SDL2 bindings for Node.js. Provides window management, input events, audio playback/recording, and clipboard manipulation. Use together with @kmamal/gl for WebGL drawing.

It should work on Linux, Mac, and Windows. Prebuilt binaries are available for x64 architectures.

SDL2 is bundled along with the binaries so a separate installation is not necessary. This package is self-contained. Just run:

npm install @kmamal/sdl

(But if things go wrong do look over here)

import sdl from '@kmamal/sdl'

sdl.video.createWindow({ title: "Hello, World!" })

There are more examples in the examples/ folder, covering several common use cases, including how to draw using Canvas and WebGL, as well as how to package the application for distribution.

• sdl
  • Event: 'beforeQuit'
  • Event: 'quit'
  • sdl.info
• sdl.video
  • Image data
  • Pixel formats
  • sdl.video.displays
  • sdl.video.windows
  • sdl.video.focused
  • sdl.video.hovered
  • sdl.video.createWindow([options])
  • class Window
    • Event: 'show'
    • Event: 'hide'
    • Event: 'expose'
    • Event: 'minimize'
    • Event: 'maximize'
    • Event: 'restore'
    • Event: 'move'
    • Event: 'resize'
    • Event: 'focus'
    • Event: 'blur'
    • Event: 'hover'
    • Event: 'leave'
    • Event: 'beforeClose'
    • Event: 'close'
    • Event: 'keyDown'
    • Event: 'keyUp'
    • Event: 'textInput'
    • Event: 'mouseButtonDown'
    • Event: 'mouseButtonUp'
    • Event: 'mouseMove'
    • Event: 'mouseWheel'
    • Event: 'dropBegin'
    • Event: 'dropText'
    • Event: 'dropFile'
    • Event: 'dropComplete'
    • window.id
    • window.title
    • window.setTitle(title)
    • window.x
    • window.y
    • window.setPosition(x, y)
    • window.width
    • window.height
    • window.setSize(width, height)
    • window.visible
    • window.show([show])
    • window.hide()
    • window.fullscreen
    • window.setFullscreen(fullscreen)
    • window.resizable
    • window.setResizable(resizable)
    • window.borderless
    • window.setBorderless(borderless)
    • window.opengl
    • window.native
    • window.maximized
    • window.maximize()
    • window.minimized
    • window.minimize()
    • window.restore()
    • window.focused
    • window.focus()
    • window.hovered
    • window.render(width, height, stride, format, buffer)
    • window.setIcon(width, height, stride, format, buffer)
    • window.destroyed
    • window.destroy()
• sdl.audio
  • Audio data
  • Sample formats
  • Event: 'deviceAdd'
  • Event: 'deviceRemove'
  • sdl.audio.bytesPerSample(format)
  • sdl.audio.minSampleValue(format)
  • sdl.audio.maxSampleValue(format)
  • sdl.audio.zeroSampleValue(format)
  • sdl.audio.readSample(format, buffer[, offset])
  • sdl.audio.writeSample(format, buffer, value[, offset])
  • sdl.audio.devices
  • sdl.audio.openDevice(device[, options])
  • class AudioInstance
    • audioInstance.id
    • audioInstance.name
    • audioInstance.channels
    • audioInstance.frequency
    • audioInstance.format
    • audioInstance.bytesPerSample
    • audioInstance.minSampleValue
    • audioInstance.maxSampleValue
    • audioInstance.zeroSampleValue
    • audioInstance.readSample(buffer[, offset])
    • audioInstance.writeSample(buffer, value[, offset])
    • audioInstance.buffered
    • audioInstance.playing
    • audioInstance.play([play])
    • audioInstance.pause()
    • audioInstance.queued
    • audioInstance.clearQueue()
    • audioInstance.closed
    • audioInstance.close()
  • class AudioPlaybackInstance extends AudioInstance
    • playbackInstance.enqueue(buffer[, bytes])
  • class AudioRecordingInstance extends AudioInstance
    • recordingInstance.dequeue(buffer[, bytes])
• sdl.keyboard
  • Virtual keys
  • Enum: SCANCODE
  • sdl.keyboard.getKey(scancode)
  • sdl.keyboard.getScancode(key)
  • sdl.keyboard.getState()
• sdl.mouse
  • Mouse cursors
  • Enum: BUTTON
  • sdl.mouse.getButton(button)
  • sdl.mouse.position
  • sdl.mouse.setPosition(x, y)
  • sdl.mouse.setCursor(cursor)
  • sdl.mouse.setCursorImage(width, height, stride, format, buffer, x, y)
  • sdl.mouse.showCursor([show])
  • sdl.mouse.hideCursor()
  • sdl.mouse.capture([capture])
  • sdl.mouse.uncapture()
• sdl.clipboard
  • Event: 'update'
  • sdl.clipboard.text
  • sdl.clipboard.setText(text)

