function is used to create an object, of unspecified type, that meets
 * CompletionCondition requirements.
 *
 * @par Example
 * Reading until a buffer is full or contains at least 64 bytes:
 * @code
 * boost::array<char, 128> buf;
 * asio::error_code ec;
 * std::size_t n = asio::read(
 *     sock, asio::buffer(buf),
 *     asio::transfer_at_least(64), ec);
 * if (ec)
 * {
 *   // An error occurred.
 * }
 * else
 * {
 *   // n >= 64 && n <= 128
 * }
 * @endcode
 */
 #if defined(GENERATING_DOCUMENTATION)
 unspecified transfer_at_least(std::size_t minimum);
 #else
 inline detail::transfer_at_least_t transfer_at_least(std::size_t minimum)
 {
  return detail::transfer_at_least_t(minimum);
 }
 #endif
 /// Return a completion condition function object that indicates that a read or
 /// write operation should continue until an exact number of bytes has been
 /// transferred, or until an error occurs.
 /**
 * This function is used to create an object, of unspecified type, that meets
 * CompletionCondition requirements.
 *
 * @par Example
 * Reading until a buffer is full or contains exactly 64 bytes:
 * @code
 * boost::array<char, 128> buf;
 * asio::error_code ec;
 * std::size_t n = asio::read(
 *     sock, asio::buffer(buf),
 *     asio::transfer_exactly(64), ec);
 * if (ec)
 * {
 *   // An error occurred.
 * }
 * else
 * {
 *   // n == 64
 * }
 * @endcode
 */
 #if defined(GENERATING_DOCUMENTATION)
 unspecified transfer_exactly(std::size_t size);
 #else
 inline detail::transfer_exactly_t transfer_exactly(std::size_t size)
 {
  return detail::transfer_exactly_t(size);
 }
 #endif
 /*@}*/
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_COMPLETION_CONDITION_HPP
--- a/module/Vendor/ASIO/include/asio/compose.hpp
+++ b/module/Vendor/ASIO/include/asio/compose.hpp
@ -0,0 +1,136 @@
 //
 // compose.hpp
 // ~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_COMPOSE_HPP
 #define ASIO_COMPOSE_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/async_result.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 #if defined(ASIO_HAS_VARIADIC_TEMPLATES) \
  || defined(GENERATING_DOCUMENTATION)
 /// Launch an asynchronous operation with a stateful implementation.
 /**
 * The async_compose function simplifies the implementation of composed
 * asynchronous operations automatically wrapping a stateful function object
 * with a conforming intermediate completion handler.
 *
 * @param implementation A function object that contains the implementation of
 * the composed asynchronous operation. The first argument to the function
 * object is a non-const reference to the enclosing intermediate completion
 * handler. The remaining arguments are any arguments that originate from the
 * completion handlers of any asynchronous operations performed by the
 * implementation.
 * @param token The completion token.
 *
 * @param io_objects_or_executors Zero or more I/O objects or I/O executors for
 * which outstanding work must be maintained.
 *
 * @par Example:
 *
 * @code struct async_echo_implementation
 * {
 *   tcp::socket& socket_;
 *   asio::mutable_buffer buffer_;
 *   enum { starting, reading, writing } state_;
 *
 *   template <typename Self>
 *   void operator()(Self& self,
 *       asio::error_code error = {},
 *       std::size_t n = 0)
 *   {
 *     switch (state_)
 *     {
 *     case starting:
 *       state_ = reading;
 *       socket_.async_read_some(
 *           buffer_, std::move(self));
 *       break;
 *     case reading:
 *       if (error)
 *       {
 *         self.complete(error, 0);
 *       }
 *       else
 *       {
 *         state_ = writing;
 *         asio::async_write(socket_, buffer_,
 *             asio::transfer_exactly(n),
 *             std::move(self));
 *       }
 *       break;
 *     case writing:
 *       self.complete(error, n);
 *       break;
 *     }
 *   }
 * };
 *
 * template <typename CompletionToken>
 * auto async_echo(tcp::socket& socket,
 *     asio::mutable_buffer buffer,
 *     CompletionToken&& token) ->
 *   typename asio::async_result<
 *     typename std::decay<CompletionToken>::type,
 *       void(asio::error_code, std::size_t)>::return_type
 * {
 *   return asio::async_compose<CompletionToken,
 *     void(asio::error_code, std::size_t)>(
 *       async_echo_implementation{socket, buffer,
 *         async_echo_implementation::starting},
 *       token, socket);
 * } @endcode
 */
 template <typename CompletionToken, typename Signature,
    typename Implementation, typename... IoObjectsOrExecutors>
 ASIO_INITFN_AUTO_RESULT_TYPE(CompletionToken, Signature)
 async_compose(ASIO_MOVE_ARG(Implementation) implementation,
    ASIO_NONDEDUCED_MOVE_ARG(CompletionToken) token,
    ASIO_MOVE_ARG(IoObjectsOrExecutors)... io_objects_or_executors);
 #else // defined(ASIO_HAS_VARIADIC_TEMPLATES)
      //   || defined(GENERATING_DOCUMENTATION)
 template <typename CompletionToken, typename Signature, typename Implementation>
 ASIO_INITFN_AUTO_RESULT_TYPE(CompletionToken, Signature)
 async_compose(ASIO_MOVE_ARG(Implementation) implementation,
    ASIO_NONDEDUCED_MOVE_ARG(CompletionToken) token);
 #define ASIO_PRIVATE_ASYNC_COMPOSE_DEF(n) \
  template <typename CompletionToken, typename Signature, \
      typename Implementation, ASIO_VARIADIC_TPARAMS(n)> \
  ASIO_INITFN_AUTO_RESULT_TYPE(CompletionToken, Signature) \
  async_compose(ASIO_MOVE_ARG(Implementation) implementation, \
      ASIO_NONDEDUCED_MOVE_ARG(CompletionToken) token, \
      ASIO_VARIADIC_MOVE_PARAMS(n));
  /**/
  ASIO_VARIADIC_GENERATE(ASIO_PRIVATE_ASYNC_COMPOSE_DEF)
 #undef ASIO_PRIVATE_ASYNC_COMPOSE_DEF
 #endif // defined(ASIO_HAS_VARIADIC_TEMPLATES)
       //   || defined(GENERATING_DOCUMENTATION)
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #include "asio/impl/compose.hpp"
 #endif // ASIO_COMPOSE_HPP
--- a/module/Vendor/ASIO/include/asio/connect.hpp
+++ b/module/Vendor/ASIO/include/asio/connect.hpp
--- a/module/Vendor/ASIO/include/asio/coroutine.hpp
+++ b/module/Vendor/ASIO/include/asio/coroutine.hpp
@ -0,0 +1,328 @@
 //
 // coroutine.hpp
 // ~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_COROUTINE_HPP
 #define ASIO_COROUTINE_HPP
 namespace asio {
 namespace detail {
 class coroutine_ref;
 } // namespace detail
 /// Provides support for implementing stackless coroutines.
 /**
 * The @c coroutine class may be used to implement stackless coroutines. The
 * class itself is used to store the current state of the coroutine.
 *
 * Coroutines are copy-constructible and assignable, and the space overhead is
 * a single int. They can be used as a base class:
 *
 * @code class session : coroutine
 * {
 *   ...
 * }; @endcode
 *
 * or as a data member:
 *
 * @code class session
 * {
 *   ...
 *   coroutine coro_;
 * }; @endcode
 *
 * or even bound in as a function argument using lambdas or @c bind(). The
 * important thing is that as the application maintains a copy of the object
 * for as long as the coroutine must be kept alive.
 *
 * @par Pseudo-keywords
 *
 * A coroutine is used in conjunction with certain "pseudo-keywords", which
 * are implemented as macros. These macros are defined by a header file:
 *
 * @code #include <asio/yield.hpp>@endcode
 *
 * and may conversely be undefined as follows:
 *
 * @code #include <asio/unyield.hpp>@endcode
 *
 * <b>reenter</b>
 *
 * The @c reenter macro is used to define the body of a coroutine. It takes a
 * single argument: a pointer or reference to a coroutine object. For example,
 * if the base class is a coroutine object you may write:
 *
 * @code reenter (this)
 * {
 *   ... coroutine body ...
 * } @endcode
 *
 * and if a data member or other variable you can write:
 *
 * @code reenter (coro_)
 * {
 *   ... coroutine body ...
 * } @endcode
 *
 * When @c reenter is executed at runtime, control jumps to the location of the
 * last @c yield or @c fork.
 *
 * The coroutine body may also be a single statement, such as:
 *
 * @code reenter (this) for (;;)
 * {
 *   ...
 * } @endcode
 *
 * @b Limitation: The @c reenter macro is implemented using a switch. This
 * means that you must take care when using local variables within the
 * coroutine body. The local variable is not allowed in a position where
 * reentering the coroutine could bypass the variable definition.
 *
 * <b>yield <em>statement</em></b>
 *
 * This form of the @c yield keyword is often used with asynchronous operations:
 *
 * @code yield socket_->async_read_some(buffer(*buffer_), *this); @endcode
 *
 * This divides into four logical steps:
 *
 * @li @c yield saves the current state of the coroutine.
 * @li The statement initiates the asynchronous operation.
 * @li The resume point is defined immediately following the statement.
 * @li Control is transferred to the end of the coroutine body.
 *
 * When the asynchronous operation completes, the function object is invoked
 * and @c reenter causes control to transfer to the resume point. It is
 * important to remember to carry the coroutine state forward with the
 * asynchronous operation. In the above snippet, the current class is a
 * function object object with a coroutine object as base class or data member.
 *
 * The statement may also be a compound statement, and this permits us to
 * define local variables with limited scope:
 *
 * @code yield
 * {
 *   mutable_buffers_1 b = buffer(*buffer_);
 *   socket_->async_read_some(b, *this);
 * } @endcode
 *
 * <b>yield return <em>expression</em> ;</b>
 *
 * This form of @c yield is often used in generators or coroutine-based parsers.
 * For example, the function object:
 *
 * @code struct interleave : coroutine
 * {
 *   istream& is1;
 *   istream& is2;
 *   char operator()(char c)
 *   {
 *     reenter (this) for (;;)
 *     {
 *       yield return is1.get();
 *       yield return is2.get();
 *     }
 *   }
 * }; @endcode
 *
 * defines a trivial coroutine that interleaves the characters from two input
 * streams.
