Wednesday, November 4, 2020

Android Programming 3D Graphics with OpenGL ES (Including Nehe's Port)

Android 3D with OpenGL ES with Nehe's Port
TABLE OF CONTENTS (HIDE)

Android Programming

3D Graphics with OpenGL ES
(Including Nehe's Port)

Introduction

Read

  1. Android Training "Displaying Graphics with OpenGL ES" @ http://developer.android.com/training/graphics/opengl/index.html.
  2. Android API Guides "OpenGL ES" @ http://developer.android.com/guide/topics/graphics/opengl.html.
  3. Android Reference "Package android.opengl" @ http://developer.android.com/reference/android/opengl/package-summary.html.

Getting Started with 3D Graphics on Android

OpenGL ES

Android supports OpenGL ES in packages android.opengl, javax.microedition.khronos.opengles and javax.microedition.khronos.egl.

GLSurfaceView

For 3D graphics programming, you need to program you own custom view, instead using XML-layout. Fortunately, a 3D OpenGL ES view called GLSurfaceView is provided, which greatly simplifies our tasks.

I shall use the Nehe's Lessons (http://nehe.gamedev.net) to illustrate Android 3D programming

Example 1: Setting up OpenGL ES using GLSurfaceView (Nehe Lesson 1: Setting Up)

Create an android application called "Nehe 01", with project name "Nehe01", package name "com.test". Create a blank activity called "MyGLActivity".

The following program sets up the GLSurfaceView, and show a blank (dark green) screen.

MyGLActivity.java
package com.test;
   
import android.app.Activity;
import android.opengl.GLSurfaceView;
import android.os.Bundle;
/**
 * Our OpenGL program's main activity
 */
public class MyGLActivity extends Activity {
   
   private GLSurfaceView glView;   // Use GLSurfaceView
  
   // Call back when the activity is started, to initialize the view
   @Override
   protected void onCreate(Bundle savedInstanceState) {
      super.onCreate(savedInstanceState);
      glView = new GLSurfaceView(this);           // Allocate a GLSurfaceView
      glView.setRenderer(new MyGLRenderer(this)); // Use a custom renderer
      this.setContentView(glView);                // This activity sets to GLSurfaceView
   }
   
   // Call back when the activity is going into the background
   @Override
   protected void onPause() {
      super.onPause();
      glView.onPause();
   }
   
   // Call back after onPause()
   @Override
   protected void onResume() {
      super.onResume();
      glView.onResume();
   }
}
Dissecting MyActivity.java

We define MyActivity by extending Activity, so as to override onCreate(), onPause() and onResume(). We then override onCreate() to allocate a GLSurfaceView, set the view's renderer to a custom renderer (to be defined below), and set this activity to use the view.

MyGLRenderer.java

This is our custom OpenGL renderer class.

package com.test;
  
import javax.microedition.khronos.egl.EGLConfig;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.opengl.GLU;
/**
 *  OpenGL Custom renderer used with GLSurfaceView 
 */
public class MyGLRenderer implements GLSurfaceView.Renderer {
   Context context;   // Application's context
   
   // Constructor with global application context
   public MyGLRenderer(Context context) {
      this.context = context;
   }
   
   // Call back when the surface is first created or re-created
   @Override
   public void onSurfaceCreated(GL10 gl, EGLConfig config) {
      gl.glClearColor(0.0f, 0.0f, 0.0f, 1.0f);  // Set color's clear-value to black
      gl.glClearDepthf(1.0f);            // Set depth's clear-value to farthest
      gl.glEnable(GL10.GL_DEPTH_TEST);   // Enables depth-buffer for hidden surface removal
      gl.glDepthFunc(GL10.GL_LEQUAL);    // The type of depth testing to do
      gl.glHint(GL10.GL_PERSPECTIVE_CORRECTION_HINT, GL10.GL_NICEST);  // nice perspective view
      gl.glShadeModel(GL10.GL_SMOOTH);   // Enable smooth shading of color
      gl.glDisable(GL10.GL_DITHER);      // Disable dithering for better performance
  
      // You OpenGL|ES initialization code here
      // ......
   }
   
   // Call back after onSurfaceCreated() or whenever the window's size changes
   @Override
   public void onSurfaceChanged(GL10 gl, int width, int height) {
      if (height == 0) height = 1;   // To prevent divide by zero
      float aspect = (float)width / height;
   
      // Set the viewport (display area) to cover the entire window
      gl.glViewport(0, 0, width, height);
  
      // Setup perspective projection, with aspect ratio matches viewport
      gl.glMatrixMode(GL10.GL_PROJECTION); // Select projection matrix
      gl.glLoadIdentity();                 // Reset projection matrix
      // Use perspective projection
      GLU.gluPerspective(gl, 45, aspect, 0.1f, 100.f);
  
      gl.glMatrixMode(GL10.GL_MODELVIEW);  // Select model-view matrix
      gl.glLoadIdentity();                 // Reset
  
      // You OpenGL|ES display re-sizing code here
      // ......
   }
   
   // Call back to draw the current frame.
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers using clear-value set earlier
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);
     
      // You OpenGL|ES rendering code here
      // ......
   }
}
Dissecting MyGLRenderer.java

Our custom rendering class implements interface GLSurfaceView.Renderer, which is responsible to make the OpenGL calls to render a frame. It declare 3 methods to be called back by the Android graphics sub-system upon specific GL events.