• prevent: <function (void) => void> Call this to prevent the application from closing.

Fired to indicate that the user has requested the application to close (usually by closing the last window). If you need to display any confirmation dialogs you should call event.prevent() and handle termination manually. If prevent is not called, then this event will be followed by a 'quit' event.

Indicates that the application is about to close. Handle any cleanup here. This event will be followed by a call to process.exit().

• <object>
  • version: <object>
    • compile: <object> The SDL2 version the bindings were compiled against.
      • major, minor, patch: <semver> The components of the version.
    • runtime: <object> The SDL2 version of the dynamic library the is loaded.
      • major, minor, patch: <semver> The components of the version.
  • platform: <string> The name of the platform we are running on. Possible values are: 'Linux', 'Windows', and 'Mac OS X'.
  • drivers: <object>
    • video: <object>
      • all: <string>[] A list of all video drivers.
      • current: <string> The video driver that is currently selected.
    • audio: <object>
      • all: <string>[] A list of all audio drivers.
      • current: <string> The audio driver that is currently selected.

This object is filled with the information produced during the initialization of SDL2. All the values will remain constant throughout the execution of the program. If you want to initialize SDL2 with drivers other than the default ones, you can do so via its environment variables.

Sample data for Ubuntu:

{
  version: {
    compile: { major: 2, minor: 0, patch: 10 },
    runtime: { major: 2, minor: 0, patch: 10 },
  },
  platform: 'Linux',
  drivers: {
    video: {
      all: [ 'x11', 'wayland', 'dummy' ],
      current: 'x11',
    },
    audio: {
      all: [ 'pulseaudio', 'alsa', 'sndio', 'dsp', 'disk', 'dummy' ],
      current: 'pulseaudio',
    },
  },
}

There are 3 places in the API where you will need to provide an image to the library:

• window.render()
• window.setIcon()
• mouse.setCursorImage()

All three of these functions accept the image as a series of arguments:

• width: <number> The width of the image in pixels.
• height: <number> The height of the image in pixels.
• stride: <number> How many bytes each row of the image takes up in the buffer. This is usually equal to width * bytesPerPixel, but can be larger if the rows of the buffer are padded to always be some multiple of bytes.
• format: <PixelFormat> The binary representation of the data in the buffer.
• buffer: <Buffer> Holds the actual pixel data for the image, in the format and layout specified by all the above arguments.

So for example, to fill the window with a red+green gradient you could do:

const { width, height } = window
const stride = width * 4
const buffer = Buffer.alloc(stride * height)

let offset = 0
for (let i = 0; i < height; i++) {
  for (let j = 0; j < width; j++) {
    buffer[offset++] = Math.floor(256 * i / height) // R
    buffer[offset++] = Math.floor(256 * j / width)  // G
    buffer[offset++] = 0                            // B
    buffer[offset++] = 255                          // A
  }
}

window.render(width, height, stride, 'rgba32', buffer)

String values used to represent how the pixels of an image are stored in a Buffer.