 *
 * This type of @c yield divides into three logical steps:
 *
 * @li @c yield saves the current state of the coroutine.
 * @li The resume point is defined immediately following the semicolon.
 * @li The value of the expression is returned from the function.
 *
 * <b>yield ;</b>
 *
 * This form of @c yield is equivalent to the following steps:
 *
 * @li @c yield saves the current state of the coroutine.
 * @li The resume point is defined immediately following the semicolon.
 * @li Control is transferred to the end of the coroutine body.
 *
 * This form might be applied when coroutines are used for cooperative
 * threading and scheduling is explicitly managed. For example:
 *
 * @code struct task : coroutine
 * {
 *   ...
 *   void operator()()
 *   {
 *     reenter (this)
 *     {
 *       while (... not finished ...)
 *       {
 *         ... do something ...
 *         yield;
 *         ... do some more ...
 *         yield;
 *       }
 *     }
 *   }
 *   ...
 * };
 * ...
 * task t1, t2;
 * for (;;)
 * {
 *   t1();
 *   t2();
 * } @endcode
 *
 * <b>yield break ;</b>
 *
 * The final form of @c yield is used to explicitly terminate the coroutine.
 * This form is comprised of two steps:
 *
 * @li @c yield sets the coroutine state to indicate termination.
 * @li Control is transferred to the end of the coroutine body.
 *
 * Once terminated, calls to is_complete() return true and the coroutine cannot
 * be reentered.
 *
 * Note that a coroutine may also be implicitly terminated if the coroutine
 * body is exited without a yield, e.g. by return, throw or by running to the
 * end of the body.
 *
 * <b>fork <em>statement</em></b>
 *
 * The @c fork pseudo-keyword is used when "forking" a coroutine, i.e. splitting
 * it into two (or more) copies. One use of @c fork is in a server, where a new
 * coroutine is created to handle each client connection:
 * 
 * @code reenter (this)
 * {
 *   do
 *   {
 *     socket_.reset(new tcp::socket(my_context_));
 *     yield acceptor->async_accept(*socket_, *this);
 *     fork server(*this)();
 *   } while (is_parent());
 *   ... client-specific handling follows ...
 * } @endcode
 * 
 * The logical steps involved in a @c fork are:
 * 
 * @li @c fork saves the current state of the coroutine.
 * @li The statement creates a copy of the coroutine and either executes it
 *     immediately or schedules it for later execution.
 * @li The resume point is defined immediately following the semicolon.
 * @li For the "parent", control immediately continues from the next line.
 *
 * The functions is_parent() and is_child() can be used to differentiate
 * between parent and child. You would use these functions to alter subsequent
 * control flow.
 *
 * Note that @c fork doesn't do the actual forking by itself. It is the
 * application's responsibility to create a clone of the coroutine and call it.
 * The clone can be called immediately, as above, or scheduled for delayed
 * execution using something like asio::post().
 *
 * @par Alternate macro names
 *
 * If preferred, an application can use macro names that follow a more typical
 * naming convention, rather than the pseudo-keywords. These are:
 *
 * @li @c ASIO_CORO_REENTER instead of @c reenter
 * @li @c ASIO_CORO_YIELD instead of @c yield
 * @li @c ASIO_CORO_FORK instead of @c fork
 */
 class coroutine
 {
 public:
  /// Constructs a coroutine in its initial state.
  coroutine() : value_(0) {}
  /// Returns true if the coroutine is the child of a fork.
  bool is_child() const { return value_ < 0; }
  /// Returns true if the coroutine is the parent of a fork.
  bool is_parent() const { return !is_child(); }
  /// Returns true if the coroutine has reached its terminal state.
  bool is_complete() const { return value_ == -1; }
 private:
  friend class detail::coroutine_ref;
  int value_;
 };
 namespace detail {
 class coroutine_ref
 {
 public:
  coroutine_ref(coroutine& c) : value_(c.value_), modified_(false) {}
  coroutine_ref(coroutine* c) : value_(c->value_), modified_(false) {}
  ~coroutine_ref() { if (!modified_) value_ = -1; }
  operator int() const { return value_; }
  int& operator=(int v) { modified_ = true; return value_ = v; }
 private:
  void operator=(const coroutine_ref&);
  int& value_;
  bool modified_;
 };
 } // namespace detail
 } // namespace asio
 #define ASIO_CORO_REENTER(c) \
  switch (::asio::detail::coroutine_ref _coro_value = c) \
    case -1: if (_coro_value) \
    { \
      goto terminate_coroutine; \
      terminate_coroutine: \
      _coro_value = -1; \
      goto bail_out_of_coroutine; \
      bail_out_of_coroutine: \
      break; \
    } \
    else /* fall-through */ case 0:
 #define ASIO_CORO_YIELD_IMPL(n) \
  for (_coro_value = (n);;) \
    if (_coro_value == 0) \
    { \
      case (n): ; \
      break; \
    } \
    else \
      switch (_coro_value ? 0 : 1) \
        for (;;) \
          /* fall-through */ case -1: if (_coro_value) \
            goto terminate_coroutine; \
          else for (;;) \
            /* fall-through */ case 1: if (_coro_value) \
              goto bail_out_of_coroutine; \
            else /* fall-through */ case 0:
 #define ASIO_CORO_FORK_IMPL(n) \
  for (_coro_value = -(n);; _coro_value = (n)) \
    if (_coro_value == (n)) \
    { \
      case -(n): ; \
      break; \
    } \
    else
 #if defined(_MSC_VER)
 # define ASIO_CORO_YIELD ASIO_CORO_YIELD_IMPL(__COUNTER__ + 1)
 # define ASIO_CORO_FORK ASIO_CORO_FORK_IMPL(__COUNTER__ + 1)
 #else // defined(_MSC_VER)
 # define ASIO_CORO_YIELD ASIO_CORO_YIELD_IMPL(__LINE__)
 # define ASIO_CORO_FORK ASIO_CORO_FORK_IMPL(__LINE__)
 #endif // defined(_MSC_VER)
 #endif // ASIO_COROUTINE_HPP
--- a/module/Vendor/ASIO/include/asio/deadline_timer.hpp
+++ b/module/Vendor/ASIO/include/asio/deadline_timer.hpp
@ -0,0 +1,38 @@
 //
 // deadline_timer.hpp
 // ~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DEADLINE_TIMER_HPP
 #define ASIO_DEADLINE_TIMER_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if defined(ASIO_HAS_BOOST_DATE_TIME) \
  || defined(GENERATING_DOCUMENTATION)
 #include "asio/detail/socket_types.hpp" // Must come before posix_time.
 #include "asio/basic_deadline_timer.hpp"
 #include <boost/date_time/posix_time/posix_time_types.hpp>
 namespace asio {
 /// Typedef for the typical usage of timer. Uses a UTC clock.
 typedef basic_deadline_timer<boost::posix_time::ptime> deadline_timer;
 } // namespace asio
 #endif // defined(ASIO_HAS_BOOST_DATE_TIME)
       // || defined(GENERATING_DOCUMENTATION)
 #endif // ASIO_DEADLINE_TIMER_HPP
--- a/module/Vendor/ASIO/include/asio/defer.hpp
+++ b/module/Vendor/ASIO/include/asio/defer.hpp
@ -0,0 +1,130 @@
 //
 // defer.hpp
 // ~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DEFER_HPP
 #define ASIO_DEFER_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/async_result.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/execution_context.hpp"
 #include "asio/execution/executor.hpp"
 #include "asio/is_executor.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 /// Submits a completion token or function object for execution.
 /**
 * This function submits an object for execution using the object's associated
 * executor. The function object is queued for execution, and is never called
 * from the current thread prior to returning from <tt>defer()</tt>.
 *
 * The use of @c defer(), rather than @ref post(), indicates the caller's
 * preference that the executor defer the queueing of the function object. This
 * may allow the executor to optimise queueing for cases when the function
 * object represents a continuation of the current call context.
 *
 * This function has the following effects:
 *
 * @li Constructs a function object handler of type @c Handler, initialized
 * with <tt>handler(forward<CompletionToken>(token))</tt>.
 *
 * @li Constructs an object @c result of type <tt>async_result<Handler></tt>,
 * initializing the object as <tt>result(handler)</tt>.
 *
 * @li Obtains the handler's associated executor object @c ex by performing
 * <tt>get_associated_executor(handler)</tt>.
 *
 * @li Obtains the handler's associated allocator object @c alloc by performing
 * <tt>get_associated_allocator(handler)</tt>.
 *
 * @li Performs <tt>ex.defer(std::move(handler), alloc)</tt>.
 *
 * @li Returns <tt>result.get()</tt>.
 */
 template <ASIO_COMPLETION_TOKEN_FOR(void()) CompletionToken>
 ASIO_INITFN_AUTO_RESULT_TYPE(CompletionToken, void()) defer(
    ASIO_MOVE_ARG(CompletionToken) token);
 /// Submits a completion token or function object for execution.
 /**
 * This function submits an object for execution using the specified executor.
 * The function object is queued for execution, and is never called from the
 * current thread prior to returning from <tt>defer()</tt>.
 *
 * The use of @c defer(), rather than @ref post(), indicates the caller's
 * preference that the executor defer the queueing of the function object. This
 * may allow the executor to optimise queueing for cases when the function
 * object represents a continuation of the current call context.
 *
 * This function has the following effects:
 *
 * @li Constructs a function object handler of type @c Handler, initialized
 * with <tt>handler(forward<CompletionToken>(token))</tt>.
 *
 * @li Constructs an object @c result of type <tt>async_result<Handler></tt>,
 * initializing the object as <tt>result(handler)</tt>.
 *
 * @li Obtains the handler's associated executor object @c ex1 by performing
 * <tt>get_associated_executor(handler)</tt>.
 *
 * @li Creates a work object @c w by performing <tt>make_work(ex1)</tt>.
 *
 * @li Obtains the handler's associated allocator object @c alloc by performing
 * <tt>get_associated_allocator(handler)</tt>.