  1. onSurfaceCreated(GL10 gl, EGLConfig config): Called when the surface is first created or recreated. It can be used to perform one-time initialization tasks such as setting the clear-value for color and depth, enabling depth-test, etc.
  2. onSurfaceChanged(GL10 gl, int width, int height): Called when the surface is first displayed and after window's size changes. It is used to set the view port and projection mode.
    In our OpenGL renderer, we set the Android's view port (display area) to cover the entire screen from (0,0) to (width-1, height-1):
    gl.glViewport(0, 0, width, height);
    We also choose the perspective projection and set the projection volume, with aspect ratio matches the view port, as follows:
    // OpenGL uses two transformation matrices: projection matrix and model-view matrix
    // We select the projection matrix to setup the projection
    gl.glMatrixMode(GL10.GL_PROJECTION); // Select projection matrix
    gl.glLoadIdentity();                 // Reset projection matrix
    // Use perspective projection with the projection volume defined by
    //   fovy, aspect-ration, z-near and z-far
    GLU.gluPerspective(gl, 45, aspect, 0.1f, 100.f);
      
    // Select the model-view matrix to manipulate objects (Deselect the projection matrix)
    gl.glMatrixMode(GL10.GL_MODELVIEW);  // Select model-view matrix
    gl.glLoadIdentity();                 // Reset
  3. onDrawFrame(GL10 gl): Called to draw the current frame. You OpenGL rendering codes here.
    In our OpenGL renderer, We clear the color and depth buffers (using the clear-values set via glClear* earlier).
    gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);

In the Activity class, we construct a custom renderer, and use setRenderer() to set it for the view:

glView = new GLSurfaceView(this);       // Allocate a GLSurfaceView
glView.setRenderer(new MyGLRenderer()); // Set the renderer for the view

Run the program. You shall see a blank screen.

Example 2: Drawing 2D Shapes (Nehe Lesson 2: Your First Polygon)

Let us get started by drawing 2D polygons as illustrated (Push Ctrl-F11 to switch the emulator in landscape orientation):

Create an android application called "Nehe 02", with project name "Nehe02", package name "com.test". Create a blank activity called "MyGLActivity".

Triangle.java

We first define a class called Triangle.

package com.test;
  
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
  
/*
 * A triangle with 3 vertices.
 */
public class Triangle {
   private FloatBuffer vertexBuffer;  // Buffer for vertex-array
   private ByteBuffer indexBuffer;    // Buffer for index-array
  
   private float[] vertices = {  // Vertices of the triangle
       0.0f,  1.0f, 0.0f, // 0. top
      -1.0f, -1.0f, 0.0f, // 1. left-bottom
       1.0f, -1.0f, 0.0f  // 2. right-bottom
   };
   private byte[] indices = { 0, 1, 2 }; // Indices to above vertices (in CCW)
 
   // Constructor - Setup the data-array buffers
   public Triangle() {
      // Setup vertex-array buffer. Vertices in float. A float has 4 bytes.
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert byte buffer to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
    
      // Setup index-array buffer. Indices in byte.
      indexBuffer = ByteBuffer.allocateDirect(indices.length);
      indexBuffer.put(indices);
      indexBuffer.position(0);
   }
  
   // Render this shape
   public void draw(GL10 gl) {
      // Enable vertex-array and define the buffers
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
      
      // Draw the primitives via index-array
      gl.glDrawElements(GL10.GL_TRIANGLES, indices.length, GL10.GL_UNSIGNED_BYTE, indexBuffer);
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
   }
}
Dissecting Triangle.java

In OpenGL ES, you cannot define individual vertex via glVertex command (this command is not supported in ES due to inefficiency). Instead, you have to use a vertex array to define a group of vertices. This is done in two steps:

  1. We first define the (x, y, z) location of the vertices in a Java array:
    private float[] vertices = {  // Vertices of the triangle
        0.0f,  1.0f, 0.0f, // 0. top
       -1.0f, -1.0f, 0.0f, // 1. left-bottom
        1.0f, -1.0f, 0.0f  // 2. right-bottom
    };
  2. We then allocate the vertex-array buffer, and transfer the data into the buffer. We use nio's buffer because they are placed on the native heap and are not garbage-collected.
    private FloatBuffer vertexBuffer;
    ......
    // Allocate a raw byte buffer. A float has 4 bytes
    ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
    // Need to use native byte order
    vbb.order(ByteOrder.nativeOrder());
    // Convert the byte buffer into float buffer
    vertexBuffer = vbb.asFloatBuffer();
    // Transfer the data into the buffer
    vertexBuffer.put(vertices);
    // Rewind
    vertexBuffer.position(0);

To render from the vertex-array, we need to enable client-state vertex-array:

gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);

We can then use method glDrawArrays() to render from the vertex array directly, or glDrawElements() to render via an index array.

In the above example, we set up an index array, which indexes into the vertex array (and its associated color array), as follows. Take note that the vertices are arranged in counter-clockwise (CCW) manner, with normal pointing out of the screen (or positive z-direction).

private ByteBuffer indexBuffer;
......
byte[] indices = { 0, 1, 2 };   // CCW
......
indexBuffer = ByteBuffer.allocateDirect(indices.length);  // Allocate raw byte buffer
indexBuffer.put(indices);   // Transfer data into buffer
indexBuffer.position(0);    // rewind

We render the triangle in the draw() method, with the following steps:

  1. We first enable vertex-array client states.
    gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
    
  2. We then specify the location of the buffers via:
    gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);   
      // gl*Pointer(int size, int type, int stride, Buffer pointer)
      //   size: number of coordinates per vertex (must be 2, 3, or 4).
      //   type: data type of vertex coordinate, GL_BYTE, GL_SHORT, GL_FIXED, or GL_FLOAT
      //   stride: the byte offset between consecutive vertices. 0 for tightly packed.
    
