docs/intro.dox - third_party/glfw - Git at Google

 /*!

 @page intro_guide Introduction to the API

 @tableofcontents

 This guide introduces the basic concepts of GLFW and describes initialization,
 error handling and API guarantees and limitations.  For a broad but shallow
 tutorial, see @ref quick_guide instead.  For details on a specific function in
 this category, see the @ref init.

 There are also guides for the other areas of GLFW.

  - @ref window_guide
  - @ref context_guide
  - @ref vulkan_guide
  - @ref monitor_guide
  - @ref input_guide


 @section intro_init Initialization and termination

 Before most GLFW functions may be called, the library must be initialized.
 This initialization checks what features are available on the machine,
 enumerates monitors and joysticks, initializes the timer and performs any
 required platform-specific initialization.

 Only the following functions may be called before the library has been
 successfully initialized, and only from the main thread.

  - @ref glfwGetVersion
  - @ref glfwGetVersionString
  - @ref glfwGetError
  - @ref glfwSetErrorCallback
  - @ref glfwInitHint
  - @ref glfwInit
  - @ref glfwTerminate

 Calling any other function before successful initialization will cause a @ref
 GLFW_NOT_INITIALIZED error.


 @subsection intro_init_init Initializing GLFW

 The library is initialized with @ref glfwInit, which returns `GLFW_FALSE` if an
 error occurred.

 @code
 if (!glfwInit())
 {
     // Handle initialization failure
 }
 @endcode

 If any part of initialization fails, any parts that succeeded are terminated as
 if @ref glfwTerminate had been called.  The library only needs to be initialized
 once and additional calls to an already initialized library will return
 `GLFW_TRUE` immediately.

 Once the library has been successfully initialized, it should be terminated
 before the application exits.  Modern systems are very good at freeing resources
 allocated by programs that exit, but GLFW sometimes has to change global system
 settings and these might not be restored without termination.


 @subsection init_hints Initialization hints

 Initialization hints are set before @ref glfwInit and affect how the library
 behaves until termination.  Hints are set with @ref glfwInitHint.

 @code
 glfwInitHint(GLFW_JOYSTICK_HAT_BUTTONS, GLFW_FALSE);
 @endcode

 The values you set hints to are never reset by GLFW, but they only take effect
 during initialization.  Once GLFW has been initialized, any values you set will
 be ignored until the library is terminated and initialized again.

 Some hints are platform specific.  These may be set on any platform but they
 will only affect their specific platform.  Other platforms will ignore them.
 Setting these hints requires no platform specific headers or functions.


 @subsubsection init_hints_shared Shared init hints

 @anchor GLFW_JOYSTICK_HAT_BUTTONS
 __GLFW_JOYSTICK_HAT_BUTTONS__ specifies whether to also expose joystick hats as
 buttons, for compatibility with earlier versions of GLFW that did not have @ref
 glfwGetJoystickHats.  Set this with @ref glfwInitHint.


 @subsubsection init_hints_osx macOS specific init hints

 @anchor GLFW_COCOA_CHDIR_RESOURCES_hint
 __GLFW_COCOA_CHDIR_RESOURCES__ specifies whether to set the current directory to
 the application to the `Contents/Resources` subdirectory of the application's
 bundle, if present.  Set this with @ref glfwInitHint.

 @anchor GLFW_COCOA_MENUBAR_hint
 __GLFW_COCOA_MENUBAR__ specifies whether to create a basic menu bar, either from
 a nib or manually, when the first window is created, which is when AppKit is
 initialized.  Set this with @ref glfwInitHint.


 @subsubsection init_hints_values Supported and default values

 Initialization hint             | Default value | Supported values
 ------------------------------- | ------------- | ----------------
 @ref GLFW_JOYSTICK_HAT_BUTTONS  | `GLFW_TRUE`   | `GLFW_TRUE` or `GLFW_FALSE`
 @ref GLFW_COCOA_CHDIR_RESOURCES | `GLFW_TRUE`   | `GLFW_TRUE` or `GLFW_FALSE`
 @ref GLFW_COCOA_MENUBAR         | `GLFW_TRUE`   | `GLFW_TRUE` or `GLFW_FALSE`


 @subsection intro_init_terminate Terminating GLFW

 Before your application exits, you should terminate the GLFW library if it has
 been initialized.  This is done with @ref glfwTerminate.