 *
 * @li Constructs a function object @c f with a function call operator that
 * performs <tt>ex1.dispatch(std::move(handler), alloc)</tt> followed by
 * <tt>w.reset()</tt>.
 *
 * @li Performs <tt>Executor(ex).defer(std::move(f), alloc)</tt>.
 *
 * @li Returns <tt>result.get()</tt>.
 */
 template <typename Executor,
    ASIO_COMPLETION_TOKEN_FOR(void()) CompletionToken
      ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(Executor)>
 ASIO_INITFN_AUTO_RESULT_TYPE(CompletionToken, void()) defer(
    const Executor& ex,
    ASIO_MOVE_ARG(CompletionToken) token
      ASIO_DEFAULT_COMPLETION_TOKEN(Executor),
    typename enable_if<
      execution::is_executor<Executor>::value || is_executor<Executor>::value
    >::type* = 0);
 /// Submits a completion token or function object for execution.
 /**
 * @returns <tt>defer(ctx.get_executor(), forward<CompletionToken>(token))</tt>.
 */
 template <typename ExecutionContext,
    ASIO_COMPLETION_TOKEN_FOR(void()) CompletionToken
      ASIO_DEFAULT_COMPLETION_TOKEN_TYPE(
        typename ExecutionContext::executor_type)>
 ASIO_INITFN_AUTO_RESULT_TYPE(CompletionToken, void()) defer(
    ExecutionContext& ctx,
    ASIO_MOVE_ARG(CompletionToken) token
      ASIO_DEFAULT_COMPLETION_TOKEN(
        typename ExecutionContext::executor_type),
    typename enable_if<is_convertible<
      ExecutionContext&, execution_context&>::value>::type* = 0);
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #include "asio/impl/defer.hpp"
 #endif // ASIO_DEFER_HPP
--- a/module/Vendor/ASIO/include/asio/detached.hpp
+++ b/module/Vendor/ASIO/include/asio/detached.hpp
@ -0,0 +1,112 @@
 //
 // detached.hpp
 // ~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETACHED_HPP
 #define ASIO_DETACHED_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include <memory>
 #include "asio/detail/type_traits.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 /// Class used to specify that an asynchronous operation is detached.
 /**
 * The detached_t class is used to indicate that an asynchronous operation is
 * detached. That is, there is no completion handler waiting for the
 * operation's result. A detached_t object may be passed as a handler to an
 * asynchronous operation, typically using the special value
 * @c asio::detached. For example:
 * @code my_socket.async_send(my_buffer, asio::detached);
 * @endcode
 */
 class detached_t
 {
 public:
  /// Constructor. 
  ASIO_CONSTEXPR detached_t()
  {
  }
  /// Adapts an executor to add the @c detached_t completion token as the
  /// default.
  template <typename InnerExecutor>
  struct executor_with_default : InnerExecutor
  {
    /// Specify @c detached_t as the default completion token type.
    typedef detached_t default_completion_token_type;
    /// Construct the adapted executor from the inner executor type.
    executor_with_default(const InnerExecutor& ex) ASIO_NOEXCEPT
      : InnerExecutor(ex)
    {
    }
    /// Convert the specified executor to the inner executor type, then use
    /// that to construct the adapted executor.
    template <typename OtherExecutor>
    executor_with_default(const OtherExecutor& ex,
        typename enable_if<
          is_convertible<OtherExecutor, InnerExecutor>::value
        >::type* = 0) ASIO_NOEXCEPT
      : InnerExecutor(ex)
    {
    }
  };
  /// Type alias to adapt an I/O object to use @c detached_t as its
  /// default completion token type.
 #if defined(ASIO_HAS_ALIAS_TEMPLATES) \
  || defined(GENERATING_DOCUMENTATION)
  template <typename T>
  using as_default_on_t = typename T::template rebind_executor<
      executor_with_default<typename T::executor_type> >::other;
 #endif // defined(ASIO_HAS_ALIAS_TEMPLATES)
       //   || defined(GENERATING_DOCUMENTATION)
  /// Function helper to adapt an I/O object to use @c detached_t as its
  /// default completion token type.
  template <typename T>
  static typename decay<T>::type::template rebind_executor<
      executor_with_default<typename decay<T>::type::executor_type>
    >::other
  as_default_on(ASIO_MOVE_ARG(T) object)
  {
    return typename decay<T>::type::template rebind_executor<
        executor_with_default<typename decay<T>::type::executor_type>
      >::other(ASIO_MOVE_CAST(T)(object));
  }
 };
 /// A special value, similar to std::nothrow.
 /**
 * See the documentation for asio::detached_t for a usage example.
 */
 #if defined(ASIO_HAS_CONSTEXPR) || defined(GENERATING_DOCUMENTATION)
 constexpr detached_t detached;
 #elif defined(ASIO_MSVC)
 __declspec(selectany) detached_t detached;
 #endif
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #include "asio/impl/detached.hpp"
 #endif // ASIO_DETACHED_HPP
--- a/module/Vendor/ASIO/include/asio/detail/array.hpp
+++ b/module/Vendor/ASIO/include/asio/detail/array.hpp
@ -0,0 +1,38 @@
 //
 // detail/array.hpp
 // ~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETAIL_ARRAY_HPP
 #define ASIO_DETAIL_ARRAY_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if defined(ASIO_HAS_STD_ARRAY)
 # include <array>
 #else // defined(ASIO_HAS_STD_ARRAY)
 # include <boost/array.hpp>
 #endif // defined(ASIO_HAS_STD_ARRAY)
 namespace asio {
 namespace detail {
 #if defined(ASIO_HAS_STD_ARRAY)
 using std::array;
 #else // defined(ASIO_HAS_STD_ARRAY)
 using boost::array;
 #endif // defined(ASIO_HAS_STD_ARRAY)
 } // namespace detail
 } // namespace asio
 #endif // ASIO_DETAIL_ARRAY_HPP
--- a/module/Vendor/ASIO/include/asio/detail/array_fwd.hpp
+++ b/module/Vendor/ASIO/include/asio/detail/array_fwd.hpp
@ -0,0 +1,34 @@
 //
 // detail/array_fwd.hpp
 // ~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETAIL_ARRAY_FWD_HPP
 #define ASIO_DETAIL_ARRAY_FWD_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 namespace boost {
 template<class T, std::size_t N>
 class array;
 } // namespace boost
 // Standard library components can't be forward declared, so we'll have to
 // include the array header. Fortunately, it's fairly lightweight and doesn't
 // add significantly to the compile time.
 #if defined(ASIO_HAS_STD_ARRAY)
 # include <array>
 #endif // defined(ASIO_HAS_STD_ARRAY)
 #endif // ASIO_DETAIL_ARRAY_FWD_HPP
--- a/module/Vendor/ASIO/include/asio/detail/assert.hpp
+++ b/module/Vendor/ASIO/include/asio/detail/assert.hpp
@ -0,0 +1,32 @@
 //
 // detail/assert.hpp
 // ~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETAIL_ASSERT_HPP
 #define ASIO_DETAIL_ASSERT_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if defined(ASIO_HAS_BOOST_ASSERT)
 # include <boost/assert.hpp>
 #else // defined(ASIO_HAS_BOOST_ASSERT)
 # include <cassert>
 #endif // defined(ASIO_HAS_BOOST_ASSERT)
 #if defined(ASIO_HAS_BOOST_ASSERT)
 # define ASIO_ASSERT(expr) BOOST_ASSERT(expr)
 #else // defined(ASIO_HAS_BOOST_ASSERT)
 # define ASIO_ASSERT(expr) assert(expr)
 #endif // defined(ASIO_HAS_BOOST_ASSERT)
 #endif // ASIO_DETAIL_ASSERT_HPP
--- a/module/Vendor/ASIO/include/asio/detail/atomic_count.hpp
+++ b/module/Vendor/ASIO/include/asio/detail/atomic_count.hpp
@ -0,0 +1,64 @@
 //
 // detail/atomic_count.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETAIL_ATOMIC_COUNT_HPP
 #define ASIO_DETAIL_ATOMIC_COUNT_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #if !defined(ASIO_HAS_THREADS)
 // Nothing to include.