  3. Finally, we render the primitives using glDrawElements(), which uses the index array to reference the vertex and color arrays.
    gl.glDrawElements(GL10.GL_TRIANGLES, numIndices, GL10.GL_UNSIGNED_BYTE, indexBuffer);
      // glDrawElements(int mode, int count, int type, Buffer indices)
      //   mode: GL_POINTS, GL_LINE_STRIP, GL_LINE_LOOP, GL_LINES, GL_TRIANGLE_STRIP, GL_TRIANGLE_FAN, or GL_TRIANGLES
      //   count: the number of elements to be rendered.
      //   type: data-type of indices (must be GL_UNSIGNED_BYTE or GL_UNSIGNED_SHORT).
      //   indices: pointer to the index array. 
    gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
Square.java

Similarly, let's define a quad. Take note that OpenGL ES does not support quad as a primitive. We need to draw two triangles instead. We shall use the same color for all the vertices of the quad. The color can be set via glColor.

package com.test;
  
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
/*
 * A square drawn in 2 triangles (using TRIANGLE_STRIP).
 */
public class Square {
   private FloatBuffer vertexBuffer;  // Buffer for vertex-array
  
   private float[] vertices = {  // Vertices for the square
      -1.0f, -1.0f,  0.0f,  // 0. left-bottom
       1.0f, -1.0f,  0.0f,  // 1. right-bottom
      -1.0f,  1.0f,  0.0f,  // 2. left-top
       1.0f,  1.0f,  0.0f   // 3. right-top
   };
  
   // Constructor - Setup the vertex buffer
   public Square() {
      // Setup vertex array buffer. Vertices in float. A float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert from byte to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
   }
  
   // Render the shape
   public void draw(GL10 gl) {
      // Enable vertex-array and define its buffer
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
      // Draw the primitives from the vertex-array directly
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, vertices.length / 3);
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
   }
}
Dissecting Square.java

OpenGL ES 1.0 does not support quad as primitive. We shall draw a quad using TRIANGLE_STRIP, composing of 2 triangles v0v1v2 and v2v1v3, in counter-clockwise orientation.

For the triangle, we use glDrawElements() which uses an index array to reference the vertex and color array. For the quad, we shall use glDrawArrays() to directly render from the vertex-array, as follows:

gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);           // Enable vertex array
gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);  // Set the location of vertex array
gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, numVertices);
  // glDrawArrays(int mode, int first, int count)
  //   mode: GL_POINTS, GL_LINE_STRIP, GL_LINE_LOOP, GL_LINES, GL_TRIANGLE_STRIP, GL_TRIANGLE_FAN, or GL_TRIANGLES
  //   first: the starting index in the enabled arrays.
  //   count: the number of indices to be rendered.
gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
GL Renderer

Now, modify the renderer to draw the triangle and quad.

package com.test;
  
import javax.microedition.khronos.egl.EGLConfig;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.opengl.GLU;
  
public class MyGLRenderer implements GLSurfaceView.Renderer {
   
   Triangle triangle;     // ( NEW )
   Square quad;           // ( NEW )
   
   // Constructor
   public MyGLRenderer(Context context) {
      // Set up the data-array buffers for these shapes ( NEW )
      triangle = new Triangle();   // ( NEW )
      quad = new Square();         // ( NEW )
   }

   // Call back when the surface is first created or re-created.
   @Override
   public void onSurfaceCreated(GL10 gl, EGLConfig config) {
      // NO CHANGE - SKIP
      ......
   }
   
   // Call back after onSurfaceCreated() or whenever the window's size changes.
   @Override
   public void onSurfaceChanged(GL10 gl, int width, int height) {
      // NO CHANGE - SKIP
      ......
   }

   // Call back to draw the current frame.
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers using clear-values set earlier 
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);
  
      gl.glLoadIdentity();                 // Reset model-view matrix ( NEW )
      gl.glTranslatef(-1.5f, 0.0f, -6.0f); // Translate left and into the screen ( NEW )
      triangle.draw(gl);                   // Draw triangle ( NEW )
  
      // Translate right, relative to the previous translation ( NEW )
      gl.glTranslatef(3.0f, 0.0f, 0.0f);
      quad.draw(gl);                       // Draw quad ( NEW )
   }
}

We run the shapes' setup codes in the renderer's constructor, as they only have to run once. We invoke the shapes' draw() in renderer's onDrawFrame() which renders the shapes upon each frame refresh.

GL Activity

There is no change to the Activity codes in MyGLActivity.

Example 3: Color (Nehe Lesson 3: Color)

Triangle.java

Modify the triangle.java as follow:

package com.test;
  
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
  
/*
 * A triangle with 3 vertices. Each vertex has its own color.
 */
public class Triangle {
   private FloatBuffer vertexBuffer;  // Buffer for vertex-array
   private FloatBuffer colorBuffer;   // Buffer for color-array (NEW)
   private ByteBuffer indexBuffer;    // Buffer for index-array
  
   private float[] vertices = {  // Vertices of the triangle
       0.0f,  1.0f, 0.0f, // 0. top
      -1.0f, -1.0f, 0.0f, // 1. left-bottom
       1.0f, -1.0f, 0.0f  // 2. right-bottom
   };
   private byte[] indices = { 0, 1, 2 }; // Indices to above vertices (in CCW)
   private float[] colors = { // Colors for the vertices (NEW)
      1.0f, 0.0f, 0.0f, 1.0f, // Red (NEW)
      0.0f, 1.0f, 0.0f, 1.0f, // Green (NEW)
      0.0f, 0.0f, 1.0f, 1.0f  // Blue (NEW)
   };
  
   // Constructor - Setup the data-array buffers
   public Triangle() {
      // Setup vertex-array buffer. Vertices in float. A float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert byte buffer to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
   
      // Setup color-array buffer. Colors in float. A float has 4 bytes (NEW)
      ByteBuffer cbb = ByteBuffer.allocateDirect(colors.length * 4);
      cbb.order(ByteOrder.nativeOrder()); // Use native byte order (NEW)
      colorBuffer = cbb.asFloatBuffer();  // Convert byte buffer to float (NEW)
      colorBuffer.put(colors);            // Copy data into buffer (NEW)
      colorBuffer.position(0);            // Rewind (NEW)
    
      // Setup index-array buffer. Indices in byte.
      indexBuffer = ByteBuffer.allocateDirect(indices.length);
      indexBuffer.put(indices);
      indexBuffer.position(0);
   }
  
   // Render this shape
   public void draw(GL10 gl) {
      // Enable arrays and define the buffers
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
      gl.glEnableClientState(GL10.GL_COLOR_ARRAY);          // Enable color-array (NEW)
      gl.glColorPointer(4, GL10.GL_FLOAT, 0, colorBuffer);  // Define color-array buffer (NEW)
      
      // Draw the primitives via index-array
      gl.glDrawElements(GL10.GL_TRIANGLES, indices.length, GL10.GL_UNSIGNED_BYTE, indexBuffer);
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glDisableClientState(GL10.GL_COLOR_ARRAY);   // Disable color-array (NEW)
   }
}
Dissecting Triangle.java

During rendering, the vertex-array will be rendered together with other attributes (such as color, texture and normal), if these attributes are enabled.