• <object>[]
  • name: <string> The name of the display.
  • format: <PixelFormat> The pixel format of the display.
  • frequency: <number> The refresh rate of the display.
  • geometry: <object> The desktop region represented by the display.
    • x, y, width, height: <Rect> The position and size of the display's geometry.
  • usable: <object> Similar to geometry, but excludes areas taken up by the OS or window manager such as menus, docks, e.t.c.
    • x, y, width, height: <Rect> The position and size of the display's usable region.
  • dpi: <object> Return pixel density for the display in dots/pixels-per-inch units.
    • horizontal: <number> The horizontal density.
    • vertical: <number> The vertical density.
    • diagonal: <number> The diagonal density.

A list of all detected displays. Sample output for two side-to-side monitors is below. Notice how the geometries don't overlap:

[
  {
    name: '0',
    format: 'rgb888',
    frequency: 60,
    geometry: { x: 0, y: 0, width: 1920, height: 1080 },
    usable: { x: 0, y: 27, width: 1920, height: 1053 },
    dpi: { horizontal: 141.76, vertical: 142.13, diagonal: 141.85 }
  },
  {
    name: '1',
    format: 'rgb888',
    frequency: 60,
    geometry: { x: 1920, y: 0, width: 1920, height: 1080 },
    usable: { x: 1920, y: 27, width: 1920, height: 1053 },
    dpi: { horizontal: 141.76, vertical: 142.13, diagonal: 141.85 }
  },
]

• <Window>[]

A list of all open windows.

• <Window>|<null>

The window that has the current keyboard focus, or null if no window has the keyboard focus.

• <Window>|<null>

The window that the mouse is hovered over, or null if the mouse is not over a window.

• options: <object>
  • title: <string> Will appear in the window's title bar. Default: ''
  • display: <number> An object from sdl.video.displays to specify in which display the window will appear (if you have multiple displays). Default: sdl.video.displays[0]
  • x: <number> The x position in which the window will appear relative to the screen, or null for centered. Default: null
  • y: <number> The y position in which the window will appear relative to the screen, or null for centered. Default: null
  • width: <number> The width of the window. Default: 640
  • height: <number> The height of the window. Default: 480
  • visible: <boolean> Set to false to create a hidden window that will only be shown when you call window.show(). Default: true
  • fullscreen: <boolean> Set to true to create the window in fullscreen mode. Default: false
  • resizable: <boolean> Set to true to allow resizing the window by dragging its borders. Default: false
  • borderless: <boolean> Set to true to completely hide the window's borders and title bar. Default: false
  • opengl: <boolean> Set to true to create an OpenGL-compatible window (for use with @kmamal/gl). Default: false
• Returns: <Window> an object representing the new window.

Creates a new window.

The following restrictions apply:

• If you specify the display option, you can't also specify the x or y options, and vice-versa.
• The resizable and borderless options can't both be true.

If you set the opengl option, then you can only render to the window with OpenGL calls. Calls to render() will fail.

This class is not directly exposed by the API so you can't use it with the new operator. Instead, objects returned by sdl.video.createWindow() are of this type.

Fired when a window becomes visible.

Fired when a window becomes hidden.

Fired when a window becomes exposed.

Fired when a window becomes minimized.

Fired when a window becomes maximized.

Fired when a window gets restored.

• x: <number> The window's new x position, relative to the screen.
• y: <number> The window's new y position, relative to the screen.

Fired when the window changes position.

• width: <number> The window's new width.
• height: <number> The window's new height.

Fired when the window changes size.

Fired when a window gains the keyboard focus.

Fired when a window loses the keyboard focus.

Fired when the mouse enters the window.

Fired when the mouse leaves the window.

• prevent: <function (void) => void> Call this to prevent the window from closing.

Fired to indicate that the user has requested the window to close (usually by clicking the "x" button). If you need to display any confirmation dialogs you should call event.prevent() and handle destruction manually. If prevent is not called, then this event will be followed by a 'close' event.

Indicates that the window is about to be destroyed. Handle any cleanup here. This event will be followed by a call to window.destroy().