 #elif defined(ASIO_HAS_STD_ATOMIC)
 # include <atomic>
 #else // defined(ASIO_HAS_STD_ATOMIC)
 # include <boost/detail/atomic_count.hpp>
 #endif // defined(ASIO_HAS_STD_ATOMIC)
 namespace asio {
 namespace detail {
 #if !defined(ASIO_HAS_THREADS)
 typedef long atomic_count;
 inline void increment(atomic_count& a, long b) { a += b; }
 inline void ref_count_up(atomic_count& a) { ++a; }
 inline bool ref_count_down(atomic_count& a) { return --a == 0; }
 #elif defined(ASIO_HAS_STD_ATOMIC)
 typedef std::atomic<long> atomic_count;
 inline void increment(atomic_count& a, long b) { a += b; }
 inline void ref_count_up(atomic_count& a)
 {
  a.fetch_add(1, std::memory_order_relaxed);
 }
 inline bool ref_count_down(atomic_count& a)
 {
  if (a.fetch_sub(1, std::memory_order_release) == 1)
  {
    std::atomic_thread_fence(std::memory_order_acquire);
    return true;
  }
  return false;
 }
 #else // defined(ASIO_HAS_STD_ATOMIC)
 typedef boost::detail::atomic_count atomic_count;
 inline void increment(atomic_count& a, long b) { while (b > 0) ++a, --b; }
 inline void ref_count_up(atomic_count& a) { ++a; }
 inline bool ref_count_down(atomic_count& a) { return --a == 0; }
 #endif // defined(ASIO_HAS_STD_ATOMIC)
 } // namespace detail
 } // namespace asio
 #endif // ASIO_DETAIL_ATOMIC_COUNT_HPP
--- a/module/Vendor/ASIO/include/asio/detail/base_from_completion_cond.hpp
+++ b/module/Vendor/ASIO/include/asio/detail/base_from_completion_cond.hpp
@ -0,0 +1,69 @@
 //
 // detail/base_from_completion_cond.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETAIL_BASE_FROM_COMPLETION_COND_HPP
 #define ASIO_DETAIL_BASE_FROM_COMPLETION_COND_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/completion_condition.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 template <typename CompletionCondition>
 class base_from_completion_cond
 {
 protected:
  explicit base_from_completion_cond(CompletionCondition& completion_condition)
    : completion_condition_(
        ASIO_MOVE_CAST(CompletionCondition)(completion_condition))
  {
  }
  std::size_t check_for_completion(
      const asio::error_code& ec,
      std::size_t total_transferred)
  {
    return detail::adapt_completion_condition_result(
        completion_condition_(ec, total_transferred));
  }
 private:
  CompletionCondition completion_condition_;
 };
 template <>
 class base_from_completion_cond<transfer_all_t>
 {
 protected:
  explicit base_from_completion_cond(transfer_all_t)
  {
  }
  static std::size_t check_for_completion(
      const asio::error_code& ec,
      std::size_t total_transferred)
  {
    return transfer_all_t()(ec, total_transferred);
  }
 };
 } // namespace detail
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_DETAIL_BASE_FROM_COMPLETION_COND_HPP
--- a/module/Vendor/ASIO/include/asio/detail/bind_handler.hpp
+++ b/module/Vendor/ASIO/include/asio/detail/bind_handler.hpp
@ -0,0 +1,938 @@
 //
 // detail/bind_handler.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETAIL_BIND_HANDLER_HPP
 #define ASIO_DETAIL_BIND_HANDLER_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/associated_allocator.hpp"
 #include "asio/associated_executor.hpp"
 #include "asio/detail/handler_alloc_helpers.hpp"
 #include "asio/detail/handler_cont_helpers.hpp"
 #include "asio/detail/handler_invoke_helpers.hpp"
 #include "asio/detail/type_traits.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 template <typename Handler, typename Arg1>
 class binder1
 {
 public:
  template <typename T>
  binder1(int, ASIO_MOVE_ARG(T) handler, const Arg1& arg1)
    : handler_(ASIO_MOVE_CAST(T)(handler)),
      arg1_(arg1)
  {
  }
  binder1(Handler& handler, const Arg1& arg1)
    : handler_(ASIO_MOVE_CAST(Handler)(handler)),
      arg1_(arg1)
  {
  }
 #if defined(ASIO_HAS_MOVE)
  binder1(const binder1& other)
    : handler_(other.handler_),
      arg1_(other.arg1_)
  {
  }
  binder1(binder1&& other)
    : handler_(ASIO_MOVE_CAST(Handler)(other.handler_)),
      arg1_(ASIO_MOVE_CAST(Arg1)(other.arg1_))
  {
  }
 #endif // defined(ASIO_HAS_MOVE)
  void operator()()
  {
    handler_(static_cast<const Arg1&>(arg1_));
  }
  void operator()() const
  {
    handler_(arg1_);
  }
 //private:
  Handler handler_;
  Arg1 arg1_;
 };
 template <typename Handler, typename Arg1>
 inline asio_handler_allocate_is_deprecated
 asio_handler_allocate(std::size_t size,
    binder1<Handler, Arg1>* this_handler)
 {
 #if defined(ASIO_NO_DEPRECATED)
  asio_handler_alloc_helpers::allocate(size, this_handler->handler_);
  return asio_handler_allocate_is_no_longer_used();
 #else // defined(ASIO_NO_DEPRECATED)
  return asio_handler_alloc_helpers::allocate(
      size, this_handler->handler_);
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1>
 inline asio_handler_deallocate_is_deprecated
 asio_handler_deallocate(void* pointer, std::size_t size,
    binder1<Handler, Arg1>* this_handler)
 {
  asio_handler_alloc_helpers::deallocate(
      pointer, size, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_deallocate_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1>
 inline bool asio_handler_is_continuation(
    binder1<Handler, Arg1>* this_handler)
 {
  return asio_handler_cont_helpers::is_continuation(
      this_handler->handler_);
 }
 template <typename Function, typename Handler, typename Arg1>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(Function& function,
    binder1<Handler, Arg1>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Function, typename Handler, typename Arg1>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(const Function& function,
    binder1<Handler, Arg1>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1>
 inline binder1<typename decay<Handler>::type, Arg1> bind_handler(
    ASIO_MOVE_ARG(Handler) handler, const Arg1& arg1)
 {
  return binder1<typename decay<Handler>::type, Arg1>(0,
      ASIO_MOVE_CAST(Handler)(handler), arg1);
 }
 template <typename Handler, typename Arg1, typename Arg2>
 class binder2
 {
 public:
  template <typename T>
  binder2(int, ASIO_MOVE_ARG(T) handler,
      const Arg1& arg1, const Arg2& arg2)
    : handler_(ASIO_MOVE_CAST(T)(handler)),
      arg1_(arg1),
      arg2_(arg2)
  {
  }
  binder2(Handler& handler, const Arg1& arg1, const Arg2& arg2)
    : handler_(ASIO_MOVE_CAST(Handler)(handler)),
      arg1_(arg1),
      arg2_(arg2)
  {
  }
 #if defined(ASIO_HAS_MOVE)
  binder2(const binder2& other)
    : handler_(other.handler_),
      arg1_(other.arg1_),
      arg2_(other.arg2_)
  {
  }
  binder2(binder2&& other)
    : handler_(ASIO_MOVE_CAST(Handler)(other.handler_)),
      arg1_(ASIO_MOVE_CAST(Arg1)(other.arg1_)),
      arg2_(ASIO_MOVE_CAST(Arg2)(other.arg2_))
  {
  }
 #endif // defined(ASIO_HAS_MOVE)
  void operator()()
  {
    handler_(static_cast<const Arg1&>(arg1_),
        static_cast<const Arg2&>(arg2_));
  }
  void operator()() const
  {
    handler_(arg1_, arg2_);
  }
 //private:
  Handler handler_;
  Arg1 arg1_;
  Arg2 arg2_;
 };
 template <typename Handler, typename Arg1, typename Arg2>
 inline asio_handler_allocate_is_deprecated
 asio_handler_allocate(std::size_t size,
    binder2<Handler, Arg1, Arg2>* this_handler)
 {
 #if defined(ASIO_NO_DEPRECATED)
  asio_handler_alloc_helpers::allocate(size, this_handler->handler_);
  return asio_handler_allocate_is_no_longer_used();
 #else // defined(ASIO_NO_DEPRECATED)
  return asio_handler_alloc_helpers::allocate(
      size, this_handler->handler_);
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2>
 inline asio_handler_deallocate_is_deprecated
 asio_handler_deallocate(void* pointer, std::size_t size,
    binder2<Handler, Arg1, Arg2>* this_handler)
 {
  asio_handler_alloc_helpers::deallocate(
      pointer, size, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_deallocate_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2>
 inline bool asio_handler_is_continuation(
    binder2<Handler, Arg1, Arg2>* this_handler)
 {
  return asio_handler_cont_helpers::is_continuation(
      this_handler->handler_);
 }
 template <typename Function, typename Handler, typename Arg1, typename Arg2>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(Function& function,
    binder2<Handler, Arg1, Arg2>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Function, typename Handler, typename Arg1, typename Arg2>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(const Function& function,
    binder2<Handler, Arg1, Arg2>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2>
 inline binder2<typename decay<Handler>::type, Arg1, Arg2> bind_handler(
    ASIO_MOVE_ARG(Handler) handler, const Arg1& arg1, const Arg2& arg2)
 {
  return binder2<typename decay<Handler>::type, Arg1, Arg2>(0,
      ASIO_MOVE_CAST(Handler)(handler), arg1, arg2);
 }
 template <typename Handler, typename Arg1, typename Arg2, typename Arg3>
 class binder3
 {
 public:
  template <typename T>
  binder3(int, ASIO_MOVE_ARG(T) handler, const Arg1& arg1,
      const Arg2& arg2, const Arg3& arg3)
    : handler_(ASIO_MOVE_CAST(T)(handler)),
      arg1_(arg1),
      arg2_(arg2),
      arg3_(arg3)
  {
  }
  binder3(Handler& handler, const Arg1& arg1,
      const Arg2& arg2, const Arg3& arg3)
    : handler_(ASIO_MOVE_CAST(Handler)(handler)),
      arg1_(arg1),
      arg2_(arg2),
      arg3_(arg3)
  {
  }
 #if defined(ASIO_HAS_MOVE)
  binder3(const binder3& other)
    : handler_(other.handler_),
      arg1_(other.arg1_),
      arg2_(other.arg2_),
      arg3_(other.arg3_)
  {
  }
  binder3(binder3&& other)
    : handler_(ASIO_MOVE_CAST(Handler)(other.handler_)),
      arg1_(ASIO_MOVE_CAST(Arg1)(other.arg1_)),
      arg2_(ASIO_MOVE_CAST(Arg2)(other.arg2_)),
      arg3_(ASIO_MOVE_CAST(Arg3)(other.arg3_))
  {
  }
 #endif // defined(ASIO_HAS_MOVE)
  void operator()()
  {
    handler_(static_cast<const Arg1&>(arg1_),
        static_cast<const Arg2&>(arg2_), static_cast<const Arg3&>(arg3_));
  }
  void operator()() const
  {
    handler_(arg1_, arg2_, arg3_);