In the above example, we define the colors of the vertices and copy them into a color-array buffer. We enable color-array client-state. The colors will be rendered together with the vertices in glDrawElements().

Square.java

Modify Square.java as follows:

package com.test;
   
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
/*
 * A square drawn in 2 triangles (using TRIANGLE_STRIP). This square has one color.
 */
public class Square {
   private FloatBuffer vertexBuffer;  // Buffer for vertex-array
   private float[] vertices = {  // Vertices for the square
      -1.0f, -1.0f,  0.0f,  // 0. left-bottom
       1.0f, -1.0f,  0.0f,  // 1. right-bottom
      -1.0f,  1.0f,  0.0f,  // 2. left-top
       1.0f,  1.0f,  0.0f   // 3. right-top
   };
  
   // Constructor - Setup the vertex buffer
   public Square() {
      // Setup vertex array buffer. Vertices in float. A float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert from byte to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
   }
  
   // Render the shape
   public void draw(GL10 gl) {
      // Enable vertex-array and define its buffer
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
      gl.glColor4f(0.5f, 0.5f, 1.0f, 1.0f);      // Set the current color (NEW)
      // Draw the primitives from the vertex array directly
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, vertices.length / 3);
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
   }
}
Dissecting Square.java

Our square has one color. That is, all vertices are rendered using the same color. Hence, there is no need to define a color-array. Instead, we added a glColor* command before rendering the square using glDrawArrays().

GL Renderer and GL Activity

No change.

Example 4: Rotation (Nehe Lesson 4: Rotation)

To rotate the shapes created in the previous example, we need to make some minor modifications to our renderer.

package com.test;
  
import javax.microedition.khronos.egl.EGLConfig;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.opengl.GLU;
  
public class MyGLRenderer implements GLSurfaceView.Renderer {
   
   private Triangle triangle;
   Square quad;
   
   // Rotational angle and speed (NEW)
   private float angleTriangle = 0.0f; // (NEW)
   private float angleQuad = 0.0f;     // (NEW)
   private float speedTriangle = 0.5f; // (NEW)
   private float speedQuad = -0.4f;    // (NEW)
   
   // Constructor
   public MyGLRenderer(Context context) {
      // Set up the buffers for these shapes
      triangle = new Triangle();
      quad = new Square();
   }
  
   // Call back when the surface is first created or re-created.
   @Override
   public void onSurfaceCreated(GL10 gl, EGLConfig config) {
      // NO CHANGE - SKIP
      ......
   }
   
   // Call back after onSurfaceCreated() or whenever the window's size changes.
   @Override
   public void onSurfaceChanged(GL10 gl, int width, int height) {
      // NO CHANGE - SKIP
      ......
   }
  
   // Call back to draw the current frame.
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers using clear-values set earlier
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);
    
      gl.glLoadIdentity();                 // Reset model-view matrix
      gl.glTranslatef(-1.5f, 0.0f, -6.0f); // Translate left and into the screen
      gl.glRotatef(angleTriangle, 0.0f, 1.0f, 0.0f); // Rotate the triangle about the y-axis (NEW)
      triangle.draw(gl);                   // Draw triangle
   
      gl.glLoadIdentity();                 // Reset the mode-view matrix (NEW)
      gl.glTranslatef(1.5f, 0.0f, -6.0f);  // Translate right and into the screen (NEW)
      gl.glRotatef(angleQuad, 1.0f, 0.0f, 0.0f); // Rotate the square about the x-axis (NEW)
      quad.draw(gl);                       // Draw quad

      // Update the rotational angle after each refresh (NEW)
      angleTriangle += speedTriangle; // (NEW)
      angleQuad += speedQuad;         // (NEW)
   }
}

A glRotate* command was added to rotate the shape, with angle of rotation updated after each refresh.

Example 5: 3D Shapes - Rotating Color Cube and Pyramid (Nehe Lesson 5: 3D Shapes)

Pyramid.java

Set up the color pyramid as follows:

package com.test;
  
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
  
public class Pyramid {
   private FloatBuffer vertexBuffer;  // Buffer for vertex-array
   private FloatBuffer colorBuffer;   // Buffer for color-array
   private ByteBuffer indexBuffer;    // Buffer for index-array
    
   private float[] vertices = { // 5 vertices of the pyramid in (x,y,z)
      -1.0f, -1.0f, -1.0f,  // 0. left-bottom-back
       1.0f, -1.0f, -1.0f,  // 1. right-bottom-back
       1.0f, -1.0f,  1.0f,  // 2. right-bottom-front
      -1.0f, -1.0f,  1.0f,  // 3. left-bottom-front
       0.0f,  1.0f,  0.0f   // 4. top
   };
          
   private float[] colors = {  // Colors of the 5 vertices in RGBA
      0.0f, 0.0f, 1.0f, 1.0f,  // 0. blue
      0.0f, 1.0f, 0.0f, 1.0f,  // 1. green
      0.0f, 0.0f, 1.0f, 1.0f,  // 2. blue
      0.0f, 1.0f, 0.0f, 1.0f,  // 3. green
      1.0f, 0.0f, 0.0f, 1.0f   // 4. red
   };
  
   private byte[] indices = { // Vertex indices of the 4 Triangles
      2, 4, 3,   // front face (CCW)
      1, 4, 2,   // right face
      0, 4, 1,   // back face
      4, 0, 3    // left face
   };
  