 @code
 glfwTerminate();
 @endcode

 This will destroy any remaining window, monitor and cursor objects, restore any
 modified gamma ramps, re-enable the screensaver if it had been disabled and free
 any other resources allocated by GLFW.

 Once the library is terminated, it is as if it had never been initialized and
 you will need to initialize it again before being able to use GLFW.  If the
 library was not initialized or had already been terminated, it return
 immediately.


 @section error_handling Error handling

 Some GLFW functions have return values that indicate an error, but this is often
 not very helpful when trying to figure out what happened or why it occurred.
 Other functions have no return value reserved for errors, so error notification
 needs a separate channel.  Finally, far from all GLFW functions have return
 values.

 The last [error code](@ref errors) for the calling thread can be queried at any
 time with @ref glfwGetError.

 @code
 int code = glfwGetError(NULL);

 if (code != GLFW_NO_ERROR)
     handle_error(code);
 @endcode

 If no error has occurred since the last call, @ref GLFW_NO_ERROR (zero) is
 returned.  The error is cleared before the function returns.

 The error code indicates the general category of the error.  Some error codes,
 such as @ref GLFW_NOT_INITIALIZED has only a single meaning, whereas others like
 @ref GLFW_PLATFORM_ERROR are used for many different errors.

 GLFW often has more information about an error than its general category.  You
 can retrieve a UTF-8 encoded human-readable description along with the error
 code.  If no error has occurred since the last call, the description is set to
 `NULL`.

 @code
 const char* description;
 int code = glfwGetError(&description);

 if (description)
     display_error_message(code, description);
 @endcode

 The retrieved description string is only valid until the next error occurs.
 This means you must make a copy of it if you want to keep it.

 You can also set an error callback, which will be called each time an error
 occurs.  It is set with @ref glfwSetErrorCallback.

 @code
 glfwSetErrorCallback(error_callback);
 @endcode

 The error callback receives the same error code and human-readable description
 returned by @ref glfwGetError.

 @code
 void error_callback(int code, const char* description)
 {
     display_error_message(code, description);
 }
 @endcode

 The error callback is called after the error is stored, so calling @ref
 glfwGetError from within the error callback returns the same values as the
 callback argument.

 The description string passed to the callback is only valid until the error
 callback returns.  This means you must make a copy of it if you want to keep it.

 __Reported errors are never fatal.__  As long as GLFW was successfully
 initialized, it will remain initialized and in a safe state until terminated
 regardless of how many errors occur.  If an error occurs during initialization
 that causes @ref glfwInit to fail, any part of the library that was initialized
 will be safely terminated.

 Do not rely on a currently invalid call to generate a specific error, as in the
 future that same call may generate a different error or become valid.


 @section coordinate_systems Coordinate systems

 GLFW has two primary coordinate systems: the _virtual screen_ and the window
 _content area_ or _content area_.  Both use the same unit: _virtual screen
 coordinates_, or just _screen coordinates_, which don't necessarily correspond
 to pixels.

 <img src="spaces.svg" width="90%" />

 Both the virtual screen and the content area coordinate systems have the X-axis
 pointing to the right and the Y-axis pointing down.

 Window and monitor positions are specified as the position of the upper-left
 corners of their content areas relative to the virtual screen, while cursor
 positions are specified relative to a window's content area.

 Because the origin of the window's content area coordinate system is also the
 point from which the window position is specified, you can translate content
 area coordinates to the virtual screen by adding the window position.  The
 window frame, when present, extends out from the content area but does not
 affect the window position.

 Almost all positions and sizes in GLFW are measured in screen coordinates
 relative to one of the two origins above.  This includes cursor positions,
 window positions and sizes, window frame sizes, monitor positions and video mode
 resolutions.

 Two exceptions are the [monitor physical size](@ref monitor_size), which is
 measured in millimetres, and [framebuffer size](@ref window_fbsize), which is
 measured in pixels.

 Pixels and screen coordinates may map 1:1 on your machine, but they won't on
 every other machine, for example on a Mac with a Retina display.  The ratio
 between screen coordinates and pixels may also change at run-time depending on
 which monitor the window is currently considered to be on.


 @section guarantees_limitations Guarantees and limitations

 This section describes the conditions under which GLFW can be expected to
 function, barring bugs in the operating system or drivers.  Use of GLFW outside
 of these limits may work on some platforms, or on some machines, or some of the
 time, or on some versions of GLFW, but it may break at any time and this will
 not be considered a bug.


