b486678290
Library -Artifacts
181 lines
8.4 KiB
C#
181 lines
8.4 KiB
C#
using UnityEngine;
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using UnityEngine.InputSystem;
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using UnityEngine.InputSystem.Layouts;
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using UnityEngine.InputSystem.Utilities;
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#if UNITY_EDITOR
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using UnityEditor;
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using UnityEngine.InputSystem.Editor;
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#endif
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// Let's say we want to have a composite that takes an axis and uses
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// it's value to multiply the length of a vector from a stick. This could
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// be used, for example, to have the right trigger on the gamepad act as
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// a strength multiplier on the value of the left stick.
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//
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// We start by creating a class that is based on InputBindingComposite<>.
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// The type we give it is the type of value that we will compute. In this
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// case, we will consume a Vector2 from the stick so that is the type
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// of value we return.
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//
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// NOTE: By advertising the type of value we return, we also allow the
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// input system to filter out our composite if it is not applicable
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// to a specific type of action. For example, if an action is set
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// to "Value" as its type and its "Control Type" is set to "Axis",
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// our composite will not be shown as our value type (Vector2) is
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// incompatible with the value type of Axis (float).
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//
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// Also, we need to register our composite with the input system. And we
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// want to do it in a way that makes the composite visible in the action
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// editor of the input system.
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//
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// For that to happen, we need to call InputSystem.RegisterBindingComposite
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// sometime during startup. We make that happen by using [InitializeOnLoad]
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// in the editor and [RuntimeInitializeOnLoadMethod] in the player.
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#if UNITY_EDITOR
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[InitializeOnLoad]
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#endif
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// We can customize the way display strings are formed for our composite by
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// annotating it with DisplayStringFormatAttribute. The string is simply a
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// list with elements to be replaced enclosed in curly braces. Everything
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// outside those will taken verbatim. The fragments inside the curly braces
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// in this case refer to the binding composite parts by name. Each such
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// instance is replaced with the display text for the corresponding
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// part binding.
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[DisplayStringFormat("{multiplier}*{stick}")]
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public class CustomComposite : InputBindingComposite<Vector2>
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{
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// In the editor, the static class constructor will be called on startup
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// because of [InitializeOnLoad].
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#if UNITY_EDITOR
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static CustomComposite()
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{
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// Trigger our RegisterBindingComposite code in the editor.
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Initialize();
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}
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#endif
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// In the player, [RuntimeInitializeOnLoadMethod] will make sure our
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// initialization code gets called during startup.
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[RuntimeInitializeOnLoadMethod(RuntimeInitializeLoadType.BeforeSceneLoad)]
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private static void Initialize()
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{
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// This registers the composite with the input system. After calling this
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// method, we can have bindings reference the composite. Also, the
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// composite will show up in the action editor.
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//
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// NOTE: We don't supply a name for the composite here. The default logic
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// will take the name of the type ("CustomComposite" in our case)
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// and snip off "Composite" if used as a suffix (which is the case
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// for us) and then use that as the name. So in our case, we are
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// registering a composite called "Custom" here.
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//
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// If we were to use our composite with the AddCompositeBinding API,
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// for example, it would look like this:
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//
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// myAction.AddCompositeBinding("Custom")
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// .With("Stick", "<Gamepad>/leftStick")
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// .With("Multiplier", "<Gamepad>/rightTrigger");
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InputSystem.RegisterBindingComposite<CustomComposite>();
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}
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// So, we need two parts for our composite. The part that delivers the stick
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// value and the part that delivers the axis multiplier. Note that each part
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// may be bound to multiple controls. The input system handles that for us
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// by giving us an integer identifier for each part that reads a single value
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// from however many controls are bound to the part.
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//
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// In our case, this could be used, for example, to bind the "multiplier" part
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// to both the left and the right trigger on the gamepad.
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// To tell the input system of a "part" binding that we need for a composite,
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// we add a public field with an "int" type and annotated with an [InputControl]
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// attribute. We set the "layout" property on the attribute to tell the system
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// what kind of control we expect to be bound to the part.
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//
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// NOTE: These part binding need to be *public fields* for the input system
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// to find them.
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//
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// So this is introduces a part to the composite called "multiplier" and
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// expecting an "Axis" control. The value of the field will be set by the
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// input system. It will be some internal, unique numeric ID for the part
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// which we can then use with InputBindingCompositeContext.ReadValue to
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// read out the value of just that part.
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[InputControl(layout = "Axis")]
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public int multiplier;
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// The other part we need is for the stick.
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//
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// NOTE: We could use "Stick" here but "Vector2" is a little less restrictive.
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[InputControl(layout = "Vector2")]
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public int stick;
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// We may also expose "parameters" on our composite. These can be configured
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// graphically in the action editor and also through AddCompositeBinding.
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//
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// Let's say we want to allow the user to specify an additional scale factor
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// to apply to the value of "multiplier". We can do so by simply adding a
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// public field of type float. Any public field that is not annotated with
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// [InputControl] will be treated as a possible parameter.
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//
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// If we added a composite with AddCompositeBinding, we could configure the
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// parameter like so:
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//
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// myAction.AddCompositeBinding("Custom(scaleFactor=0.5)"
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// .With("Multiplier", "<Gamepad>/rightTrigger")
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// .With("Stick", "<Gamepad>/leftStick");
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public float scaleFactor = 1;
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// Ok, so now we have all the configuration in place. The final piece we
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// need is the actual logic that reads input from "multiplier" and "stick"
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// and computes a final input value.
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//
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// We can do that by defining a ReadValue method which is the actual workhorse
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// for our composite.
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public override Vector2 ReadValue(ref InputBindingCompositeContext context)
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{
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// We read input from the parts we have by simply
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// supplying the part IDs that the input system has set up
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// for us to ReadValue.
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//
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// NOTE: Vector2 is a less straightforward than primitive value types
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// like int and float. If there are multiple controls bound to the
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// "stick" part, we need to tell the input system which one to pick.
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// We do so by giving it an IComparer. In this case, we choose
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// Vector2MagnitudeComparer to return the Vector2 with the greatest
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// length.
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var stickValue = context.ReadValue<Vector2, Vector2MagnitudeComparer>(stick);
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var multiplierValue = context.ReadValue<float>(multiplier);
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// The rest is simple. We just scale the vector we read by the
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// multiple from the axis and apply our scale factor.
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return stickValue * (multiplierValue * scaleFactor);
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}
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}
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// Our custom composite is complete and fully functional. We could stop here and
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// call it a day. However, for the sake of demonstration, let's say we also want
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// to customize how the parameters for our composite are edited. We have "scaleFactor"
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// so let's say we want to replace the default float inspector with a slider.
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//
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// We can replace the default UI by simply deriving a custom InputParameterEditor
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// for our composite.
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#if UNITY_EDITOR
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public class CustomCompositeEditor : InputParameterEditor<CustomComposite>
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{
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public override void OnGUI()
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{
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// Using the 'target' property, we can access an instance of our composite.
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var currentValue = target.scaleFactor;
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// The easiest way to lay out our UI is to simply use EditorGUILayout.
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// We simply assign the changed value back to the 'target' object. The input
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// system will automatically detect a change in value.
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target.scaleFactor = EditorGUILayout.Slider(m_ScaleFactorLabel, currentValue, 0, 2);
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}
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private GUIContent m_ScaleFactorLabel = new GUIContent("Scale Factor");
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}
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#endif
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