Utiliser l'API Gamepad

L'API Gamepad introduit de nouveaux évènements à l'objet Window pour lire l'état des contrôleurs. En plus de ces événements, l'API ajoute aussi un objet Gamepad que vous pouvez utiliser pour récupérer l'état d'un contrôleur connecté, et une méthode navigator.getGamepads que vous pouvez utiliser pour obtenir la liste des contrôleurs connus par la page.

Connexion au contrôleur

Lorsqu'un nouveau contrôleur est connecté à l'ordinateur, la page active reçoit tout d'abord un événement Window.gamepadconnected. Si un contrôleur est déjà connecté lorsque la page termine de charger, l'événement Window.gamepadconnected est envoyé à la page active lorsque l'utilisateur appuie sur un bouton ou bouge un axe.

Vous pouvez utiliser Window.gamepadconnected ainsi :

window.addEventListener("gamepadconnected", function(e) {
  console.log("Contrôleur n°%d connecté : %s. %d boutons, %d axes.",
  e.gamepad.index, e.gamepad.id,
  e.gamepad.buttons.length, e.gamepad.axes.length);
});

Chaque contrôleur est associé à un identifiant unique, qui est disponible dans la propriété gamepad de l'événement.

Déconnexion du contrôleur

Lorsqu'un contrôleur est déconnecté, et si la page avait déjà reçu des données de ce contrôleur auparavant (par exemple par l'événement Window.gamepadconnected), un second événement est envoyé à la fenêtre active :  Window.gamepaddisconnected.

window.addEventListener("gamepaddisconnected", function(e) {
  console.log("Contrôleur n°%d déconnecté : %s",
  e.gamepad.index, e.gamepad.id);
});

La propriété index sera unique à chaque périphérique connecté au système, même si plusieurs contrôleurs du même type sont utilisés. La propriété correspond également à l'indice du tableau retourné par navigator.getGamepads.

var gamepads = {};

function gamepadHandler(event, connecting) {
  var gamepad = event.gamepad;
  // Note :
  // gamepad === navigator.getGamepads()[gamepad.index]

  if (connecting) {
    gamepads[gamepad.index] = gamepad;
  } else {
    delete gamepads[gamepad.index];
  }
}

window.addEventListener("gamepadconnected", function(e) { gamepadHandler(e, true); }, false);
window.addEventListener("gamepaddisconnected", function(e) { gamepadHandler(e, false); }, false);

Cet exemple montre également comment la propriété gamepad peut être conservée après que l'événement se soit terminé. Cette technique sera utilisée plus tard pour obtenir l'état du périphérique.

Querying the Gamepad object

As you can see, the gamepad events discussed above include a gamepad property on the event object, which returns a Gamepad object. We can use this in order to determine which gamepad (i.e., its ID) had caused the event, since multiple gamepads might be connected at once. We can do much more with the Gamepad object, including holding a reference to it and querying it to find out which buttons and axes are being pressed at any one time. Doing so is often desirable for games or other interactive web pages that need to know the state of a gamepad now vs. the next time an event fires.

Performing such checks tends to involve using the Gamepad object in conjunction with an animation loop (e.g., requestAnimationFrame), where developers want to make decisions for the current frame based on the state of the gamepad or gamepads.

window.addEventListener("gamepadconnected", function(e) {
  var gp = navigator.getGamepads()[e.gamepad.index];
  console.log("Gamepad connected at index %d: %s. %d buttons, %d axes.",
  gp.index, gp.id,
  gp.buttons.length, gp.axes.length);
});

The Gamepad object's properties are as follows:

• id: A string containing some information about the controller. This is not strictly specified, but in Firefox it will contain three pieces of information separated by dashes (-): two 4-digit hexadecimal strings containing the USB vendor and product id of the controller, and the name of the controller as provided by the driver. This information is intended to allow you to find a mapping for the controls on the device as well as display useful feedback to the user.
• index: An integer that is unique for each gamepad currently connected to the system. This can be used to distinguish multiple controllers. Note that disconnecting a device and then connecting a new device may reuse the previous index.
• mapping: A string indicating whether the browser has remapped the controls on the device to a known layout. Currently there is only one supported known layout–the standard gamepad. If the browser is able to map controls on the device to that layout the mapping property will be set to the string standard.
• connected: A boolean indicating whether the gamepad is still connected to the system. If this is so the value is True; if not, it is False.
• buttons: An array of GamepadButton objects representing the buttons present on the device. Each GamepadButton has a pressed and a value property:
  • The pressed property is a boolean indicating whether the button is currently pressed (true) or unpressed (false).
  • The value property is a floating point value used to enable representing analog buttons, such as the triggers on many modern gamepads. The values are normalized to the range 0.0..1.0, with 0.0 representing a button that is not pressed, and 1.0 representing a button that is fully pressed.
• axes: An array representing the controls with axes present on the device (e.g. analog thumb sticks). Each entry in the array is a floating point value in the range -1.0 - 1.0, representing the axis position from the lowest value (-1.0) to the highest value (1.0).
• timestamp: This returns a DOMHighResTimeStamp representing the last time the data for this gamepad was updated, allowing developers to determine if the axes and button data have been updated from the hardware. The value must be relative to the navigationStart attribute of the PerformanceTiming interface. Values are monotonically increasing, meaning that they can be compared to determine the ordering of updates, as newer values will always be greater than or equal to older values. Note that this property is not currently supported in Firefox.