 @subsection lifetime Pointer lifetimes

 GLFW will never free any pointer you provide to it and you must never free any
 pointer it provides to you.

 Many GLFW functions return pointers to dynamically allocated structures, strings
 or arrays, and some callbacks are provided with strings or arrays.  These are
 always managed by GLFW and should never be freed by the application.  The
 lifetime of these pointers is documented for each GLFW function and callback.
 If you need to keep this data, you must copy it before its lifetime expires.

 Many GLFW functions accept pointers to structures or strings allocated by the
 application.  These are never freed by GLFW and are always the responsibility of
 the application.  If GLFW needs to keep the data in these structures or strings,
 it is copied before the function returns.

 Pointer lifetimes are guaranteed not to be shortened in future minor or patch
 releases.


 @subsection reentrancy Reentrancy

 GLFW event processing and object destruction are not reentrant.  This means that
 the following functions must not be called from any callback function:

  - @ref glfwDestroyWindow
  - @ref glfwDestroyCursor
  - @ref glfwPollEvents
  - @ref glfwWaitEvents
  - @ref glfwWaitEventsTimeout
  - @ref glfwTerminate

 These functions may be made reentrant in future minor or patch releases, but
 functions not on this list will not be made non-reentrant.


 @subsection thread_safety Thread safety

 Most GLFW functions must only be called from the main thread (the thread that
 calls main), but some may be called from any thread once the library has been
 initialized.  Before initialization the whole library is thread-unsafe.

 The reference documentation for every GLFW function states whether it is limited
 to the main thread.

 Initialization, termination, event processing and the creation and
 destruction of windows, cursors and OpenGL and OpenGL ES contexts are all
 restricted to the main thread due to limitations of one or several platforms.

 Because event processing must be performed on the main thread, all callbacks
 except for the error callback will only be called on that thread.  The error
 callback may be called on any thread, as any GLFW function may generate errors.

 The error code and description may be queried from any thread.

  - @ref glfwGetError

 Empty events may be posted from any thread.

  - @ref glfwPostEmptyEvent

 The window user pointer and close flag may be read and written from any thread,
 but this is not synchronized by GLFW.

  - @ref glfwGetWindowUserPointer
  - @ref glfwSetWindowUserPointer
  - @ref glfwWindowShouldClose
  - @ref glfwSetWindowShouldClose

 These functions for working with OpenGL and OpenGL ES contexts may be called
 from any thread, but the window object is not synchronized by GLFW.

  - @ref glfwMakeContextCurrent
  - @ref glfwGetCurrentContext
  - @ref glfwSwapBuffers
  - @ref glfwSwapInterval
  - @ref glfwExtensionSupported
  - @ref glfwGetProcAddress

 The raw timer functions may be called from any thread.

  - @ref glfwGetTimerFrequency
  - @ref glfwGetTimerValue

 The regular timer may be used from any thread, but reading and writing the timer
 offset is not synchronized by GLFW.

  - @ref glfwGetTime
  - @ref glfwSetTime

 Library version information may be queried from any thread.

  - @ref glfwGetVersion
  - @ref glfwGetVersionString

 All Vulkan related functions may be called from any thread.

  - @ref glfwVulkanSupported
  - @ref glfwGetRequiredInstanceExtensions
  - @ref glfwGetInstanceProcAddress
  - @ref glfwGetPhysicalDevicePresentationSupport
  - @ref glfwCreateWindowSurface

 GLFW uses synchronization objects internally only to manage the per-thread
 context and error states.  Additional synchronization is left to the
 application.

 Functions that may currently be called from any thread will always remain so,
 but functions that are currently limited to the main thread may be updated to
 allow calls from any thread in future releases.


 @subsection compatibility Version compatibility

 GLFW uses [Semantic Versioning](https://semver.org/).  This guarantees source
 and binary backward compatibility with earlier minor versions of the API.  This
 means that you can drop in a newer version of the library and existing programs
 will continue to compile and existing binaries will continue to run.

 Once a function or constant has been added, the signature of that function or
 value of that constant will remain unchanged until the next major version of
 GLFW.  No compatibility of any kind is guaranteed between major versions.

 Undocumented behavior, i.e. behavior that is not described in the documentation,
 may change at any time until it is documented.

