Responder a eventos de toque
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Fazer objetos se mover de acordo com um programa predefinido, como o triângulo giratório, é útil para
chamando atenção, mas e se você quiser que os usuários interajam com os gráficos do OpenGL ES?
A chave para tornar seu aplicativo OpenGL ES interativo por toque é expandir sua implementação do
GLSurfaceView para substituir o
onTouchEvent() para detectar eventos de toque.
Esta lição mostra como ouvir eventos de toque para permitir que os usuários girem um objeto OpenGL ES.
Configurar um listener de toque
Para que seu aplicativo OpenGL ES responda a eventos de toque, é preciso implementar a
onTouchEvent() na sua
GLSurfaceView. O exemplo de implementação abaixo mostra como detectar
MotionEvent.ACTION_MOVE eventos e traduzi-los para
um ângulo de rotação de uma forma.
Kotlin
private const val TOUCH_SCALE_FACTOR: Float = 180.0f / 320f
...
private var previousX: Float = 0f
private var previousY: Float = 0f
override fun onTouchEvent(e: MotionEvent): Boolean {
// MotionEvent reports input details from the touch screen
// and other input controls. In this case, you are only
// interested in events where the touch position changed.
val x: Float = e.x
val y: Float = e.y
when (e.action) {
MotionEvent.ACTION_MOVE -> {
var dx: Float = x - previousX
var dy: Float = y - previousY
// reverse direction of rotation above the mid-line
if (y > height / 2) {
dx *= -1
}
// reverse direction of rotation to left of the mid-line
if (x < width / 2) {
dy *= -1
}
renderer.angle += (dx + dy) * TOUCH_SCALE_FACTOR
requestRender()
}
}
previousX = x
previousY = y
return true
}
Java
private final float TOUCH_SCALE_FACTOR = 180.0f / 320;
private float previousX;
private float previousY;
@Override
public boolean onTouchEvent(MotionEvent e) {
// MotionEvent reports input details from the touch screen
// and other input controls. In this case, you are only
// interested in events where the touch position changed.
float x = e.getX();
float y = e.getY();
switch (e.getAction()) {
case MotionEvent.ACTION_MOVE:
float dx = x - previousX;
float dy = y - previousY;
// reverse direction of rotation above the mid-line
if (y > getHeight() / 2) {
dx = dx * -1 ;
}
// reverse direction of rotation to left of the mid-line
if (x < getWidth() / 2) {
dy = dy * -1 ;
}
renderer.setAngle(
renderer.getAngle() +
((dx + dy) * TOUCH_SCALE_FACTOR));
requestRender();
}
previousX = x;
previousY = y;
return true;
}
Observe que, depois de calcular o ângulo de rotação, este método chama
requestRender() para informar
ao renderizador de que é hora de renderizar o frame. Essa é a abordagem mais eficiente neste exemplo.
porque o frame não precisa ser redesenhado, a menos que haja uma mudança na rotação. No entanto,
não afeta a eficiência, a menos que você solicite que o renderizador só redesenhe quando
as mudanças de dados usando o método setRenderMode()
. Por isso, certifique-se de que esta linha não seja comentada no renderizador:
Kotlin
class MyGlSurfaceView(context: Context) : GLSurfaceView(context) {
init {
// Render the view only when there is a change in the drawing data
renderMode = GLSurfaceView.RENDERMODE_WHEN_DIRTY
}
}
Java
public MyGLSurfaceView(Context context) {
...
// Render the view only when there is a change in the drawing data
setRenderMode(GLSurfaceView.RENDERMODE_WHEN_DIRTY);
}
Expor o ângulo de rotação
O código de exemplo acima exige que você exponha o ângulo de rotação pelo renderizador:
adicionar um membro público. Como o código do renderizador está sendo executado em uma linha de execução separada do usuário principal
linha de execução de interface do seu aplicativo, declare essa variável pública como volatile.
Este é o código para declarar a variável e expor o par de getter e setter:
Kotlin
class MyGLRenderer4 : GLSurfaceView.Renderer {
@Volatile
var angle: Float = 0f
}
Java
public class MyGLRenderer implements GLSurfaceView.Renderer {
...
public volatile float mAngle;
public float getAngle() {
return mAngle;
}
public void setAngle(float angle) {
mAngle = angle;
}
}
Aplicar rotação
Para aplicar a rotação gerada pela entrada por toque, comente o código que gera um ângulo e
adicione uma variável que contenha o ângulo gerado pela entrada de toque:
Kotlin
override fun onDrawFrame(gl: GL10) {
...
val scratch = FloatArray(16)
// Create a rotation for the triangle
// long time = SystemClock.uptimeMillis() % 4000L;
// float angle = 0.090f * ((int) time);
Matrix.setRotateM(rotationMatrix, 0, angle, 0f, 0f, -1.0f)
// Combine the rotation matrix with the projection and camera view
// Note that the mvpMatrix factor *must be first* in order
// for the matrix multiplication product to be correct.