• scancode: <Scancode> The scancode of the key that caused the event.
• key: <Key>|<null> The virtual key that caused the event, or null if the physical key does not correspond to any virtual key.
• repeat: <boolean> Is true if the event was generated by holding down a key for a long time.
• shift: <boolean> Is true if the Shift key was pressed when the event was generated.
• ctrl: <boolean> Is true if the Ctrl key was pressed when the event was generated.
• alt: <boolean> Is true if the Alt key was pressed when the event was generated.
• super: <boolean> Is true if the "Windows" key was pressed when the event was generated.
• altgr: <boolean> Is true if the AltGr key was pressed when the event was generated.
• capslock: <boolean> Is true if CapsLock was active when the event was generated.
• numlock: <boolean> Is true if NumLock was active when the event was generated.

Fired when a key is pressed, and will also be fired repeatedly afterwards if the key is held down.

• scancode: <Scancode> The scancode of the key that caused the event.
• key: <Key>|<null> The virtual key that caused the event, or null if the physical key does not correspond to any virtual key.
• shift: <boolean> Is true if the Shift key was pressed when the event was generated.
• ctrl: <boolean> Is true if the Ctrl key was pressed when the event was generated.
• alt: <boolean> Is true if the Alt key was pressed when the event was generated.
• super: <boolean> Is true if the "Windows" key was pressed when the event was generated.
• altgr: <boolean> Is true if the AltGr key was pressed when the event was generated.
• capslock: <boolean> Is true if CapsLock was active when the event was generated.
• numlock: <boolean> Is true if NumLock was active when the event was generated.

Fired when a key is released.

• text: <string> The unicode representation of the character that was entered.

Fired when the user enters text via the keyboard.

• x: <number> The mouse's x position when the event happened, relative to the window.
• y: <number> The mouse's y position when the event happened, relative to the window.
• touch: <boolean> Will be true if the event was caused by a touch event.
• button: <sdl.mouse.BUTTON> The button that was pressed.

Fired when a mouse button is pressed.

• x: <number> The mouse's x position when the event happened, relative to the window.
• y: <number> The mouse's y position when the event happened, relative to the window.
• touch: <boolean> Will be true if the event was caused by a touch event.
• button: <sdl.mouse.BUTTON> The button that was released.

Fired when a mouse button is released.

• x: <number> The mouse's x position when the event happened, relative to the window.
• y: <number> The mouse's y position when the event happened, relative to the window.
• touch: <boolean> Will be true if the event was caused by a touch event.

Fired when the mouse moves.

• x: <number> The mouse's x position when the event happened, relative to the window.
• y: <number> The mouse's y position when the event happened, relative to the window.
• touch: <boolean> Will be true if the event was caused by a touch event.
• dx: <number> The wheel's x movement, relative to its last position.
• dy: <number> The wheel's y movement, relative to its last position.
• flipped: <boolean> Will be true if the underlying platform reverses the mouse wheel's scroll direction. Multiply dx and dy by -1 to get the correct values.

Fired when the mouse wheel is scrolled.

When dropping a set of items onto a window, first the 'drop-begin' event will be fired, then a number of 'drop-text' and/or 'drop-file' events will be fired corresponding to the contents of the drop, then finally the 'drop-complete' event will be fired.

• text: <string>: The text that was dropped onto the window.

Fired when one of the drops is a text item.

• file: <string>: The path to the file that was dropped onto the window.

Fired when one of the drops is a file.

Fired after a set of items has been dropped on a window.

• <number>

A unique identifier for the window.

• <string>

The text that appears in the window's title bar.

• title: <string>: The new title.

Changes the text that appears in the window's title bar.

• <number>

The window's x position, relative to the screen.

• <number>

The window's y position, relative to the screen.

• x: <number>: The new x position, relative to the screen.
• y: <number>: The new y position, relative to the screen.

Moves the window to a new position on the screen.

• <number>

The window's width.

• <number>

The window's height.

• width: <number>: The new width.
• height: <number>: The new height.

Changes the size of the window.

• <boolean>

Will be true if the window is visible.

• show: <boolean> Set to true to make the window visible, false to hide it. Default: true

Shows or hides the window.

Equivalent to window.show(false).

• <boolean>

Will be true if the window is fullscreen. A fullscreen window is displayed over the entire screen.

• fullscreen: <boolean> The new value of the property.

Changes the window's fullscreen property.