 If the reference documentation and the implementation differ, the reference
 documentation will almost always take precedence and the implementation will be
 fixed in the next release.  The reference documentation will also take
 precedence over anything stated in a guide.


 @subsection event_order Event order

 The order of arrival of related events is not guaranteed to be consistent
 across platforms.  The exception is synthetic key and mouse button release
 events, which are always delivered after the window defocus event.


 @section intro_version Version management

 GLFW provides mechanisms for identifying what version of GLFW your application
 was compiled against as well as what version it is currently running against.
 If you are loading GLFW dynamically (not just linking dynamically), you can use
 this to verify that the library binary is compatible with your application.


 @subsection intro_version_compile Compile-time version

 The compile-time version of GLFW is provided by the GLFW header with the
 `GLFW_VERSION_MAJOR`, `GLFW_VERSION_MINOR` and `GLFW_VERSION_REVISION` macros.

 @code
 printf("Compiled against GLFW %i.%i.%i\n",
        GLFW_VERSION_MAJOR,
        GLFW_VERSION_MINOR,
        GLFW_VERSION_REVISION);
 @endcode


 @subsection intro_version_runtime Run-time version

 The run-time version can be retrieved with @ref glfwGetVersion, a function that
 may be called regardless of whether GLFW is initialized.

 @code
 int major, minor, revision;
 glfwGetVersion(&major, &minor, &revision);

 printf("Running against GLFW %i.%i.%i\n", major, minor, revision);
 @endcode


 @subsection intro_version_string Version string

 GLFW 3 also provides a compile-time generated version string that describes the
 version, platform, compiler and any platform-specific compile-time options.
 This is primarily intended for submitting bug reports, to allow developers to
 see which code paths are enabled in a binary.

 The version string is returned by @ref glfwGetVersionString, a function that may
 be called regardless of whether GLFW is initialized.

 __Do not use the version string__ to parse the GLFW library version.  The @ref
 glfwGetVersion function already provides the version of the running library
 binary.

 The format of the string is as follows:
  - The version of GLFW
  - The name of the window system API
  - The name of the context creation API
  - Any additional options or APIs

 For example, when compiling GLFW 3.0 with MinGW using the Win32 and WGL
 back ends, the version string may look something like this:

 @code
 3.0.0 Win32 WGL MinGW
 @endcode

 */
	/*!

	@page intro_guide Introduction to the API

	@tableofcontents

	This guide introduces the basic concepts of GLFW and describes initialization,
	error handling and API guarantees and limitations. For a broad but shallow
	tutorial, see @ref quick_guide instead. For details on a specific function in
	this category, see the @ref init.

	There are also guides for the other areas of GLFW.

	- @ref window_guide
	- @ref context_guide
	- @ref vulkan_guide
	- @ref monitor_guide
	- @ref input_guide


	@section intro_init Initialization and termination

	Before most GLFW functions may be called, the library must be initialized.
	This initialization checks what features are available on the machine,
	enumerates monitors and joysticks, initializes the timer and performs any
	required platform-specific initialization.

	Only the following functions may be called before the library has been
	successfully initialized, and only from the main thread.

	- @ref glfwGetVersion
	- @ref glfwGetVersionString
	- @ref glfwGetError
	- @ref glfwSetErrorCallback
	- @ref glfwInitHint
	- @ref glfwInit
	- @ref glfwTerminate

	Calling any other function before successful initialization will cause a @ref
	GLFW_NOT_INITIALIZED error.


	@subsection intro_init_init Initializing GLFW

	The library is initialized with @ref glfwInit, which returns `GLFW_FALSE` if an
	error occurred.

	@code
	if (!glfwInit())
	{
	// Handle initialization failure
	}
	@endcode

	If any part of initialization fails, any parts that succeeded are terminated as
	if @ref glfwTerminate had been called. The library only needs to be initialized
	once and additional calls to an already initialized library will return
	`GLFW_TRUE` immediately.

	Once the library has been successfully initialized, it should be terminated
	before the application exits. Modern systems are very good at freeing resources
	allocated by programs that exit, but GLFW sometimes has to change global system
	settings and these might not be restored without termination.


	@subsection init_hints Initialization hints

	Initialization hints are set before @ref glfwInit and affect how the library
	behaves until termination. Hints are set with @ref glfwInitHint.