Matrix.multiplyMM(scratch, 0, mvpMatrix, 0, rotationMatrix, 0)
// Draw triangle
triangle.draw(scratch)
}
Java
public void onDrawFrame(GL10 gl) {
...
float[] scratch = new float[16];
// Create a rotation for the triangle
// long time = SystemClock.uptimeMillis() % 4000L;
// float angle = 0.090f * ((int) time);
Matrix.setRotateM(rotationMatrix, 0, mAngle, 0, 0, -1.0f);
// Combine the rotation matrix with the projection and camera view
// Note that the vPMatrix factor *must be first* in order
// for the matrix multiplication product to be correct.
Matrix.multiplyMM(scratch, 0, vPMatrix, 0, rotationMatrix, 0);
// Draw triangle
mTriangle.draw(scratch);
}
Quando você tiver concluído as etapas descritas acima, execute o programa e arraste o dedo sobre o
tela para girar o triângulo:
Figura 1. Triângulo sendo girado com entrada por toque (o círculo mostra o toque
local).
O conteúdo e os exemplos de código nesta página estão sujeitos às licenças descritas na Licença de conteúdo. Java e OpenJDK são marcas registradas da Oracle e/ou suas afiliadas.
Última atualização 2025-07-27 UTC.
[[["Fácil de entender","easyToUnderstand","thumb-up"],["Meu problema foi resolvido","solvedMyProblem","thumb-up"],["Outro","otherUp","thumb-up"]],[["Não contém as informações de que eu preciso","missingTheInformationINeed","thumb-down"],["Muito complicado / etapas demais","tooComplicatedTooManySteps","thumb-down"],["Desatualizado","outOfDate","thumb-down"],["Problema na tradução","translationIssue","thumb-down"],["Problema com as amostras / o código","samplesCodeIssue","thumb-down"],["Outro","otherDown","thumb-down"]],["Última atualização 2025-07-27 UTC."],[],[],null,["# Respond to touch events\n\nMaking objects move according to a preset program like the rotating triangle is useful for\ngetting some attention, but what if you want to have users interact with your OpenGL ES graphics?\nThe key to making your OpenGL ES application touch interactive is expanding your implementation of\n[GLSurfaceView](/reference/android/opengl/GLSurfaceView) to override the\n[onTouchEvent()](/reference/android/view/View#onTouchEvent(android.view.MotionEvent)) to listen for touch events.\n\nThis lesson shows you how to listen for touch events to let users rotate an OpenGL ES object.\n\nSetup a touch listener\n----------------------\n\nIn order to make your OpenGL ES application respond to touch events, you must implement the\n[onTouchEvent()](/reference/android/view/View#onTouchEvent(android.view.MotionEvent)) method in your\n[GLSurfaceView](/reference/android/opengl/GLSurfaceView) class. The example implementation below shows how to listen for\n[MotionEvent.ACTION_MOVE](/reference/android/view/MotionEvent#ACTION_MOVE) events and translate them to\nan angle of rotation for a shape. \n\n### Kotlin\n\n```kotlin\nprivate const val TOUCH_SCALE_FACTOR: Float = 180.0f / 320f\n...\nprivate var previousX: Float = 0f\nprivate var previousY: Float = 0f\n\noverride fun onTouchEvent(e: MotionEvent): Boolean {\n // MotionEvent reports input details from the touch screen\n // and other input controls. In this case, you are only\n // interested in events where the touch position changed.\n\n val x: Float = e.x\n val y: Float = e.y\n\n when (e.action) {\n MotionEvent.ACTION_MOVE -\u003e {\n\n var dx: Float = x - previousX\n var dy: Float = y - previousY\n\n // reverse direction of rotation above the mid-line\n if (y \u003e height / 2) {\n dx *= -1\n }\n\n // reverse direction of rotation to left of the mid-line\n if (x \u003c width / 2) {\n dy *= -1\n }\n\n renderer.angle += (dx + dy) * TOUCH_SCALE_FACTOR\n requestRender()\n }\n }\n\n previousX = x\n previousY = y\n return true\n}\n```\n\n### Java\n\n```java\nprivate final float TOUCH_SCALE_FACTOR = 180.0f / 320;\nprivate float previousX;\nprivate float previousY;\n\n@Override\npublic boolean onTouchEvent(MotionEvent e) {\n // MotionEvent reports input details from the touch screen\n // and other input controls. In this case, you are only\n // interested in events where the touch position changed.