Merespons peristiwa sentuh
Tetap teratur dengan koleksi
Simpan dan kategorikan konten berdasarkan preferensi Anda.
Membuat objek bergerak sesuai dengan program {i>preset<i} seperti segitiga berputar berguna untuk
mendapatkan perhatian, tetapi bagaimana jika Anda ingin pengguna berinteraksi dengan grafis OpenGL ES?
Kunci untuk membuat aplikasi OpenGL ES interaktif sentuh adalah memperluas implementasi
GLSurfaceView untuk mengganti
onTouchEvent() untuk memproses peristiwa sentuh.
Tutorial ini menunjukkan cara memproses peristiwa sentuh agar memungkinkan pengguna memutar objek OpenGL ES.
Menyiapkan pemroses sentuhan
Agar aplikasi OpenGL ES merespons peristiwa sentuh, Anda harus mengimplementasikan antarmuka
Metode onTouchEvent() di
Class GLSurfaceView. Contoh implementasi di bawah ini
menunjukkan cara memproses
MotionEvent.ACTION_MOVE peristiwa dan menerjemahkannya ke
sudut rotasi untuk sebuah bentuk.
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;
}
Perhatikan bahwa setelah menghitung sudut rotasi, metode ini akan memanggil
requestRender() untuk memberi tahu
bahwa sudah waktunya untuk merender {i>frame<i}. Pendekatan ini adalah yang paling efisien dalam contoh ini
karena {i>frame<i} tidak perlu digambar ulang kecuali jika ada perubahan dalam rotasi. Namun,
tidak berdampak pada efisiensi, kecuali jika Anda juga meminta agar perender hanya menggambar ulang saat
data berubah menggunakan setRenderMode()
, jadi pastikan baris ini tidak dikomentari di perender:
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);
}
Menampilkan sudut rotasi
Kode contoh di atas mengharuskan Anda mengekspos sudut rotasi melalui perender dengan
menambahkan anggota publik. Karena kode perender berjalan pada thread terpisah dari pengguna utama
thread antarmuka aplikasi, Anda harus mendeklarasikan variabel publik ini sebagai volatile.
Berikut adalah kode untuk mendeklarasikan variabel serta menampilkan pasangan getter dan 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;
}
}
Menerapkan rotasi
Untuk menerapkan rotasi yang dihasilkan oleh input sentuh, komentari kode yang menghasilkan sudut dan
tambahkan variabel yang berisi sudut yang dihasilkan input sentuh:
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);
}
Setelah Anda menyelesaikan langkah-langkah yang dijelaskan di atas, jalankan program dan seret jari Anda ke atas
untuk memutar segitiga:
Gambar 1. Segitiga diputar dengan input sentuh (lingkaran menampilkan sentuhan
lokasi).
Konten dan contoh kode di halaman ini tunduk kepada lisensi yang dijelaskan dalam Lisensi Konten. Java dan OpenJDK adalah merek dagang atau merek dagang terdaftar dari Oracle dan/atau afiliasinya.
Terakhir diperbarui pada 2025-07-27 UTC.
[[["Mudah dipahami","easyToUnderstand","thumb-up"],["Memecahkan masalah saya","solvedMyProblem","thumb-up"],["Lainnya","otherUp","thumb-up"]],[["Informasi yang saya butuhkan tidak ada","missingTheInformationINeed","thumb-down"],["Terlalu rumit/langkahnya terlalu banyak","tooComplicatedTooManySteps","thumb-down"],["Sudah usang","outOfDate","thumb-down"],["Masalah terjemahan","translationIssue","thumb-down"],["Masalah kode / contoh","samplesCodeIssue","thumb-down"],["Lainnya","otherDown","thumb-down"]],["Terakhir diperbarui pada 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)."]]