	@code
	glfwInitHint(GLFW_JOYSTICK_HAT_BUTTONS, GLFW_FALSE);
	@endcode

	The values you set hints to are never reset by GLFW, but they only take effect
	during initialization. Once GLFW has been initialized, any values you set will
	be ignored until the library is terminated and initialized again.

	Some hints are platform specific. These may be set on any platform but they
	will only affect their specific platform. Other platforms will ignore them.
	Setting these hints requires no platform specific headers or functions.


	@subsubsection init_hints_shared Shared init hints

	@anchor GLFW_JOYSTICK_HAT_BUTTONS
	__GLFW_JOYSTICK_HAT_BUTTONS__ specifies whether to also expose joystick hats as
	buttons, for compatibility with earlier versions of GLFW that did not have @ref
	glfwGetJoystickHats. Set this with @ref glfwInitHint.


	@subsubsection init_hints_osx macOS specific init hints

	@anchor GLFW_COCOA_CHDIR_RESOURCES_hint
	__GLFW_COCOA_CHDIR_RESOURCES__ specifies whether to set the current directory to
	the application to the `Contents/Resources` subdirectory of the application's
	bundle, if present. Set this with @ref glfwInitHint.

	@anchor GLFW_COCOA_MENUBAR_hint
	__GLFW_COCOA_MENUBAR__ specifies whether to create a basic menu bar, either from
	a nib or manually, when the first window is created, which is when AppKit is
	initialized. Set this with @ref glfwInitHint.


	@subsubsection init_hints_values Supported and default values

	Initialization hint \| Default value \| Supported values
	------------------------------- \| ------------- \| ----------------
	@ref GLFW_JOYSTICK_HAT_BUTTONS \| `GLFW_TRUE` \| `GLFW_TRUE` or `GLFW_FALSE`
	@ref GLFW_COCOA_CHDIR_RESOURCES \| `GLFW_TRUE` \| `GLFW_TRUE` or `GLFW_FALSE`
	@ref GLFW_COCOA_MENUBAR \| `GLFW_TRUE` \| `GLFW_TRUE` or `GLFW_FALSE`


	@subsection intro_init_terminate Terminating GLFW

	Before your application exits, you should terminate the GLFW library if it has
	been initialized. This is done with @ref glfwTerminate.

	@code
	glfwTerminate();
	@endcode

	This will destroy any remaining window, monitor and cursor objects, restore any
	modified gamma ramps, re-enable the screensaver if it had been disabled and free
	any other resources allocated by GLFW.

	Once the library is terminated, it is as if it had never been initialized and
	you will need to initialize it again before being able to use GLFW. If the
	library was not initialized or had already been terminated, it return
	immediately.


	@section error_handling Error handling

	Some GLFW functions have return values that indicate an error, but this is often
	not very helpful when trying to figure out what happened or why it occurred.
	Other functions have no return value reserved for errors, so error notification
	needs a separate channel. Finally, far from all GLFW functions have return
	values.

	The last [error code](@ref errors) for the calling thread can be queried at any
	time with @ref glfwGetError.

	@code
	int code = glfwGetError(NULL);

	if (code != GLFW_NO_ERROR)
	handle_error(code);
	@endcode

	If no error has occurred since the last call, @ref GLFW_NO_ERROR (zero) is
	returned. The error is cleared before the function returns.

	The error code indicates the general category of the error. Some error codes,
	such as @ref GLFW_NOT_INITIALIZED has only a single meaning, whereas others like
	@ref GLFW_PLATFORM_ERROR are used for many different errors.

	GLFW often has more information about an error than its general category. You
	can retrieve a UTF-8 encoded human-readable description along with the error
	code. If no error has occurred since the last call, the description is set to
	`NULL`.

	@code
	const char* description;
	int code = glfwGetError(&description);

	if (description)
	display_error_message(code, description);
	@endcode

	The retrieved description string is only valid until the next error occurs.
	This means you must make a copy of it if you want to keep it.

	You can also set an error callback, which will be called each time an error
	occurs. It is set with @ref glfwSetErrorCallback.

	@code
	glfwSetErrorCallback(error_callback);
	@endcode

	The error callback receives the same error code and human-readable description
	returned by @ref glfwGetError.

	@code
	void error_callback(int code, const char* description)
	{
	display_error_message(code, description);
	}
	@endcode

	The error callback is called after the error is stored, so calling @ref
	glfwGetError from within the error callback returns the same values as the
	callback argument.