  }
 //private:
  Handler handler_;
  Arg1 arg1_;
  Arg2 arg2_;
  Arg3 arg3_;
 };
 template <typename Handler, typename Arg1, typename Arg2, typename Arg3>
 inline asio_handler_allocate_is_deprecated
 asio_handler_allocate(std::size_t size,
    binder3<Handler, Arg1, Arg2, Arg3>* this_handler)
 {
 #if defined(ASIO_NO_DEPRECATED)
  asio_handler_alloc_helpers::allocate(size, this_handler->handler_);
  return asio_handler_allocate_is_no_longer_used();
 #else // defined(ASIO_NO_DEPRECATED)
  return asio_handler_alloc_helpers::allocate(
      size, this_handler->handler_);
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2, typename Arg3>
 inline asio_handler_deallocate_is_deprecated
 asio_handler_deallocate(void* pointer, std::size_t size,
    binder3<Handler, Arg1, Arg2, Arg3>* this_handler)
 {
  asio_handler_alloc_helpers::deallocate(
      pointer, size, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_deallocate_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2, typename Arg3>
 inline bool asio_handler_is_continuation(
    binder3<Handler, Arg1, Arg2, Arg3>* this_handler)
 {
  return asio_handler_cont_helpers::is_continuation(
      this_handler->handler_);
 }
 template <typename Function, typename Handler,
    typename Arg1, typename Arg2, typename Arg3>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(Function& function,
    binder3<Handler, Arg1, Arg2, Arg3>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Function, typename Handler,
    typename Arg1, typename Arg2, typename Arg3>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(const Function& function,
    binder3<Handler, Arg1, Arg2, Arg3>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2, typename Arg3>
 inline binder3<typename decay<Handler>::type, Arg1, Arg2, Arg3> bind_handler(
    ASIO_MOVE_ARG(Handler) handler, const Arg1& arg1, const Arg2& arg2,
    const Arg3& arg3)
 {
  return binder3<typename decay<Handler>::type, Arg1, Arg2, Arg3>(0,
      ASIO_MOVE_CAST(Handler)(handler), arg1, arg2, arg3);
 }
 template <typename Handler, typename Arg1,
    typename Arg2, typename Arg3, typename Arg4>
 class binder4
 {
 public:
  template <typename T>
  binder4(int, ASIO_MOVE_ARG(T) handler, const Arg1& arg1,
      const Arg2& arg2, const Arg3& arg3, const Arg4& arg4)
    : handler_(ASIO_MOVE_CAST(T)(handler)),
      arg1_(arg1),
      arg2_(arg2),
      arg3_(arg3),
      arg4_(arg4)
  {
  }
  binder4(Handler& handler, const Arg1& arg1,
      const Arg2& arg2, const Arg3& arg3, const Arg4& arg4)
    : handler_(ASIO_MOVE_CAST(Handler)(handler)),
      arg1_(arg1),
      arg2_(arg2),
      arg3_(arg3),
      arg4_(arg4)
  {
  }
 #if defined(ASIO_HAS_MOVE)
  binder4(const binder4& other)
    : handler_(other.handler_),
      arg1_(other.arg1_),
      arg2_(other.arg2_),
      arg3_(other.arg3_),
      arg4_(other.arg4_)
  {
  }
  binder4(binder4&& other)
    : handler_(ASIO_MOVE_CAST(Handler)(other.handler_)),
      arg1_(ASIO_MOVE_CAST(Arg1)(other.arg1_)),
      arg2_(ASIO_MOVE_CAST(Arg2)(other.arg2_)),
      arg3_(ASIO_MOVE_CAST(Arg3)(other.arg3_)),
      arg4_(ASIO_MOVE_CAST(Arg4)(other.arg4_))
  {
  }
 #endif // defined(ASIO_HAS_MOVE)
  void operator()()
  {
    handler_(static_cast<const Arg1&>(arg1_),
        static_cast<const Arg2&>(arg2_), static_cast<const Arg3&>(arg3_),
        static_cast<const Arg4&>(arg4_));
  }
  void operator()() const
  {
    handler_(arg1_, arg2_, arg3_, arg4_);
  }
 //private:
  Handler handler_;
  Arg1 arg1_;
  Arg2 arg2_;
  Arg3 arg3_;
  Arg4 arg4_;
 };
 template <typename Handler, typename Arg1,
    typename Arg2, typename Arg3, typename Arg4>
 inline asio_handler_allocate_is_deprecated
 asio_handler_allocate(std::size_t size,
    binder4<Handler, Arg1, Arg2, Arg3, Arg4>* this_handler)
 {
 #if defined(ASIO_NO_DEPRECATED)
  asio_handler_alloc_helpers::allocate(size, this_handler->handler_);
  return asio_handler_allocate_is_no_longer_used();
 #else // defined(ASIO_NO_DEPRECATED)
  return asio_handler_alloc_helpers::allocate(
      size, this_handler->handler_);
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1,
    typename Arg2, typename Arg3, typename Arg4>
 inline asio_handler_deallocate_is_deprecated
 asio_handler_deallocate(void* pointer, std::size_t size,
    binder4<Handler, Arg1, Arg2, Arg3, Arg4>* this_handler)
 {
  asio_handler_alloc_helpers::deallocate(
      pointer, size, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_deallocate_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1,
    typename Arg2, typename Arg3, typename Arg4>
 inline bool asio_handler_is_continuation(
    binder4<Handler, Arg1, Arg2, Arg3, Arg4>* this_handler)
 {
  return asio_handler_cont_helpers::is_continuation(
      this_handler->handler_);
 }
 template <typename Function, typename Handler, typename Arg1,
    typename Arg2, typename Arg3, typename Arg4>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(Function& function,
    binder4<Handler, Arg1, Arg2, Arg3, Arg4>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Function, typename Handler, typename Arg1,
    typename Arg2, typename Arg3, typename Arg4>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(const Function& function,
    binder4<Handler, Arg1, Arg2, Arg3, Arg4>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1,
    typename Arg2, typename Arg3, typename Arg4>
 inline binder4<typename decay<Handler>::type, Arg1, Arg2, Arg3, Arg4>
 bind_handler(ASIO_MOVE_ARG(Handler) handler, const Arg1& arg1,
    const Arg2& arg2, const Arg3& arg3, const Arg4& arg4)
 {
  return binder4<typename decay<Handler>::type, Arg1, Arg2, Arg3, Arg4>(0,
      ASIO_MOVE_CAST(Handler)(handler), arg1, arg2, arg3, arg4);
 }
 template <typename Handler, typename Arg1, typename Arg2,
    typename Arg3, typename Arg4, typename Arg5>
 class binder5
 {
 public:
  template <typename T>
  binder5(int, ASIO_MOVE_ARG(T) handler, const Arg1& arg1,
      const Arg2& arg2, const Arg3& arg3, const Arg4& arg4, const Arg5& arg5)
    : handler_(ASIO_MOVE_CAST(T)(handler)),
      arg1_(arg1),
      arg2_(arg2),
      arg3_(arg3),
      arg4_(arg4),
      arg5_(arg5)
  {
  }
  binder5(Handler& handler, const Arg1& arg1, const Arg2& arg2,
      const Arg3& arg3, const Arg4& arg4, const Arg5& arg5)
    : handler_(ASIO_MOVE_CAST(Handler)(handler)),
      arg1_(arg1),
      arg2_(arg2),
      arg3_(arg3),
      arg4_(arg4),
      arg5_(arg5)
  {
  }
 #if defined(ASIO_HAS_MOVE)
  binder5(const binder5& other)
    : handler_(other.handler_),
      arg1_(other.arg1_),
      arg2_(other.arg2_),
      arg3_(other.arg3_),
      arg4_(other.arg4_),
      arg5_(other.arg5_)
  {
  }
  binder5(binder5&& other)
    : handler_(ASIO_MOVE_CAST(Handler)(other.handler_)),
      arg1_(ASIO_MOVE_CAST(Arg1)(other.arg1_)),
      arg2_(ASIO_MOVE_CAST(Arg2)(other.arg2_)),
      arg3_(ASIO_MOVE_CAST(Arg3)(other.arg3_)),
      arg4_(ASIO_MOVE_CAST(Arg4)(other.arg4_)),
      arg5_(ASIO_MOVE_CAST(Arg5)(other.arg5_))
  {
  }
 #endif // defined(ASIO_HAS_MOVE)
  void operator()()
  {
    handler_(static_cast<const Arg1&>(arg1_),
        static_cast<const Arg2&>(arg2_), static_cast<const Arg3&>(arg3_),
        static_cast<const Arg4&>(arg4_), static_cast<const Arg5&>(arg5_));
  }
  void operator()() const
  {
    handler_(arg1_, arg2_, arg3_, arg4_, arg5_);
  }
 //private:
  Handler handler_;
  Arg1 arg1_;
  Arg2 arg2_;
  Arg3 arg3_;
  Arg4 arg4_;
  Arg5 arg5_;
 };
 template <typename Handler, typename Arg1, typename Arg2,
    typename Arg3, typename Arg4, typename Arg5>
 inline asio_handler_allocate_is_deprecated
 asio_handler_allocate(std::size_t size,
    binder5<Handler, Arg1, Arg2, Arg3, Arg4, Arg5>* this_handler)
 {
 #if defined(ASIO_NO_DEPRECATED)
  asio_handler_alloc_helpers::allocate(size, this_handler->handler_);
  return asio_handler_allocate_is_no_longer_used();
 #else // defined(ASIO_NO_DEPRECATED)
  return asio_handler_alloc_helpers::allocate(
      size, this_handler->handler_);
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2,
    typename Arg3, typename Arg4, typename Arg5>
 inline asio_handler_deallocate_is_deprecated
 asio_handler_deallocate(void* pointer, std::size_t size,
    binder5<Handler, Arg1, Arg2, Arg3, Arg4, Arg5>* this_handler)
 {
  asio_handler_alloc_helpers::deallocate(
      pointer, size, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_deallocate_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2,
    typename Arg3, typename Arg4, typename Arg5>
 inline bool asio_handler_is_continuation(
    binder5<Handler, Arg1, Arg2, Arg3, Arg4, Arg5>* this_handler)
 {
  return asio_handler_cont_helpers::is_continuation(
      this_handler->handler_);
 }
 template <typename Function, typename Handler, typename Arg1,
    typename Arg2, typename Arg3, typename Arg4, typename Arg5>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(Function& function,
    binder5<Handler, Arg1, Arg2, Arg3, Arg4, Arg5>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Function, typename Handler, typename Arg1,
    typename Arg2, typename Arg3, typename Arg4, typename Arg5>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(const Function& function,
    binder5<Handler, Arg1, Arg2, Arg3, Arg4, Arg5>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      function, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2,
    typename Arg3, typename Arg4, typename Arg5>
 inline binder5<typename decay<Handler>::type, Arg1, Arg2, Arg3, Arg4, Arg5>
 bind_handler(ASIO_MOVE_ARG(Handler) handler, const Arg1& arg1,
    const Arg2& arg2, const Arg3& arg3, const Arg4& arg4, const Arg5& arg5)
 {
  return binder5<typename decay<Handler>::type, Arg1, Arg2, Arg3, Arg4, Arg5>(0,
      ASIO_MOVE_CAST(Handler)(handler), arg1, arg2, arg3, arg4, arg5);
 }
 #if defined(ASIO_HAS_MOVE)
 template <typename Handler, typename Arg1>
 class move_binder1
 {
 public:
  move_binder1(int, ASIO_MOVE_ARG(Handler) handler,