• <boolean>

Will be true if the window is resizable. A resizable window can be resized by dragging it's borders.

• resizable: <boolean> The new value of the property.

Changes the window's resizable property.

• <boolean>

Will be true if the window is borderless. A borderless window has no borders or title bar.

• borderless: <boolean> The new value of the property.

Changes the window's borderless property.

• <boolean>

Will be true if the window was created in OpenGl mode. In OpenGL mode, you can only render to the window with OpenGL calls. Calls to render() will fail.

• <any>

Holds a copy of the native (platform-specific) representation of the window. Only used for passing to @kmamal/gl.

• <boolean>

Will be true if the window is maximized.

Maximizes the window.

• <boolean>

Will be true if the window is minimized.

Minimizes the window.

Restores the window so it's neither minimized nor maximized.

• <boolean>

Will be true if the window has keyboard input.

Gives the window the keyboard focus.

• <boolean>

Will be true if the mouse is over the window.

• width, height, stride, format, buffer: <Image> The image to display on the window.

Displays an image in the window. This functions preforms no scaling (or positioning). To fill the whole window you must provide an image that matches the window's width and height.

• width, height, stride, format, buffer: <Image> The image to display as the icon of the window.

Set's the window's icon, usually displayed in the title bar and the taskbar.

• <boolean>

Will be true if the window is destroyed. A destroyed window object should not be used any further.

Destroys the window.

The playbackInstance.enqueue() function expects a buffer of audio data as input and the recordingInstance.dequeue() function returns a buffer of audio data as output. The format of the data in these buffers depends on the options you passed to sdl.audio.openDevice().

Audio data are a sequence of frames, with each frame being a sequence of samples. A sample is a single number representing the intensity of a single audio channel at a specific point in time. For audio with multiple channels, each point in time is represented by one sample per channel. This is called a frame. The samples in a frame are arranged as follows:

• For 1 channel (mono) a frame contains just the one sample.
• For 2 channels (stereo) the frame's first sample will be the one for the left channel, followed by the one for the right channel.
• For 4 channels (quad) the layout is front-left, front-right, rear-left, rear-right.
• For 6 channels (5.1) the layout is front-left, front-right, center, low-freq, rear-left, rear-right.

So for example, to fill a buffer with 3 seconds of a 440Hz sine wave, you could do:

const TWO_PI = 2 * Math.PI

const {
  channels,
  frequency,
  bytesPerSample,
  minSampleValue,
  maxSampleValue,
  zeroSampleValue,
} = playbackInstance

const range = maxSampleValue - minSampleValue
const amplitude = range / 2

const sineAmplitude = 0.3 * amplitude
const sineNote = 440
const sinePeriod = 1 / sineNote

const duration = 3
const numFrames = duration * frequency
const numSamples = numFrames * channels
const numBytes = numSamples * bytesPerSample
const buffer = Buffer.alloc(numBytes)

let offset = 0
for (let i = 0; i < numFrames; i++) {
  const time = i / frequency
  const angle = time / sinePeriod * TWO_PI
  const sample = zeroSampleValue + Math.sin(angle) * sineAmplitude
  for (let j = 0; j < channels; j++) {
    offset = playbackInstance.writeSample(buffer, sample, offset)
  }
}

String values used to represent how audio samples are stored in a Buffer.

• device: <object>: An object from sdl.audio.devices indicating the device that caused the event.

Fired when a new audio device becomes available. Check sdl.audio.devices to get the new list of audio devices.

• device: <object>: An object from sdl.audio.devices indicating the device that caused the event.

Fired when an existing audio device is removed. Check sdl.audio.devices to get the new list of audio devices. When this event is emitted, all instances that were opened from the removed device are closed automatically.

• format: <SampleFormat>: The desired sample format.
• Returns: <number> The number of bytes.

Helper function which maps each sample format to the corresponding number of bytes its samples take up.

• format: <SampleFormat>: The desired sample format.
• Returns: <number> The minimum sample value.

Helper function which maps each sample format to the corresponding minimum value its samples can take.