Using button information

Let's look at a simple example that displays connection information for one gamepad (it ignores subsequent gamepad connections) and allows you to move a ball around the screen using the four gamepad buttons on the right hand side of the gamepad. You can view the demo live, and find the source code on Github.

To start with, we declare some variables: The gamepadInfo paragraph that the connection info is written into, the ball that we want to move, the start variable that acts as the ID for requestAnimation Frame, the a and b variables that act as position modifiers for moving the ball, and the shorthand variables that will be used for the requestAnimationFrame and cancelRequestAnimationFrame cross browser forks.

var gamepadInfo = document.getElementById("gamepad-info");
var ball = document.getElementById("ball");
var start;
var a = 0;
var b = 0;

var rAF = window.mozRequestAnimationFrame ||
  window.webkitRequestAnimationFrame ||
  window.requestAnimationFrame;

var rAFStop = window.mozCancelRequestAnimationFrame ||
  window.webkitCancelRequestAnimationFrame ||
  window.cancelRequestAnimationFrame;

Next we use the Window.gamepadconnected event to check for a gamepad being connected. When one is connected, we grab the gamepad using Navigator.getGamepads[0], print information about the gamepad into our gamepad info div, and fire the gameLoop() function that starts the whole ball movement process up.

window.addEventListener("gamepadconnected", function(e) {
  var gp = navigator.getGamepads()[e.gamepad.index];
  gamepadInfo.innerHTML = "Gamepad connected at index " + gp.index + ": " + gp.id + ". It has " + gp.buttons.length + " buttons and " + gp.axes.length + " axes.";

  gameLoop();
});

Now we use the Window.gamepaddisconnected event to check if the gamepad is disconnected again. If so, we stop the requestAnimationFrame loop (see below) and revert the gamepad information back to what it was originally.

window.addEventListener("gamepaddisconnected", function(e) {
  gamepadInfo.innerHTML = "Waiting for gamepad.";

  rAFStop(start);
});

Chrome does things differently here. Instead of constantly storing the gamepad's latest state in a variable it only stores a snapshot, so to do the same thing in Chrome you have to keep polling it and then only use the Gamepad object in code when it is available. We have done this below using Window.setInterval; once the object is available the gamepad info is outputted, the game loop is started, and the interval is cleared using Window.clearInterval. Note that in older versions of Chrome Navigator.getGamepads is implemented with a webkit prefix. We attempt to detect and handle both the prefixed version and the standard version of the function for backwards-compatibility.

if(!('GamepadEvent' in window)) {
  // No gamepad events available, poll instead.
  var interval = setInterval(pollGamepads, 500);
}

function pollGamepads() {
  var gamepads = navigator.getGamepads ? navigator.getGamepads() : (navigator.webkitGetGamepads ? navigator.webkitGetGamepads : []);
  for (var i = 0; i < gamepads.length; i++) {
    var gp = gamepads[i];
    if(gp) {
      gamepadInfo.innerHTML = "Gamepad connected at index " + gp.index + ": " + gp.id + ". It has " + gp.buttons.length + " buttons and " + gp.axes.length + " axes.";
      gameLoop();
      clearInterval(interval);
    }
  }
}

Now on to the main game loop. In each execution of the loop we check if one of four buttons is being pressed; if so, we update the values of the a and b movement variables appropriately, then update the left and top properties, changing their values to the current values of a and b respectively. This has the effect of moving the ball around the screen.  In current versions of Chrome (version 34 as of this writing) the button values are stored as an array of double values, instead of GamepadButton objects. This is fixed in development versions.