      ASIO_MOVE_ARG(Arg1) arg1)
    : handler_(ASIO_MOVE_CAST(Handler)(handler)),
      arg1_(ASIO_MOVE_CAST(Arg1)(arg1))
  {
  }
  move_binder1(move_binder1&& other)
    : handler_(ASIO_MOVE_CAST(Handler)(other.handler_)),
      arg1_(ASIO_MOVE_CAST(Arg1)(other.arg1_))
  {
  }
  void operator()()
  {
    handler_(ASIO_MOVE_CAST(Arg1)(arg1_));
  }
 //private:
  Handler handler_;
  Arg1 arg1_;
 };
 template <typename Handler, typename Arg1>
 inline asio_handler_allocate_is_deprecated
 asio_handler_allocate(std::size_t size,
    move_binder1<Handler, Arg1>* this_handler)
 {
 #if defined(ASIO_NO_DEPRECATED)
  asio_handler_alloc_helpers::allocate(size, this_handler->handler_);
  return asio_handler_allocate_is_no_longer_used();
 #else // defined(ASIO_NO_DEPRECATED)
  return asio_handler_alloc_helpers::allocate(
      size, this_handler->handler_);
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1>
 inline asio_handler_deallocate_is_deprecated
 asio_handler_deallocate(void* pointer, std::size_t size,
    move_binder1<Handler, Arg1>* this_handler)
 {
  asio_handler_alloc_helpers::deallocate(
      pointer, size, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_deallocate_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1>
 inline bool asio_handler_is_continuation(
    move_binder1<Handler, Arg1>* this_handler)
 {
  return asio_handler_cont_helpers::is_continuation(
      this_handler->handler_);
 }
 template <typename Function, typename Handler, typename Arg1>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(ASIO_MOVE_ARG(Function) function,
    move_binder1<Handler, Arg1>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      ASIO_MOVE_CAST(Function)(function), this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2>
 class move_binder2
 {
 public:
  move_binder2(int, ASIO_MOVE_ARG(Handler) handler,
      const Arg1& arg1, ASIO_MOVE_ARG(Arg2) arg2)
    : handler_(ASIO_MOVE_CAST(Handler)(handler)),
      arg1_(arg1),
      arg2_(ASIO_MOVE_CAST(Arg2)(arg2))
  {
  }
  move_binder2(move_binder2&& other)
    : handler_(ASIO_MOVE_CAST(Handler)(other.handler_)),
      arg1_(ASIO_MOVE_CAST(Arg1)(other.arg1_)),
      arg2_(ASIO_MOVE_CAST(Arg2)(other.arg2_))
  {
  }
  void operator()()
  {
    handler_(static_cast<const Arg1&>(arg1_),
        ASIO_MOVE_CAST(Arg2)(arg2_));
  }
 //private:
  Handler handler_;
  Arg1 arg1_;
  Arg2 arg2_;
 };
 template <typename Handler, typename Arg1, typename Arg2>
 inline asio_handler_allocate_is_deprecated
 asio_handler_allocate(std::size_t size,
    move_binder2<Handler, Arg1, Arg2>* this_handler)
 {
 #if defined(ASIO_NO_DEPRECATED)
  asio_handler_alloc_helpers::allocate(size, this_handler->handler_);
  return asio_handler_allocate_is_no_longer_used();
 #else // defined(ASIO_NO_DEPRECATED)
  return asio_handler_alloc_helpers::allocate(
      size, this_handler->handler_);
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2>
 inline asio_handler_deallocate_is_deprecated
 asio_handler_deallocate(void* pointer, std::size_t size,
    move_binder2<Handler, Arg1, Arg2>* this_handler)
 {
  asio_handler_alloc_helpers::deallocate(
      pointer, size, this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_deallocate_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 template <typename Handler, typename Arg1, typename Arg2>
 inline bool asio_handler_is_continuation(
    move_binder2<Handler, Arg1, Arg2>* this_handler)
 {
  return asio_handler_cont_helpers::is_continuation(
      this_handler->handler_);
 }
 template <typename Function, typename Handler, typename Arg1, typename Arg2>
 inline asio_handler_invoke_is_deprecated
 asio_handler_invoke(ASIO_MOVE_ARG(Function) function,
    move_binder2<Handler, Arg1, Arg2>* this_handler)
 {
  asio_handler_invoke_helpers::invoke(
      ASIO_MOVE_CAST(Function)(function), this_handler->handler_);
 #if defined(ASIO_NO_DEPRECATED)
  return asio_handler_invoke_is_no_longer_used();
 #endif // defined(ASIO_NO_DEPRECATED)
 }
 #endif // defined(ASIO_HAS_MOVE)
 } // namespace detail
 template <typename Handler, typename Arg1, typename Allocator>
 struct associated_allocator<detail::binder1<Handler, Arg1>, Allocator>
 {
  typedef typename associated_allocator<Handler, Allocator>::type type;
  static type get(const detail::binder1<Handler, Arg1>& h,
      const Allocator& a = Allocator()) ASIO_NOEXCEPT
  {
    return associated_allocator<Handler, Allocator>::get(h.handler_, a);
  }
 };
 template <typename Handler, typename Arg1, typename Arg2, typename Allocator>
 struct associated_allocator<detail::binder2<Handler, Arg1, Arg2>, Allocator>
 {
  typedef typename associated_allocator<Handler, Allocator>::type type;
  static type get(const detail::binder2<Handler, Arg1, Arg2>& h,
      const Allocator& a = Allocator()) ASIO_NOEXCEPT
  {
    return associated_allocator<Handler, Allocator>::get(h.handler_, a);
  }
 };
 template <typename Handler, typename Arg1, typename Executor>
 struct associated_executor<detail::binder1<Handler, Arg1>, Executor>
  : detail::associated_executor_forwarding_base<Handler, Executor>
 {
  typedef typename associated_executor<Handler, Executor>::type type;
  static type get(const detail::binder1<Handler, Arg1>& h,
      const Executor& ex = Executor()) ASIO_NOEXCEPT
  {
    return associated_executor<Handler, Executor>::get(h.handler_, ex);
  }
 };
 template <typename Handler, typename Arg1, typename Arg2, typename Executor>
 struct associated_executor<detail::binder2<Handler, Arg1, Arg2>, Executor>
  : detail::associated_executor_forwarding_base<Handler, Executor>
 {
  typedef typename associated_executor<Handler, Executor>::type type;
  static type get(const detail::binder2<Handler, Arg1, Arg2>& h,
      const Executor& ex = Executor()) ASIO_NOEXCEPT
  {
    return associated_executor<Handler, Executor>::get(h.handler_, ex);
  }
 };
 #if defined(ASIO_HAS_MOVE)
 template <typename Handler, typename Arg1, typename Allocator>
 struct associated_allocator<detail::move_binder1<Handler, Arg1>, Allocator>
 {
  typedef typename associated_allocator<Handler, Allocator>::type type;
  static type get(const detail::move_binder1<Handler, Arg1>& h,
      const Allocator& a = Allocator()) ASIO_NOEXCEPT
  {
    return associated_allocator<Handler, Allocator>::get(h.handler_, a);
  }
 };
 template <typename Handler, typename Arg1, typename Arg2, typename Allocator>
 struct associated_allocator<
    detail::move_binder2<Handler, Arg1, Arg2>, Allocator>
 {
  typedef typename associated_allocator<Handler, Allocator>::type type;
  static type get(const detail::move_binder2<Handler, Arg1, Arg2>& h,
      const Allocator& a = Allocator()) ASIO_NOEXCEPT
  {
    return associated_allocator<Handler, Allocator>::get(h.handler_, a);
  }
 };
 template <typename Handler, typename Arg1, typename Executor>
 struct associated_executor<detail::move_binder1<Handler, Arg1>, Executor>
  : detail::associated_executor_forwarding_base<Handler, Executor>
 {
  typedef typename associated_executor<Handler, Executor>::type type;
  static type get(const detail::move_binder1<Handler, Arg1>& h,
      const Executor& ex = Executor()) ASIO_NOEXCEPT
  {
    return associated_executor<Handler, Executor>::get(h.handler_, ex);
  }
 };
 template <typename Handler, typename Arg1, typename Arg2, typename Executor>
 struct associated_executor<detail::move_binder2<Handler, Arg1, Arg2>, Executor>
  : detail::associated_executor_forwarding_base<Handler, Executor>
 {
  typedef typename associated_executor<Handler, Executor>::type type;
  static type get(const detail::move_binder2<Handler, Arg1, Arg2>& h,
      const Executor& ex = Executor()) ASIO_NOEXCEPT
  {
    return associated_executor<Handler, Executor>::get(h.handler_, ex);
  }
 };
 #endif // defined(ASIO_HAS_MOVE)
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_DETAIL_BIND_HANDLER_HPP
--- a/module/Vendor/ASIO/include/asio/detail/blocking_executor_op.hpp
+++ b/module/Vendor/ASIO/include/asio/detail/blocking_executor_op.hpp
@ -0,0 +1,107 @@
 //
 // detail/blocking_executor_op.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETAIL_BLOCKING_EXECUTOR_OP_HPP
 #define ASIO_DETAIL_BLOCKING_EXECUTOR_OP_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/detail/event.hpp"
 #include "asio/detail/fenced_block.hpp"
 #include "asio/detail/handler_invoke_helpers.hpp"
 #include "asio/detail/mutex.hpp"
 #include "asio/detail/scheduler_operation.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 template <typename Operation = scheduler_operation>
 class blocking_executor_op_base : public Operation
 {
 public:
  blocking_executor_op_base(typename Operation::func_type complete_func)
    : Operation(complete_func),
      is_complete_(false)
  {
  }
  void wait()
  {
    asio::detail::mutex::scoped_lock lock(mutex_);
    while (!is_complete_)
      event_.wait(lock);
  }
 protected:
  struct do_complete_cleanup
  {
    ~do_complete_cleanup()
    {
      asio::detail::mutex::scoped_lock lock(op_->mutex_);
      op_->is_complete_ = true;
      op_->event_.unlock_and_signal_one_for_destruction(lock);
    }
    blocking_executor_op_base* op_;
  };
 private:
  asio::detail::mutex mutex_;
  asio::detail::event event_;
  bool is_complete_;
 };
 template <typename Handler, typename Operation = scheduler_operation>
 class blocking_executor_op : public blocking_executor_op_base<Operation>
 {
 public:
  blocking_executor_op(Handler& h)
    : blocking_executor_op_base<Operation>(&blocking_executor_op::do_complete),
      handler_(h)
  {
  }
  static void do_complete(void* owner, Operation* base,
      const asio::error_code& /*ec*/,
      std::size_t /*bytes_transferred*/)
  {
    blocking_executor_op* o(static_cast<blocking_executor_op*>(base));
    typename blocking_executor_op_base<Operation>::do_complete_cleanup
      on_exit = { o };
    (void)on_exit;
    ASIO_HANDLER_COMPLETION((*o));
    // Make the upcall if required.