   // Constructor - Set up the buffers
   public Pyramid() {
      // Setup vertex-array buffer. Vertices in float. An float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert from byte to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
  
      // Setup color-array buffer. Colors in float. An float has 4 bytes
      ByteBuffer cbb = ByteBuffer.allocateDirect(colors.length * 4);
      cbb.order(ByteOrder.nativeOrder());
      colorBuffer = cbb.asFloatBuffer();
      colorBuffer.put(colors);
      colorBuffer.position(0);
  
      // Setup index-array buffer. Indices in byte.
      indexBuffer = ByteBuffer.allocateDirect(indices.length);
      indexBuffer.put(indices);
      indexBuffer.position(0);
   }
  
   // Draw the shape
   public void draw(GL10 gl) {
      gl.glFrontFace(GL10.GL_CCW);  // Front face in counter-clockwise orientation
  
      // Enable arrays and define their buffers
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
      gl.glEnableClientState(GL10.GL_COLOR_ARRAY);
      gl.glColorPointer(4, GL10.GL_FLOAT, 0, colorBuffer);
      
      gl.glDrawElements(GL10.GL_TRIANGLES, indices.length, GL10.GL_UNSIGNED_BYTE,
            indexBuffer);
      
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glDisableClientState(GL10.GL_COLOR_ARRAY);
   }
}
Cube.java

Similarly, set up the color cube as follows:

package com.test;
  
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
  
public class Cube {
   private FloatBuffer vertexBuffer;  // Buffer for vertex-array
   private int numFaces = 6;
   
   private float[][] colors = {  // Colors of the 6 faces
      {1.0f, 0.5f, 0.0f, 1.0f},  // 0. orange
      {1.0f, 0.0f, 1.0f, 1.0f},  // 1. violet
      {0.0f, 1.0f, 0.0f, 1.0f},  // 2. green
      {0.0f, 0.0f, 1.0f, 1.0f},  // 3. blue
      {1.0f, 0.0f, 0.0f, 1.0f},  // 4. red
      {1.0f, 1.0f, 0.0f, 1.0f}   // 5. yellow
   };
  
   private float[] vertices = {  // Vertices of the 6 faces
      // FRONT
      -1.0f, -1.0f,  1.0f,  // 0. left-bottom-front
       1.0f, -1.0f,  1.0f,  // 1. right-bottom-front
      -1.0f,  1.0f,  1.0f,  // 2. left-top-front
       1.0f,  1.0f,  1.0f,  // 3. right-top-front
      // BACK
       1.0f, -1.0f, -1.0f,  // 6. right-bottom-back
      -1.0f, -1.0f, -1.0f,  // 4. left-bottom-back
       1.0f,  1.0f, -1.0f,  // 7. right-top-back
      -1.0f,  1.0f, -1.0f,  // 5. left-top-back
      // LEFT
      -1.0f, -1.0f, -1.0f,  // 4. left-bottom-back
      -1.0f, -1.0f,  1.0f,  // 0. left-bottom-front 
      -1.0f,  1.0f, -1.0f,  // 5. left-top-back
      -1.0f,  1.0f,  1.0f,  // 2. left-top-front
      // RIGHT
       1.0f, -1.0f,  1.0f,  // 1. right-bottom-front
       1.0f, -1.0f, -1.0f,  // 6. right-bottom-back
       1.0f,  1.0f,  1.0f,  // 3. right-top-front
       1.0f,  1.0f, -1.0f,  // 7. right-top-back
      // TOP
      -1.0f,  1.0f,  1.0f,  // 2. left-top-front
       1.0f,  1.0f,  1.0f,  // 3. right-top-front
      -1.0f,  1.0f, -1.0f,  // 5. left-top-back
       1.0f,  1.0f, -1.0f,  // 7. right-top-back
      // BOTTOM
      -1.0f, -1.0f, -1.0f,  // 4. left-bottom-back
       1.0f, -1.0f, -1.0f,  // 6. right-bottom-back
      -1.0f, -1.0f,  1.0f,  // 0. left-bottom-front
       1.0f, -1.0f,  1.0f   // 1. right-bottom-front
   };
        
   // Constructor - Set up the buffers
   public Cube() {
      // Setup vertex-array buffer. Vertices in float. An float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert from byte to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
   }
  
   // Draw the shape
   public void draw(GL10 gl) {
      gl.glFrontFace(GL10.GL_CCW);    // Front face in counter-clockwise orientation
      gl.glEnable(GL10.GL_CULL_FACE); // Enable cull face
      gl.glCullFace(GL10.GL_BACK);    // Cull the back face (don't display)
  
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);

      // Render all the faces
      for (int face = 0; face < numFaces; face++) {
         // Set the color for each of the faces
         gl.glColor4f(colors[face][0], colors[face][1], colors[face][2], colors[face][3]);
         // Draw the primitive from the vertex-array directly
         gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, face*4, 4);
      }
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glDisable(GL10.GL_CULL_FACE);
   }
}

The vertices of the color cube is labeled as follows.

The vertices of all the faces are arranged in counter-clockwise orientation with normal pointing outwards in a consistent manner. This enables us to cull the back face with the following codes:

gl.glFrontFace(GL10.GL_CCW);    // Set the front face
gl.glEnable(GL10.GL_CULL_FACE); // Enable cull face
gl.glCullFace(GL10.GL_BACK);    // Cull the back face
GL Renderer

The renderer is as follows:

package com.test;
  
import javax.microedition.khronos.egl.EGLConfig;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.opengl.GLU;
  
public class MyGLRenderer implements GLSurfaceView.Renderer {
   
   private Pyramid pyramid;    // (NEW)
   private Cube cube;          // (NEW)
   
   private static float anglePyramid = 0; // Rotational angle in degree for pyramid (NEW)
   private static float angleCube = 0;    // Rotational angle in degree for cube (NEW)
   private static float speedPyramid = 2.0f; // Rotational speed for pyramid (NEW)
   private static float speedCube = -1.5f;   // Rotational speed for cube (NEW)
   