• format: <SampleFormat>: The desired sample format.
• Returns: <number> The maximum sample value.

Helper function which maps each sample format to the corresponding maximum value its samples can take.

• format: <SampleFormat>: The desired sample format.
• Returns: <number> The zero sample value.

Helper function which maps each sample format to the sample value that corresponds to silence.

• format: <SampleFormat>: The desired sample format.
• buffer: <Buffer> The buffer to read the sample from.
• offset: <number> The position from which to read the sample. Default: 0
• Returns: <number> The value of the sample read.

Helper function which calls the appropriate read* method of Buffer based on the format argument. For example, a call to sdl.audio.readSample('f32', buffer, offset) would be equivalent to buffer.readFloatLE(offset).

• format: <SampleFormat>: The desired sample format.
• buffer: <Buffer> The buffer to write the sample to.
• value: <number> The value of the sample to write.
• offset: <number> The position at which to write the sample. Default: 0
• Returns: <number> The updated offset.

Helper function which calls the appropriate write* method of Buffer based on the format argument. For example, a call to sdl.audio.writeSample('f32', buffer, value, offset) would be equivalent to buffer.writeFloatLE(value, offset).

• <object>[]
  • name: <string> The name of the device.
  • recording: <boolean> Will be true if this is a recording device.

A list of all the detected audio devices. Sample output for PulseAudio:

[
  { name: 'Built-in Audio Analog Stereo', recording: false },
  { name: 'Built-in Audio Analog Stereo', recording: true }
]

• device: <object> An object from sdl.audio.devices that should be opened.
• options: <object>
  • name: <string>: Some drivers accept custom names, such as a hostname/IP address for a remote audio server, or a filename in the diskaudio driver. Default: device.name.
  • channels: <number>: Number of audio channels. Valid values: 1, 2, 4, 6. Default 1.
  • frequency: <number>: The sampling frequency in frames per second. Default 48e3.
  • format: <SampleFormat>: The binary format for each sample. Default 'f32'.
  • buffered: <number>: Number of frames that will be buffered by the driver. Must be a power of 2. Default 4096.
• Returns: <AudioInstance> an object representing the opened audio device instance.

Initializes an audio device for playback/recording and returns a corresponding instance. If the opened device is a playback device, then the returned object will be an AudioPlaybackInstance, otherwise it will be an AudioRecordingInstance.

The channels, frequency and format options together define what the data in the Buffer objects you read from or write to the instance will look like. See also the section on audio data.

The buffered option specifies the "delay" that you will experience between the application and the audio driver. With smaller values you will have smaller delays, but you will also have to read/write data from/to the driver more frequently. Applications such as virtual instruments that need to play audio in reaction to user input will want to change this option to lower values.

This class is not directly exposed by the API so you can't use it with the new operator. It only serves as the base class for AudioPlaybackInstance and AudioRecordingInstance.

• <number>

A unique identifier for the instance.

• <object>

The device from which this instance was opened.

• <string>

The name the instance was opened with.

• <number>

The number of channels the instance was opened with.

• <number>

The sampling frequency (in frames per second) the instance was opened with.

• <SampleFormat>

The audio sample format the instance was opened with.

• <number>

The number of bytes that make up a single audio sample, based on the format the instance was opened with.

• <number>

The minimum value a sample can take, based on the format the instance was opened with.

• <number>

The maximum value a sample can take, based on the format the instance was opened with.

• <number>

The sample value that corresponds to silence, based on the format the instance was opened with.

• buffer: <Buffer> The buffer to read the sample from.
• offset: <number> The position from which to read the sample. Default: 0
• Returns: <number> The value of the sample read.

Helper function which calls the appropriate read* method of Buffer based on the format the instance was opened with. For example, for an instance opened with the 'f32' sample format, a call to audioinstance.readSample(buffer, offset) would be equivalent to buffer.readFloatLE(offset).

• buffer: <Buffer> The buffer to write the sample to.
• value: <number> The value of the sample to write.
• offset: <number> The position at which to write the sample. Default: 0
• Returns: <number> The updated offset.