    if (owner)
    {
      fenced_block b(fenced_block::half);
      ASIO_HANDLER_INVOCATION_BEGIN(());
      asio_handler_invoke_helpers::invoke(o->handler_, o->handler_);
      ASIO_HANDLER_INVOCATION_END;
    }
  }
 private:
  Handler& handler_;
 };
 } // namespace detail
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_DETAIL_BLOCKING_EXECUTOR_OP_HPP
--- a/module/Vendor/ASIO/include/asio/detail/buffer_resize_guard.hpp
+++ b/module/Vendor/ASIO/include/asio/detail/buffer_resize_guard.hpp
@ -0,0 +1,66 @@
 //
 // detail/buffer_resize_guard.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETAIL_BUFFER_RESIZE_GUARD_HPP
 #define ASIO_DETAIL_BUFFER_RESIZE_GUARD_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/detail/limits.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 // Helper class to manage buffer resizing in an exception safe way.
 template <typename Buffer>
 class buffer_resize_guard
 {
 public:
  // Constructor.
  buffer_resize_guard(Buffer& buffer)
    : buffer_(buffer),
      old_size_(buffer.size())
  {
  }
  // Destructor rolls back the buffer resize unless commit was called.
  ~buffer_resize_guard()
  {
    if (old_size_ != (std::numeric_limits<size_t>::max)())
    {
      buffer_.resize(old_size_);
    }
  }
  // Commit the resize transaction.
  void commit()
  {
    old_size_ = (std::numeric_limits<size_t>::max)();
  }
 private:
  // The buffer being managed.
  Buffer& buffer_;
  // The size of the buffer at the time the guard was constructed.
  size_t old_size_;
 };
 } // namespace detail
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #endif // ASIO_DETAIL_BUFFER_RESIZE_GUARD_HPP
--- a/module/Vendor/ASIO/include/asio/detail/buffer_sequence_adapter.hpp
+++ b/module/Vendor/ASIO/include/asio/detail/buffer_sequence_adapter.hpp
@ -0,0 +1,650 @@
 //
 // detail/buffer_sequence_adapter.hpp
 // ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 //
 // Copyright (c) 2003-2021 Christopher M. Kohlhoff (chris at kohlhoff dot com)
 //
 // Distributed under the Boost Software License, Version 1.0. (See accompanying
 // file LICENSE_1_0.txt or copy at http://www.boost.org/LICENSE_1_0.txt)
 //
 #ifndef ASIO_DETAIL_BUFFER_SEQUENCE_ADAPTER_HPP
 #define ASIO_DETAIL_BUFFER_SEQUENCE_ADAPTER_HPP
 #if defined(_MSC_VER) && (_MSC_VER >= 1200)
 # pragma once
 #endif // defined(_MSC_VER) && (_MSC_VER >= 1200)
 #include "asio/detail/config.hpp"
 #include "asio/buffer.hpp"
 #include "asio/detail/array_fwd.hpp"
 #include "asio/detail/socket_types.hpp"
 #include "asio/detail/push_options.hpp"
 namespace asio {
 namespace detail {
 class buffer_sequence_adapter_base
 {
 #if defined(ASIO_WINDOWS_RUNTIME)
 public:
  // The maximum number of buffers to support in a single operation.
  enum { max_buffers = 1 };
 protected:
  typedef Windows::Storage::Streams::IBuffer^ native_buffer_type;
  ASIO_DECL static void init_native_buffer(
      native_buffer_type& buf,
      const asio::mutable_buffer& buffer);
  ASIO_DECL static void init_native_buffer(
      native_buffer_type& buf,
      const asio::const_buffer& buffer);
 #elif defined(ASIO_WINDOWS) || defined(__CYGWIN__)
 public:
  // The maximum number of buffers to support in a single operation.
  enum { max_buffers = 64 < max_iov_len ? 64 : max_iov_len };
 protected:
  typedef WSABUF native_buffer_type;
  static void init_native_buffer(WSABUF& buf,
      const asio::mutable_buffer& buffer)
  {
    buf.buf = static_cast<char*>(buffer.data());
    buf.len = static_cast<ULONG>(buffer.size());
  }
  static void init_native_buffer(WSABUF& buf,
      const asio::const_buffer& buffer)
  {
    buf.buf = const_cast<char*>(static_cast<const char*>(buffer.data()));
    buf.len = static_cast<ULONG>(buffer.size());
  }
 #else // defined(ASIO_WINDOWS) || defined(__CYGWIN__)
 public:
  // The maximum number of buffers to support in a single operation.
  enum { max_buffers = 64 < max_iov_len ? 64 : max_iov_len };
 protected:
  typedef iovec native_buffer_type;
  static void init_iov_base(void*& base, void* addr)
  {
    base = addr;
  }
  template <typename T>
  static void init_iov_base(T& base, void* addr)
  {
    base = static_cast<T>(addr);
  }
  static void init_native_buffer(iovec& iov,
      const asio::mutable_buffer& buffer)
  {
    init_iov_base(iov.iov_base, buffer.data());
    iov.iov_len = buffer.size();
  }
  static void init_native_buffer(iovec& iov,
      const asio::const_buffer& buffer)
  {
    init_iov_base(iov.iov_base, const_cast<void*>(buffer.data()));
    iov.iov_len = buffer.size();
  }
 #endif // defined(ASIO_WINDOWS) || defined(__CYGWIN__)
 };
 // Helper class to translate buffers into the native buffer representation.
 template <typename Buffer, typename Buffers>
 class buffer_sequence_adapter
  : buffer_sequence_adapter_base
 {
 public:
  enum { is_single_buffer = false };
  explicit buffer_sequence_adapter(const Buffers& buffer_sequence)
    : count_(0), total_buffer_size_(0)
  {
    buffer_sequence_adapter::init(
        asio::buffer_sequence_begin(buffer_sequence),
        asio::buffer_sequence_end(buffer_sequence));
  }
  native_buffer_type* buffers()
  {
    return buffers_;
  }
  std::size_t count() const
  {
    return count_;
  }
  std::size_t total_size() const
  {
    return total_buffer_size_;
  }
  bool all_empty() const
  {
    return total_buffer_size_ == 0;
  }
  static bool all_empty(const Buffers& buffer_sequence)
  {
    return buffer_sequence_adapter::all_empty(
        asio::buffer_sequence_begin(buffer_sequence),
        asio::buffer_sequence_end(buffer_sequence));
  }
  static void validate(const Buffers& buffer_sequence)
  {
    buffer_sequence_adapter::validate(
        asio::buffer_sequence_begin(buffer_sequence),
        asio::buffer_sequence_end(buffer_sequence));
  }
  static Buffer first(const Buffers& buffer_sequence)
  {
    return buffer_sequence_adapter::first(
        asio::buffer_sequence_begin(buffer_sequence),
        asio::buffer_sequence_end(buffer_sequence));
  }
  enum { linearisation_storage_size = 8192 };
  static Buffer linearise(const Buffers& buffer_sequence,
      const asio::mutable_buffer& storage)
  {
    return buffer_sequence_adapter::linearise(
        asio::buffer_sequence_begin(buffer_sequence),
        asio::buffer_sequence_end(buffer_sequence), storage);
  }
 private:
  template <typename Iterator>
  void init(Iterator begin, Iterator end)
  {
    Iterator iter = begin;
    for (; iter != end && count_ < max_buffers; ++iter, ++count_)
    {
      Buffer buffer(*iter);
      init_native_buffer(buffers_[count_], buffer);
      total_buffer_size_ += buffer.size();
    }
  }
  template <typename Iterator>
  static bool all_empty(Iterator begin, Iterator end)
  {
    Iterator iter = begin;
    std::size_t i = 0;
    for (; iter != end && i < max_buffers; ++iter, ++i)
      if (Buffer(*iter).size() > 0)
        return false;
    return true;
  }
  template <typename Iterator>
  static void validate(Iterator begin, Iterator end)
  {
    Iterator iter = begin;
    for (; iter != end; ++iter)
    {
      Buffer buffer(*iter);
      buffer.data();
    }
  }
  template <typename Iterator>
  static Buffer first(Iterator begin, Iterator end)
  {
    Iterator iter = begin;
    for (; iter != end; ++iter)
    {
      Buffer buffer(*iter);
      if (buffer.size() != 0)
        return buffer;
    }
    return Buffer();
  }
  template <typename Iterator>
  static Buffer linearise(Iterator begin, Iterator end,
      const asio::mutable_buffer& storage)
  {
    asio::mutable_buffer unused_storage = storage;
    Iterator iter = begin;
    while (iter != end && unused_storage.size() != 0)
    {
      Buffer buffer(*iter);
      ++iter;
      if (buffer.size() == 0)
        continue;
      if (unused_storage.size() == storage.size())
      {
        if (iter == end)
          return buffer;
        if (buffer.size() >= unused_storage.size())
          return buffer;
      }
      unused_storage += asio::buffer_copy(unused_storage, buffer);
    }
    return Buffer(storage.data(), storage.size() - unused_storage.size());
  }
  native_buffer_type buffers_[max_buffers];
  std::size_t count_;
  std::size_t total_buffer_size_;
 };
 template <typename Buffer>
 class buffer_sequence_adapter<Buffer, asio::mutable_buffer>
  : buffer_sequence_adapter_base
 {
 public:
  enum { is_single_buffer = true };
  explicit buffer_sequence_adapter(
      const asio::mutable_buffer& buffer_sequence)
  {