   // Constructor
   public MyGLRenderer(Context context) {
      // Set up the buffers for these shapes
      pyramid = new Pyramid();   // (NEW)
      cube = new Cube();         // (NEW)
   }
  
   // Call back when the surface is first created or re-created.
   @Override
   public void onSurfaceCreated(GL10 gl, EGLConfig config) {
      // NO CHANGE - SKIP
      ......
   }
   
   // Call back after onSurfaceCreated() or whenever the window's size changes.
   @Override
   public void onSurfaceChanged(GL10 gl, int width, int height) {
      // NO CHANGE - SKIP
      ......
   }
  
   // Call back to draw the current frame.
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);
    
      // ----- Render the Pyramid -----
      gl.glLoadIdentity();                 // Reset the model-view matrix
      gl.glTranslatef(-1.5f, 0.0f, -6.0f); // Translate left and into the screen
      gl.glRotatef(anglePyramid, 0.1f, 1.0f, -0.1f); // Rotate (NEW)
      pyramid.draw(gl);                              // Draw the pyramid (NEW)
    
      // ----- Render the Color Cube -----
      gl.glLoadIdentity();                // Reset the model-view matrix
      gl.glTranslatef(1.5f, 0.0f, -6.0f); // Translate right and into the screen
      gl.glScalef(0.8f, 0.8f, 0.8f);      // Scale down (NEW)
      gl.glRotatef(angleCube, 1.0f, 1.0f, 1.0f); // rotate about the axis (1,1,1) (NEW)
      cube.draw(gl);                      // Draw the cube (NEW)
      
      // Update the rotational angle after each refresh (NEW)
      anglePyramid += speedPyramid;   // (NEW)
      angleCube += speedCube;         // (NEW)
   }
}
Cube

There are many ways to render a cube. You could define all the vertices of the 6 faces as in the above example. You could also define one representative face, and render the face 6 times with proper translation and rotation.

Example 1: Cube1.java

package com.test;
  
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
/*
 * Define the vertices for only one face (the front face).
 * Render the cube by translating and rotating the face.
 */
public class Cube1 {
   private FloatBuffer vertexBuffer;  // Buffer for vertex-array
   
   private float[][] colors = {  // Colors of the 6 faces
      {1.0f, 0.5f, 0.0f, 1.0f},  // 0. orange
      {1.0f, 0.0f, 1.0f, 1.0f},  // 1. violet
      {0.0f, 1.0f, 0.0f, 1.0f},  // 2. green
      {0.0f, 0.0f, 1.0f, 1.0f},  // 3. blue
      {1.0f, 0.0f, 0.0f, 1.0f},  // 4. red
      {1.0f, 1.0f, 0.0f, 1.0f}   // 5. yellow
   };
  
   private float[] vertices = {  // Vertices for the front face
      -1.0f, -1.0f, 1.0f,  // 0. left-bottom-front
       1.0f, -1.0f, 1.0f,  // 1. right-bottom-front
      -1.0f,  1.0f, 1.0f,  // 2. left-top-front
       1.0f,  1.0f, 1.0f   // 3. right-top-front
   };
   
   // Constructor - Set up the buffers
   public Cube1() {
      // Setup vertex-array buffer. Vertices in float. An float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert from byte to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
   }
  
   // Draw the color cube
   public void draw(GL10 gl) {
      gl.glFrontFace(GL10.GL_CCW);    // Front face in counter-clockwise orientation
      gl.glEnable(GL10.GL_CULL_FACE); // Enable cull face
      gl.glCullFace(GL10.GL_BACK);    // Cull the back face (don't display)
   
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);

      // Front
      gl.glColor4f(colors[0][0], colors[0][1], colors[0][2], colors[0][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      
      // Right - Rotate 90 degree about y-axis
      gl.glRotatef(90.0f, 0.0f, 1.0f, 0.0f);
      gl.glColor4f(colors[1][0], colors[1][1], colors[1][2], colors[1][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);

      // Back - Rotate another 90 degree about y-axis
      gl.glRotatef(90.0f, 0.0f, 1.0f, 0.0f);
      gl.glColor4f(colors[2][0], colors[2][1], colors[2][2], colors[2][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);

      // Left - Rotate another 90 degree about y-axis
      gl.glRotatef(90.0f, 0.0f, 1.0f, 0.0f);
      gl.glColor4f(colors[3][0], colors[3][1], colors[3][2], colors[3][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);

      // Bottom - Rotate 90 degree about x-axis
      gl.glRotatef(90.0f, 1.0f, 0.0f, 0.0f);
      gl.glColor4f(colors[4][0], colors[4][1], colors[4][2], colors[4][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      
      // Top - Rotate another 180 degree about x-axis
      gl.glRotatef(180.0f, 1.0f, 0.0f, 0.0f);
      gl.glColor4f(colors[5][0], colors[5][1], colors[5][2], colors[5][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);

      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glDisable(GL10.GL_CULL_FACE);
   }
}

Example 2: Cube2.java

package com.test;
  
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
/*
 * Define the vertices for a representative face.
 * Render the cube by translating and rotating the face.
 */
public class Cube2 {
   private FloatBuffer vertexBuffer; // Buffer for vertex-array
  
   private float[] vertices = { // Vertices for a face at z=0
      -1.0f, -1.0f, 0.0f,  // 0. left-bottom-front
       1.0f, -1.0f, 0.0f,  // 1. right-bottom-front
      -1.0f,  1.0f, 0.0f,  // 2. left-top-front
       1.0f,  1.0f, 0.0f   // 3. right-top-front
   };
  
   private float[][] colors = {  // Colors of the 6 faces
      {1.0f, 0.5f, 0.0f, 1.0f},  // 0. orange
      {1.0f, 0.0f, 1.0f, 1.0f},  // 1. violet
      {0.0f, 1.0f, 0.0f, 1.0f},  // 2. green
      {0.0f, 0.0f, 1.0f, 1.0f},  // 3. blue
      {1.0f, 0.0f, 0.0f, 1.0f},  // 4. red
      {1.0f, 1.0f, 0.0f, 1.0f}   // 5. yellow
   };
  