	The description string passed to the callback is only valid until the error
	callback returns. This means you must make a copy of it if you want to keep it.

	__Reported errors are never fatal.__ As long as GLFW was successfully
	initialized, it will remain initialized and in a safe state until terminated
	regardless of how many errors occur. If an error occurs during initialization
	that causes @ref glfwInit to fail, any part of the library that was initialized
	will be safely terminated.

	Do not rely on a currently invalid call to generate a specific error, as in the
	future that same call may generate a different error or become valid.


	@section coordinate_systems Coordinate systems

	GLFW has two primary coordinate systems: the _virtual screen_ and the window
	_content area_ or _content area_. Both use the same unit: _virtual screen
	coordinates_, or just _screen coordinates_, which don't necessarily correspond
	to pixels.

	<img src="spaces.svg" width="90%" />

	Both the virtual screen and the content area coordinate systems have the X-axis
	pointing to the right and the Y-axis pointing down.

	Window and monitor positions are specified as the position of the upper-left
	corners of their content areas relative to the virtual screen, while cursor
	positions are specified relative to a window's content area.

	Because the origin of the window's content area coordinate system is also the
	point from which the window position is specified, you can translate content
	area coordinates to the virtual screen by adding the window position. The
	window frame, when present, extends out from the content area but does not
	affect the window position.

	Almost all positions and sizes in GLFW are measured in screen coordinates
	relative to one of the two origins above. This includes cursor positions,
	window positions and sizes, window frame sizes, monitor positions and video mode
	resolutions.

	Two exceptions are the [monitor physical size](@ref monitor_size), which is
	measured in millimetres, and [framebuffer size](@ref window_fbsize), which is
	measured in pixels.

	Pixels and screen coordinates may map 1:1 on your machine, but they won't on
	every other machine, for example on a Mac with a Retina display. The ratio
	between screen coordinates and pixels may also change at run-time depending on
	which monitor the window is currently considered to be on.


	@section guarantees_limitations Guarantees and limitations

	This section describes the conditions under which GLFW can be expected to
	function, barring bugs in the operating system or drivers. Use of GLFW outside
	of these limits may work on some platforms, or on some machines, or some of the
	time, or on some versions of GLFW, but it may break at any time and this will
	not be considered a bug.


	@subsection lifetime Pointer lifetimes

	GLFW will never free any pointer you provide to it and you must never free any
	pointer it provides to you.

	Many GLFW functions return pointers to dynamically allocated structures, strings
	or arrays, and some callbacks are provided with strings or arrays. These are
	always managed by GLFW and should never be freed by the application. The
	lifetime of these pointers is documented for each GLFW function and callback.
	If you need to keep this data, you must copy it before its lifetime expires.

	Many GLFW functions accept pointers to structures or strings allocated by the
	application. These are never freed by GLFW and are always the responsibility of
	the application. If GLFW needs to keep the data in these structures or strings,
	it is copied before the function returns.

	Pointer lifetimes are guaranteed not to be shortened in future minor or patch
	releases.


	@subsection reentrancy Reentrancy

	GLFW event processing and object destruction are not reentrant. This means that
	the following functions must not be called from any callback function:

	- @ref glfwDestroyWindow
	- @ref glfwDestroyCursor
	- @ref glfwPollEvents
	- @ref glfwWaitEvents
	- @ref glfwWaitEventsTimeout
	- @ref glfwTerminate

	These functions may be made reentrant in future minor or patch releases, but
	functions not on this list will not be made non-reentrant.


	@subsection thread_safety Thread safety

	Most GLFW functions must only be called from the main thread (the thread that
	calls main), but some may be called from any thread once the library has been
	initialized. Before initialization the whole library is thread-unsafe.

	The reference documentation for every GLFW function states whether it is limited
	to the main thread.

	Initialization, termination, event processing and the creation and
	destruction of windows, cursors and OpenGL and OpenGL ES contexts are all
	restricted to the main thread due to limitations of one or several platforms.

	Because event processing must be performed on the main thread, all callbacks
	except for the error callback will only be called on that thread. The error
	callback may be called on any thread, as any GLFW function may generate errors.

	The error code and description may be queried from any thread.

	- @ref glfwGetError

	Empty events may be posted from any thread.

	- @ref glfwPostEmptyEvent

	The window user pointer and close flag may be read and written from any thread,
	but this is not synchronized by GLFW.