    init_native_buffer(buffer_, Buffer(buffer_sequence));
    total_buffer_size_ = buffer_sequence.size();
  }
  native_buffer_type* buffers()
  {
    return &buffer_;
  }
  std::size_t count() const
  {
    return 1;
  }
  std::size_t total_size() const
  {
    return total_buffer_size_;
  }
  bool all_empty() const
  {
    return total_buffer_size_ == 0;
  }
  static bool all_empty(const asio::mutable_buffer& buffer_sequence)
  {
    return buffer_sequence.size() == 0;
  }
  static void validate(const asio::mutable_buffer& buffer_sequence)
  {
    buffer_sequence.data();
  }
  static Buffer first(const asio::mutable_buffer& buffer_sequence)
  {
    return Buffer(buffer_sequence);
  }
  enum { linearisation_storage_size = 1 };
  static Buffer linearise(const asio::mutable_buffer& buffer_sequence,
      const Buffer&)
  {
    return Buffer(buffer_sequence);
  }
 private:
  native_buffer_type buffer_;
  std::size_t total_buffer_size_;
 };
 template <typename Buffer>
 class buffer_sequence_adapter<Buffer, asio::const_buffer>
  : buffer_sequence_adapter_base
 {
 public:
  enum { is_single_buffer = true };
  explicit buffer_sequence_adapter(
      const asio::const_buffer& buffer_sequence)
  {
    init_native_buffer(buffer_, Buffer(buffer_sequence));
    total_buffer_size_ = buffer_sequence.size();
  }
  native_buffer_type* buffers()
  {
    return &buffer_;
  }
  std::size_t count() const
  {
    return 1;
  }
  std::size_t total_size() const
  {
    return total_buffer_size_;
  }
  bool all_empty() const
  {
    return total_buffer_size_ == 0;
  }
  static bool all_empty(const asio::const_buffer& buffer_sequence)
  {
    return buffer_sequence.size() == 0;
  }
  static void validate(const asio::const_buffer& buffer_sequence)
  {
    buffer_sequence.data();
  }
  static Buffer first(const asio::const_buffer& buffer_sequence)
  {
    return Buffer(buffer_sequence);
  }
  enum { linearisation_storage_size = 1 };
  static Buffer linearise(const asio::const_buffer& buffer_sequence,
      const Buffer&)
  {
    return Buffer(buffer_sequence);
  }
 private:
  native_buffer_type buffer_;
  std::size_t total_buffer_size_;
 };
 #if !defined(ASIO_NO_DEPRECATED)
 template <typename Buffer>
 class buffer_sequence_adapter<Buffer, asio::mutable_buffers_1>
  : buffer_sequence_adapter_base
 {
 public:
  enum { is_single_buffer = true };
  explicit buffer_sequence_adapter(
      const asio::mutable_buffers_1& buffer_sequence)
  {
    init_native_buffer(buffer_, Buffer(buffer_sequence));
    total_buffer_size_ = buffer_sequence.size();
  }
  native_buffer_type* buffers()
  {
    return &buffer_;
  }
  std::size_t count() const
  {
    return 1;
  }
  std::size_t total_size() const
  {
    return total_buffer_size_;
  }
  bool all_empty() const
  {
    return total_buffer_size_ == 0;
  }
  static bool all_empty(const asio::mutable_buffers_1& buffer_sequence)
  {
    return buffer_sequence.size() == 0;
  }
  static void validate(const asio::mutable_buffers_1& buffer_sequence)
  {
    buffer_sequence.data();
  }
  static Buffer first(const asio::mutable_buffers_1& buffer_sequence)
  {
    return Buffer(buffer_sequence);
  }
  enum { linearisation_storage_size = 1 };
  static Buffer linearise(const asio::mutable_buffers_1& buffer_sequence,
      const Buffer&)
  {
    return Buffer(buffer_sequence);
  }
 private:
  native_buffer_type buffer_;
  std::size_t total_buffer_size_;
 };
 template <typename Buffer>
 class buffer_sequence_adapter<Buffer, asio::const_buffers_1>
  : buffer_sequence_adapter_base
 {
 public:
  enum { is_single_buffer = true };
  explicit buffer_sequence_adapter(
      const asio::const_buffers_1& buffer_sequence)
  {
    init_native_buffer(buffer_, Buffer(buffer_sequence));
    total_buffer_size_ = buffer_sequence.size();
  }
  native_buffer_type* buffers()
  {
    return &buffer_;
  }
  std::size_t count() const
  {
    return 1;
  }
  std::size_t total_size() const
  {
    return total_buffer_size_;
  }
  bool all_empty() const
  {
    return total_buffer_size_ == 0;
  }
  static bool all_empty(const asio::const_buffers_1& buffer_sequence)
  {
    return buffer_sequence.size() == 0;
  }
  static void validate(const asio::const_buffers_1& buffer_sequence)
  {
    buffer_sequence.data();
  }
  static Buffer first(const asio::const_buffers_1& buffer_sequence)
  {
    return Buffer(buffer_sequence);
  }
  enum { linearisation_storage_size = 1 };
  static Buffer linearise(const asio::const_buffers_1& buffer_sequence,
      const Buffer&)
  {
    return Buffer(buffer_sequence);
  }
 private:
  native_buffer_type buffer_;
  std::size_t total_buffer_size_;
 };
 #endif // !defined(ASIO_NO_DEPRECATED)
 template <typename Buffer, typename Elem>
 class buffer_sequence_adapter<Buffer, boost::array<Elem, 2> >
  : buffer_sequence_adapter_base
 {
 public:
  enum { is_single_buffer = false };
  explicit buffer_sequence_adapter(
      const boost::array<Elem, 2>& buffer_sequence)
  {
    init_native_buffer(buffers_[0], Buffer(buffer_sequence[0]));
    init_native_buffer(buffers_[1], Buffer(buffer_sequence[1]));
    total_buffer_size_ = buffer_sequence[0].size() + buffer_sequence[1].size();
  }
  native_buffer_type* buffers()
  {
    return buffers_;
  }
  std::size_t count() const
  {
    return 2;
  }
  std::size_t total_size() const
  {
    return total_buffer_size_;
  }
  bool all_empty() const
  {
    return total_buffer_size_ == 0;
  }
  static bool all_empty(const boost::array<Elem, 2>& buffer_sequence)
  {
    return buffer_sequence[0].size() == 0 && buffer_sequence[1].size() == 0;
  }
  static void validate(const boost::array<Elem, 2>& buffer_sequence)
  {
    buffer_sequence[0].data();
    buffer_sequence[1].data();
  }
  static Buffer first(const boost::array<Elem, 2>& buffer_sequence)
  {
    return Buffer(buffer_sequence[0].size() != 0
        ? buffer_sequence[0] : buffer_sequence[1]);
  }
  enum { linearisation_storage_size = 8192 };
  static Buffer linearise(const boost::array<Elem, 2>& buffer_sequence,
      const asio::mutable_buffer& storage)
  {
    if (buffer_sequence[0].size() == 0)
      return Buffer(buffer_sequence[1]);
    if (buffer_sequence[1].size() == 0)
      return Buffer(buffer_sequence[0]);
    return Buffer(storage.data(),
        asio::buffer_copy(storage, buffer_sequence));
  }
 private:
  native_buffer_type buffers_[2];
  std::size_t total_buffer_size_;
 };
 #if defined(ASIO_HAS_STD_ARRAY)
 template <typename Buffer, typename Elem>
 class buffer_sequence_adapter<Buffer, std::array<Elem, 2> >
  : buffer_sequence_adapter_base
 {
 public:
  enum { is_single_buffer = false };
  explicit buffer_sequence_adapter(
      const std::array<Elem, 2>& buffer_sequence)
  {
    init_native_buffer(buffers_[0], Buffer(buffer_sequence[0]));
    init_native_buffer(buffers_[1], Buffer(buffer_sequence[1]));
    total_buffer_size_ = buffer_sequence[0].size() + buffer_sequence[1].size();
  }
  native_buffer_type* buffers()
  {
    return buffers_;
  }
  std::size_t count() const
  {
    return 2;
  }
  std::size_t total_size() const
  {
    return total_buffer_size_;
  }
  bool all_empty() const
  {
    return total_buffer_size_ == 0;
  }
  static bool all_empty(const std::array<Elem, 2>& buffer_sequence)
  {
    return buffer_sequence[0].size() == 0 && buffer_sequence[1].size() == 0;
  }
  static void validate(const std::array<Elem, 2>& buffer_sequence)
  {
    buffer_sequence[0].data();
    buffer_sequence[1].data();
  }
  static Buffer first(const std::array<Elem, 2>& buffer_sequence)
  {
    return Buffer(buffer_sequence[0].size() != 0
        ? buffer_sequence[0] : buffer_sequence[1]);
  }
  enum { linearisation_storage_size = 8192 };
  static Buffer linearise(const std::array<Elem, 2>& buffer_sequence,
      const asio::mutable_buffer& storage)
  {
    if (buffer_sequence[0].size() == 0)
      return Buffer(buffer_sequence[1]);
    if (buffer_sequence[1].size() == 0)
      return Buffer(buffer_sequence[0]);
    return Buffer(storage.data(),
        asio::buffer_copy(storage, buffer_sequence));
  }
 private:
  native_buffer_type buffers_[2];
  std::size_t total_buffer_size_;
 };
 #endif // defined(ASIO_HAS_STD_ARRAY)
 } // namespace detail
 } // namespace asio
 #include "asio/detail/pop_options.hpp"
 #if defined(ASIO_HEADER_ONLY)
 # include "asio/detail/impl/buffer_sequence_adapter.ipp"
 #endif // defined(ASIO_HEADER_ONLY)
 #endif // ASIO_DETAIL_BUFFER_SEQUENCE_ADAPTER_HPP
--- a/Show More
+++ b/Show More