Helper function which calls the appropriate write* method of Buffer based on the format the instance was opened with. For example, for an instance opened with the 'f32' sample format, a call to audioinstance.writeSample(buffer, value, offset) would be equivalent to buffer.writeFloatLE(value, offset).

• <number>

The buffer size (in frames) the instance was opened with.

• <boolean>

Will be true if the instance is currently playing.

• show: <boolean> Set to true to start the instance, false to stop. Default: true

Starts or stops the instance.

Equivalent to audioInstance.play(false)

• <number>

The number of bytes that are currently queued up, waiting to be either played by the instance or dequeued by the user.

Clears the queued data.

• <boolean>

Will be true if the instance is closed. A closed instance object should not be used any further.

Closes the instance.

This class is not directly exposed by the API so you can't use it with the new operator. Instead, objects returned by sdl.audio.openDevice() are of this type, if a playback device is opened.

• buffer: <Buffer> The buffer to read data from.
• bytes: <number> The number of bytes to read from the buffer. Default: buffer.length

Takes generated audio data from the buffer, and writes it to the queue, from which it will be played back.

This class is not directly exposed by the API so you can't use it with the new operator. Instead, objects returned by sdl.audio.openDevice() are of this type, if a recording device is opened.

• buffer: <Buffer> The buffer to write data to.
• bytes: <number> The number of bytes to write to the buffer. Default: buffer.length
• Returns: <number> The actual number of bytes read.

Takes recorded audio data that has been put on the queue, and writes it to the provided buffer.

There are three levels at which you can deal with the keyboard: physical keys (scancodes), virtual keys (keys), and text ('textInput' events).

On the physical level, each of the physical keys corresponds to a number: the key's scancode. For any given keyboard, the same key will always produce the same scancode. If your application cares about the layout of the keyboard (for example using the "WASD" keys as a substitute for arrow keys), then you should handle key events at this level using the scancode property of 'keyDown' and 'keyUp' events.

For the most part it's better to treat scancode values as arbitrary/meaningless, but SDL does provide a scancode enumeration with values based on the USB usage page standard so you should be able to derive some meaning from the scancodes if your keyboard is compatible.

More commonly, you don't care about the physical key itself but about the "meaning" associated with each key: the character that it produces ("a", "b", "@", " ", .e.t.c) or the function that it corresponds to ("Esc", "F4", "Ctrl", e.t.c.). Your operating system provides a "keyboard mapping" that associates physical keys with their corresponding meaning. Changing the keyboard mapping (for example by changing the language from English to German) will also change the corresponding meaning for each key (in the English-German example: the "y" and "z" keys will be switched). These meanings are represented as virtual key strings. If your application cares about the meaning associated with individual keys then you should handle key events at this level using the key property of 'keyDown' and 'keyUp' events.

Note that not all physical keys correspond to a well-defined meaning and thus don't have a virtual key value associated with them. The key events for these keys will have a null value for the key property.

But sometimes the application doesn't care about individual keys at all, but about the resulting text that the user is entering. Consider for example what happens when a user on a Greek keyboard layout enters an accent mark "´" followed by the letter "α" to produce the character "ά": Two keys were pressed, but only a single character was produced. Trying to handle text input by manually translating key presses to text is not a very viable solution. It's better to let the OS handle all the text logic, and get the final text by handling the rasulting ('textInput') events.

Used to represent physical keys on the keyboard. The same key will always produce the same scancode. Values are based on the USB usage page standard.

String values used to represent virtual keys in the context of the current keyboard mapping. Note that some keys do not correspond to any virtual key. A Key can be either one of the values below or any unicode character. Keys that produce characters are represented by that character. All others are represented by one of these values:

'&&', '+/-', '||', '00', '000', 'again', 'alt', 'altErase', 'app1', 'app2', 'application', 'audioFastForward', 'audioMute', 'audioNext', 'audioPlay', 'audioPrev', 'audioRewind', 'audioStop', 'back', 'backspace', 'binary', 'bookmarks', 'brightnessDown', 'brightnessUp', 'calculator', 'cancel', 'capsLock', 'clear', 'clearEntry', 'computer', 'copy', 'crSel', 'ctrl', 'currencySubUnit', 'currencyUnit', 'cut', 'decimal', 'decimalSeparator', 'delete', 'displaySwitch', 'down', 'eject', 'end', 'enter', 'escape', 'execute', 'exSel', 'f1', 'f2', 'f3', 'f4', 'f5', 'f6', 'f7', 'f8', 'f9', 'f10', 'f11', 'f12', 'f13', 'f14', 'f15', 'f16', 'f17', 'f18', 'f19', 'f20', 'f21', 'f22', 'f23', 'f24', 'find', 'forward', 'gui', 'help', 'hexadecimal', 'home', 'illumDown', 'illumToggle', 'illumUp', 'insert', 'left', 'mail', 'mediaSelect', 'memAdd', 'memClear', 'memDivide', 'memMultiply', 'memRecall', 'memStore', 'memSubtract', 'menu', 'modeSwitch', 'mute', 'numlock', 'octal', 'oper', 'out', 'pageDown', 'pageUp', 'paste', 'pause', 'power', 'printScreen', 'prior', 'refresh', 'return', 'right', 'scrollLock', 'search', 'select', 'separator', 'shift', 'sleep', 'space', 'stop', 'sysReq', 'tab', 'thousandsSeparator', 'undo', 'up', 'volumeDown', 'volumeUp', 'www', 'xor'.

• scancode: <Scancode>
• Returns: <Key>|<null>

Maps a scancode to the corresponding key based on the current keyboard mapping.

• key: <Key>
• Returns: <Scancode>

Maps a key to the corresponding scancode based on the current keyboard mapping. If multiple physical keys produce the same virtual key, then only the first one will be returned.

• Returns: <boolean[]> an object representing the state of each key.

The returned array can be indexed with Scancode values. Pressed keys will correspond to true values.

String values used to represent the types of cursors available on most systems.

Used to represent the buttons on a mouse. A mouse can have many buttons, but the values for the three most common ones are represented in this enum.

• button: <number> The index of the button.
• Returns: <boolean> Will be true if the button is pressed.

Queries the state of a single mouse button.

• <object>
  • x: <number> The x position of the mouse, relative to the screen.
  • y: <number> The y position of the mouse, relative to the screen.

The position of the mouse on the screen.

• x: <number> The new x position of the mouse, relative to the screen.
• y: <number> The new y position of the mouse, relative to the screen.

Moves the mouse to the specified position.

• cursor: <MouseCursor> The icon to use for the cursor.

Changes the icon that is displayed for the mouse cursor.

• width, height, stride, format, buffer: <Image> The image to use as a cursor.
• x: <number> The x position of the cursor image's hotspot.
• y: <number> The y position of the cursor image's hotspot.

Sets a image to be the mouse cursor. The hotspot represents the pixel that is considered to be under the mouse.

• show: <boolean> If true then the mouse cursor will be visible. Default true.

Changes the visibility of the mouse cursor.

Equivalent to sdl.mouse.showCursor(false).

• capture: <boolean> If true the mouse will be captured by the current window. Default true.

When the mouse has been captured you will continue receiving mouse events even if the mouse is not over a window.

Equivalent to sdl.mouse.capture(false).

Fired when the contents of the clipboard have changed. Check sdl.clipboard.text to get the new contents of the clipboard.

• <string>

The current text value on the clipboard.

• text: <string> The new value to save on the clipboard.

Changes the text contents of the clipboard.

This should not be necessary, since this package bundles the SDL2 runtime library along with its binaries, but you never know...

This package depends on SDL2 >=2.0.5. To install it on your system you might have to download one of the SDL2 Runtime Binaries.

• Linux: Run sudo apt install libsdl2-2.0-0 or whatever the equivalent command is for your package manager.
• Mac: Download the .dmg file, open it, and copy the SDL2.framework to /Library/Frameworks.
• Windows: Download the .zip file, extract it, and copy the .dll files to a path Node.js can link them from. This will usually be your system directory (C:\Windows) but see here for other paths where Windows will look for .dll files to link.

// TODO