   // Constructor - Set up the buffers
   public Cube2() {
      // Setup vertex-array buffer. Vertices in float. An float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert from byte to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
   }
   
   // Draw the shape
   public void draw(GL10 gl) {
      gl.glFrontFace(GL10.GL_CCW);    // Front face in counter-clockwise orientation
      gl.glEnable(GL10.GL_CULL_FACE); // Enable cull face
      gl.glCullFace(GL10.GL_BACK);    // Cull the back face (don't display)
  
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
      
      // front
      gl.glPushMatrix();
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glColor4f(colors[0][0], colors[0][1], colors[0][2], colors[0][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // left
      gl.glPushMatrix();
      gl.glRotatef(270.0f, 0.0f, 1.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glColor4f(colors[1][0], colors[1][1], colors[1][2], colors[1][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // back
      gl.glPushMatrix();
      gl.glRotatef(180.0f, 0.0f, 1.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glColor4f(colors[2][0], colors[2][1], colors[2][2], colors[2][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // right
      gl.glPushMatrix();
      gl.glRotatef(90.0f, 0.0f, 1.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glColor4f(colors[3][0], colors[3][1], colors[3][2], colors[3][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
 
      // top
      gl.glPushMatrix();
      gl.glRotatef(270.0f, 1.0f, 0.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glColor4f(colors[4][0], colors[4][1], colors[4][2], colors[4][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
 
      // bottom
      gl.glPushMatrix();
      gl.glRotatef(90.0f, 1.0f, 0.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glColor4f(colors[5][0], colors[5][1], colors[5][2], colors[5][3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glDisable(GL10.GL_CULL_FACE);
   }
}

Example 6: Texture (Nehe Lesson 6: Texture)

Let's convert our color-cube into a texture-cube.

TextureCube.java

Let's modify our earlier Cube2.java to set up the texture array.

package com.test;
   
import java.io.IOException;
import java.io.InputStream;
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.graphics.Bitmap;
import android.graphics.BitmapFactory;
import android.opengl.GLUtils;
/*
 * A cube with texture. 
 * Define the vertices for only one representative face.
 * Render the cube by translating and rotating the face.
 */
public class TextureCube {
   private FloatBuffer vertexBuffer; // Buffer for vertex-array
   private FloatBuffer texBuffer;    // Buffer for texture-coords-array (NEW)
  
   private float[] vertices = { // Vertices for a face
      -1.0f, -1.0f, 0.0f,  // 0. left-bottom-front
       1.0f, -1.0f, 0.0f,  // 1. right-bottom-front
      -1.0f,  1.0f, 0.0f,  // 2. left-top-front
       1.0f,  1.0f, 0.0f   // 3. right-top-front
   };
  
   float[] texCoords = { // Texture coords for the above face (NEW)
      0.0f, 1.0f,  // A. left-bottom (NEW)
      1.0f, 1.0f,  // B. right-bottom (NEW)
      0.0f, 0.0f,  // C. left-top (NEW)
      1.0f, 0.0f   // D. right-top (NEW)
   };
   int[] textureIDs = new int[1];   // Array for 1 texture-ID (NEW)
     
   // Constructor - Set up the buffers
   public TextureCube() {
      // Setup vertex-array buffer. Vertices in float. An float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert from byte to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
  
      // Setup texture-coords-array buffer, in float. An float has 4 bytes (NEW)
      ByteBuffer tbb = ByteBuffer.allocateDirect(texCoords.length * 4);
      tbb.order(ByteOrder.nativeOrder());
      texBuffer = tbb.asFloatBuffer();
      texBuffer.put(texCoords);
      texBuffer.position(0);
   }
   
   // Draw the shape
   public void draw(GL10 gl) {
      gl.glFrontFace(GL10.GL_CCW);    // Front face in counter-clockwise orientation
      gl.glEnable(GL10.GL_CULL_FACE); // Enable cull face
      gl.glCullFace(GL10.GL_BACK);    // Cull the back face (don't display) 
   
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
      gl.glEnableClientState(GL10.GL_TEXTURE_COORD_ARRAY);  // Enable texture-coords-array (NEW)
      gl.glTexCoordPointer(2, GL10.GL_FLOAT, 0, texBuffer); // Define texture-coords buffer (NEW)
      
      // front
      gl.glPushMatrix();
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // left
      gl.glPushMatrix();
      gl.glRotatef(270.0f, 0.0f, 1.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // back
      gl.glPushMatrix();
      gl.glRotatef(180.0f, 0.0f, 1.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // right
      gl.glPushMatrix();
      gl.glRotatef(90.0f, 0.0f, 1.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // top
      gl.glPushMatrix();
      gl.glRotatef(270.0f, 1.0f, 0.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // bottom
      gl.glPushMatrix();
      gl.glRotatef(90.0f, 1.0f, 0.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      gl.glDisableClientState(GL10.GL_TEXTURE_COORD_ARRAY);  // Disable texture-coords-array (NEW)
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glDisable(GL10.GL_CULL_FACE);
   }
  
   // Load an image into GL texture
   public void loadTexture(GL10 gl, Context context) {
      gl.glGenTextures(1, textureIDs, 0); // Generate texture-ID array

      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[0]);   // Bind to texture ID
      // Set up texture filters
      gl.glTexParameterf(GL10.GL_TEXTURE_2D, GL10.GL_TEXTURE_MIN_FILTER, GL10.GL_NEAREST);
      gl.glTexParameterf(GL10.GL_TEXTURE_2D, GL10.GL_TEXTURE_MAG_FILTER, GL10.GL_LINEAR);
  