\n\n float x = e.getX();\n float y = e.getY();\n\n switch (e.getAction()) {\n case MotionEvent.ACTION_MOVE:\n\n float dx = x - previousX;\n float dy = y - previousY;\n\n // reverse direction of rotation above the mid-line\n if (y \u003e getHeight() / 2) {\n dx = dx * -1 ;\n }\n\n // reverse direction of rotation to left of the mid-line\n if (x \u003c getWidth() / 2) {\n dy = dy * -1 ;\n }\n\n renderer.setAngle(\n renderer.getAngle() +\n ((dx + dy) * TOUCH_SCALE_FACTOR));\n requestRender();\n }\n\n previousX = x;\n previousY = y;\n return true;\n}\n```\n\nNotice that after calculating the rotation angle, this method calls\n[requestRender()](/reference/android/opengl/GLSurfaceView#requestRender()) to tell the\nrenderer that it is time to render the frame. This approach is the most efficient in this example\nbecause the frame does not need to be redrawn unless there is a change in the rotation. However, it\ndoes not have any impact on efficiency unless you also request that the renderer only redraw when\nthe data changes using the [setRenderMode()](/reference/android/opengl/GLSurfaceView#setRenderMode(int))\nmethod, so make sure this line is uncommented in the renderer: \n\n### Kotlin\n\n```kotlin\nclass MyGlSurfaceView(context: Context) : GLSurfaceView(context) {\n\n init {\n // Render the view only when there is a change in the drawing data\n renderMode = GLSurfaceView.RENDERMODE_WHEN_DIRTY\n }\n}\n```\n\n### Java\n\n```java\npublic MyGLSurfaceView(Context context) {\n ...\n // Render the view only when there is a change in the drawing data\n setRenderMode(GLSurfaceView.RENDERMODE_WHEN_DIRTY);\n}\n```\n\nExpose the rotation angle\n-------------------------\n\nThe example code above requires that you expose the rotation angle through your renderer by\nadding a public member. Since the renderer code is running on a separate thread from the main user\ninterface thread of your application, you must declare this public variable as `volatile`.\nHere is the code to declare the variable and expose the getter and setter pair: \n\n### Kotlin\n\n```kotlin\nclass MyGLRenderer4 : GLSurfaceView.Renderer {\n\n @Volatile\n var angle: Float = 0f\n}\n```\n\n### Java\n\n```java\npublic class MyGLRenderer implements GLSurfaceView.Renderer {\n ...\n\n public volatile float mAngle;\n\n public float getAngle() {\n return mAngle;\n }\n\n public void setAngle(float angle) {\n mAngle = angle;\n }\n}\n```\n\nApply rotation\n--------------\n\nTo apply the rotation generated by touch input, comment out the code that generates an angle and\nadd a variable that contains the touch input generated angle: \n\n### Kotlin\n\n```kotlin\noverride fun onDrawFrame(gl: GL10) {\n ...\n val scratch = FloatArray(16)\n\n // Create a rotation for the triangle\n // long time = SystemClock.uptimeMillis() % 4000L;\n // float angle = 0.090f * ((int) time);\n Matrix.setRotateM(rotationMatrix, 0, angle, 0f, 0f, -1.0f)\n\n // Combine the rotation matrix with the projection and camera view\n // Note that the mvpMatrix factor *must be first* in order\n // for the matrix multiplication product to be correct.\n Matrix.multiplyMM(scratch, 0, mvpMatrix, 0, rotationMatrix, 0)\n\n // Draw triangle\n triangle.draw(scratch)\n}\n```\n\n### Java\n\n```java\npublic void onDrawFrame(GL10 gl) {\n ...\n float[] scratch = new float[16];\n\n // Create a rotation for the triangle\n // long time = SystemClock.uptimeMillis() % 4000L;\n // float angle = 0.090f * ((int) time);\n Matrix.setRotateM(rotationMatrix, 0, mAngle, 0, 0, -1.0f);\n\n // Combine the rotation matrix with the projection and camera view\n // Note that the vPMatrix factor *must be first* in order\n // for the matrix multiplication product to be correct.\n Matrix.multiplyMM(scratch, 0, vPMatrix, 0, rotationMatrix, 0);\n\n // Draw triangle\n mTriangle.draw(scratch);\n}\n```\n\nWhen you have completed the steps described above, run the program and drag your finger over the\nscreen to rotate the triangle:\n\n\n**Figure 1.** Triangle being rotated with touch input (circle shows touch\nlocation)."]]