After all this is done, we use our rAF variable to request the next animation frame, running gameLoop() again.

function buttonPressed(b) {
  if (typeof(b) == "object") {
    return b.pressed;
  }
  return b == 1.0;
}

function gameLoop() {
  var gamepads = navigator.getGamepads ? navigator.getGamepads() : (navigator.webkitGetGamepads ? navigator.webkitGetGamepads : []);
  if (!gamepads)
    return;

  var gp = gamepads[0];
  if (buttonPressed(gp.buttons[0])) {
    b--;
  } else if (buttonPressed(gp.buttons[2])) {
    b++;
  }
  if(buttonPressed(gp.buttons[1])) {
    a++;
  } else if(buttonPressed(gp.buttons[3])) {
    a--;
  }

  ball.style.left = a*2 + "px";
  ball.style.top = b*2 + "px";

  var start = rAF(gameLoop);
};

Using axes information

TBD (basically the same, except using axes[i] rather than button[i].value for both Firefox and Chrome.)

Complete example: Displaying gamepad state

This example shows how to use the Gamepad object, as well as the Window.gamepadconnected and Window.gamepaddisconnected events in order to display the state of all gamepads connected to the system. You can find a working demo and look at the full source code on Github.

var haveEvents = 'GamepadEvent' in window;
var controllers = {};
var rAF = window.mozRequestAnimationFrame ||
  window.webkitRequestAnimationFrame ||
  window.requestAnimationFrame;

function connecthandler(e) {
  addgamepad(e.gamepad);
}
function addgamepad(gamepad) {
  controllers[gamepad.index] = gamepad; var d = document.createElement("div");
  d.setAttribute("id", "controller" + gamepad.index);
  var t = document.createElement("h1");
  t.appendChild(document.createTextNode("gamepad: " + gamepad.id));
  d.appendChild(t);
  var b = document.createElement("div");
  b.className = "buttons";
  for (var i=0; i<gamepad.buttons.length; i++) {
    var e = document.createElement("span");
    e.className = "button";
    //e.id = "b" + i;
    e.innerHTML = i;
    b.appendChild(e);
  }
  d.appendChild(b);
  var a = document.createElement("div");
  a.className = "axes";
  for (var i=0; i<gamepad.axes.length; i++) {
    var e = document.createElement("progress");
    e.className = "axis";
    //e.id = "a" + i;
    e.setAttribute("max", "2");
    e.setAttribute("value", "1");
    e.innerHTML = i;
    a.appendChild(e);
  }
  d.appendChild(a);
  document.getElementById("start").style.display = "none";
  document.body.appendChild(d);
  rAF(updateStatus);
}

function disconnecthandler(e) {
  removegamepad(e.gamepad);
}

function removegamepad(gamepad) {
  var d = document.getElementById("controller" + gamepad.index);
  document.body.removeChild(d);
  delete controllers[gamepad.index];
}

function updateStatus() {
  if (!haveEvents) {
    scangamepads();
  }
  for (j in controllers) {
    var controller = controllers[j];
    var d = document.getElementById("controller" + j);
    var buttons = d.getElementsByClassName("button");
    for (var i=0; i<controller.buttons.length; i++) {
      var b = buttons[i];
      var val = controller.buttons[i];
      var pressed = val == 1.0;
      if (typeof(val) == "object") {
        pressed = val.pressed;
        val = val.value;
      }
      var pct = Math.round(val * 100) + "%"
      b.style.backgroundSize = pct + " " + pct;
      if (pressed) {
        b.className = "button pressed";
      } else {
        b.className = "button";
      }
    }

    var axes = d.getElementsByClassName("axis");
    for (var i=0; i<controller.axes.length; i++) {
      var a = axes[i];
      a.innerHTML = i + ": " + controller.axes[i].toFixed(4);
      a.setAttribute("value", controller.axes[i] + 1);
    }
  }
  rAF(updateStatus);
}

function scangamepads() {
  var gamepads = navigator.getGamepads ? navigator.getGamepads() : (navigator.webkitGetGamepads ? navigator.webkitGetGamepads() : []);
  for (var i = 0; i < gamepads.length; i++) {
    if (gamepads[i]) {
      if (!(gamepads[i].index in controllers)) {
        addgamepad(gamepads[i]);
      } else {
        controllers[gamepads[i].index] = gamepads[i];
      }
    }
  }
}

window.addEventListener("gamepadconnected", connecthandler);
window.addEventListener("gamepaddisconnected", disconnecthandler);
if (!haveEvents) {
  setInterval(scangamepads, 500);
}

Specifications

Browser compatibility