	- @ref glfwGetWindowUserPointer
	- @ref glfwSetWindowUserPointer
	- @ref glfwWindowShouldClose
	- @ref glfwSetWindowShouldClose

	These functions for working with OpenGL and OpenGL ES contexts may be called
	from any thread, but the window object is not synchronized by GLFW.

	- @ref glfwMakeContextCurrent
	- @ref glfwGetCurrentContext
	- @ref glfwSwapBuffers
	- @ref glfwSwapInterval
	- @ref glfwExtensionSupported
	- @ref glfwGetProcAddress

	The raw timer functions may be called from any thread.

	- @ref glfwGetTimerFrequency
	- @ref glfwGetTimerValue

	The regular timer may be used from any thread, but reading and writing the timer
	offset is not synchronized by GLFW.

	- @ref glfwGetTime
	- @ref glfwSetTime

	Library version information may be queried from any thread.

	- @ref glfwGetVersion
	- @ref glfwGetVersionString

	All Vulkan related functions may be called from any thread.

	- @ref glfwVulkanSupported
	- @ref glfwGetRequiredInstanceExtensions
	- @ref glfwGetInstanceProcAddress
	- @ref glfwGetPhysicalDevicePresentationSupport
	- @ref glfwCreateWindowSurface

	GLFW uses synchronization objects internally only to manage the per-thread
	context and error states. Additional synchronization is left to the
	application.

	Functions that may currently be called from any thread will always remain so,
	but functions that are currently limited to the main thread may be updated to
	allow calls from any thread in future releases.


	@subsection compatibility Version compatibility

	GLFW uses [Semantic Versioning](https://semver.org/). This guarantees source
	and binary backward compatibility with earlier minor versions of the API. This
	means that you can drop in a newer version of the library and existing programs
	will continue to compile and existing binaries will continue to run.

	Once a function or constant has been added, the signature of that function or
	value of that constant will remain unchanged until the next major version of
	GLFW. No compatibility of any kind is guaranteed between major versions.

	Undocumented behavior, i.e. behavior that is not described in the documentation,
	may change at any time until it is documented.

	If the reference documentation and the implementation differ, the reference
	documentation will almost always take precedence and the implementation will be
	fixed in the next release. The reference documentation will also take
	precedence over anything stated in a guide.


	@subsection event_order Event order

	The order of arrival of related events is not guaranteed to be consistent
	across platforms. The exception is synthetic key and mouse button release
	events, which are always delivered after the window defocus event.


	@section intro_version Version management

	GLFW provides mechanisms for identifying what version of GLFW your application
	was compiled against as well as what version it is currently running against.
	If you are loading GLFW dynamically (not just linking dynamically), you can use
	this to verify that the library binary is compatible with your application.


	@subsection intro_version_compile Compile-time version

	The compile-time version of GLFW is provided by the GLFW header with the
	`GLFW_VERSION_MAJOR`, `GLFW_VERSION_MINOR` and `GLFW_VERSION_REVISION` macros.

	@code
	printf("Compiled against GLFW %i.%i.%i\n",
	GLFW_VERSION_MAJOR,
	GLFW_VERSION_MINOR,
	GLFW_VERSION_REVISION);
	@endcode


	@subsection intro_version_runtime Run-time version

	The run-time version can be retrieved with @ref glfwGetVersion, a function that
	may be called regardless of whether GLFW is initialized.

	@code
	int major, minor, revision;
	glfwGetVersion(&major, &minor, &revision);

	printf("Running against GLFW %i.%i.%i\n", major, minor, revision);
	@endcode


	@subsection intro_version_string Version string

	GLFW 3 also provides a compile-time generated version string that describes the
	version, platform, compiler and any platform-specific compile-time options.
	This is primarily intended for submitting bug reports, to allow developers to
	see which code paths are enabled in a binary.

	The version string is returned by @ref glfwGetVersionString, a function that may
	be called regardless of whether GLFW is initialized.

	__Do not use the version string__ to parse the GLFW library version. The @ref
	glfwGetVersion function already provides the version of the running library
	binary.

	The format of the string is as follows:
	- The version of GLFW
	- The name of the window system API
	- The name of the context creation API
	- Any additional options or APIs

	For example, when compiling GLFW 3.0 with MinGW using the Win32 and WGL
	back ends, the version string may look something like this:

	@code
	3.0.0 Win32 WGL MinGW
	@endcode

	*/