      // Construct an input stream to texture image "res\drawable\nehe.png"
      InputStream istream = context.getResources().openRawResource(R.drawable.nehe);
      Bitmap bitmap;
      try {
         // Read and decode input as bitmap
         bitmap = BitmapFactory.decodeStream(istream);
      } finally {
         try {
            istream.close();
         } catch(IOException e) { }
      }
  
      // Build Texture from loaded bitmap for the currently-bind texture ID
      GLUtils.texImage2D(GL10.GL_TEXTURE_2D, 0, bitmap, 0);
      bitmap.recycle();
   }
}
Dissecting TextureCube.java

The vertices of all the 6 faces are arranged in a consistent manner (inverted-Z). Hence, we can use the same texture coordinates for all 6 face. We define the texture coords once, and put into the texture buffer 6 times. Take note that texture coordinates' origin is at the top-left corner. The coordinates are normalized to [0, 1].

private FloatBuffer texBuffer;     // Texture Coords Buffer
......
float[] texCoords = {  // Define the texture coord, applicable to all 6 faces
   // FRONT
   0.0f, 1.0f,  // A. left-bottom
   1.0f, 1.0f,  // B. right-bottom
   0.0f, 0.0f,  // C. left-top
   1.0f, 0.0f   // D. right-top
};
   
// Allocate texture buffer
ByteBuffer tbb = ByteBuffer.allocateDirect(texCoords.length * 4 * 6);
tbb.order(ByteOrder.nativeOrder());
texBuffer = tbb.asFloatBuffer();
// All the 6 faces have the same texture coords, repeat 6 times
for (int face = 0; face < 6; face++) {
   texBuffer.put(texCoords);
}
texBuffer.position(0);     // Rewind

To render the texture, we simply enable client-state texture-coords-array (together with vertex-array). The vertices and texture-coords will be rendered together.

gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
gl.glEnableClientState(GL10.GL_TEXTURE_COORD_ARRAY);
gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
gl.glTexCoordPointer(2, GL10.GL_FLOAT, 0, texBuffer);
   
for (int face = 0; face < 6; face++) {
// Render each face in TRIANGLE_STRIP using 4 vertices
   gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, face*4, 4);
}

We store the texture image "nehe.png" into folder "res\drawable".

The following steps are needed to setup texture and load an image:

  1. [TODO]

Take note that we have removed all the color information.

GL Renderer

We need to modify our renderer to setup texture as follows:

package com.test;
  
import javax.microedition.khronos.egl.EGLConfig;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.opengl.GLU;

public class MyGLRenderer implements GLSurfaceView.Renderer {
   
   private Context context;   // Application context needed to read image (NEW)
   private TextureCube cube;
   private static float angleCube = 0;     // rotational angle in degree for cube
   private static float speedCube = -1.5f; // rotational speed for cube
   
   // Constructor
   public MyGLRenderer(Context context) {
      this.context = context;   // Get the application context (NEW)
      cube = new TextureCube();
   }
  
   // Call back when the surface is first created or re-created.
   @Override
   public void onSurfaceCreated(GL10 gl, EGLConfig config) {
      gl.glClearColor(0.0f, 0.0f, 0.0f, 1.0f);  // Set color's clear-value to black
      gl.glClearDepthf(1.0f);            // Set depth's clear-value to farthest
      gl.glEnable(GL10.GL_DEPTH_TEST);   // Enables depth-buffer for hidden surface removal
      gl.glDepthFunc(GL10.GL_LEQUAL);    // The type of depth testing to do
      gl.glHint(GL10.GL_PERSPECTIVE_CORRECTION_HINT, GL10.GL_NICEST);  // nice perspective view
      gl.glShadeModel(GL10.GL_SMOOTH);   // Enable smooth shading of color
      gl.glDisable(GL10.GL_DITHER);      // Disable dithering for better performance
  
      // Setup Texture, each time the surface is created (NEW)
      cube.loadTexture(gl, context);    // Load image into Texture (NEW)
      gl.glEnable(GL10.GL_TEXTURE_2D);  // Enable texture (NEW)
   }
   
   // Call back after onSurfaceCreated() or whenever the window's size changes.
   @Override
   public void onSurfaceChanged(GL10 gl, int width, int height) {
      // NO CHANGE - SKIP
      .......
   }
  
   // Call back to draw the current frame.
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);
      
      // ----- Render the Cube -----
      gl.glLoadIdentity();                  // Reset the current model-view matrix
      gl.glTranslatef(0.0f, 0.0f, -6.0f);   // Translate into the screen
      gl.glRotatef(angleCube, 0.1f, 1.0f, 0.2f); // Rotate
      cube.draw(gl);
      
      // Update the rotational angle after each refresh.
      angleCube += speedCube;
   }
}

Example 6a: Photo-Cube

Let's convert the texture cube into photo cube with different images for each of the 6 faces.

PhotoCube.java
package com.test;
  
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.graphics.Bitmap;
import android.graphics.BitmapFactory;
import android.opengl.GLUtils;
/*
 * A photo cube with 6 pictures (textures) on its 6 faces.
 */
public class PhotoCube {
   private FloatBuffer vertexBuffer;  // Vertex Buffer
   private FloatBuffer texBuffer;     // Texture Coords Buffer
   
   private int numFaces = 6;
   private int[] imageFileIDs = {  // Image file IDs
      R.drawable.caldera,
      R.drawable.candice,
      R.drawable.mule,
      R.drawable.glass,
      R.drawable.leonardo,
      R.drawable.tmsk
   };
   private int[] textureIDs = new int[numFaces];
   private Bitmap[] bitmap = new Bitmap[numFaces];
   private float cubeHalfSize = 1.2f;
        
   // Constructor - Set up the vertex buffer
   public PhotoCube(Context context) {
      // Allocate vertex buffer. An float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(12 * 4 * numFaces);
      vbb.order(ByteOrder.nativeOrder());
      vertexBuffer = vbb.asFloatBuffer();
  
      // Read images. Find the aspect ratio and adjust the vertices accordingly.
      for (int face = 0; face < numFaces; face++) {
         bitmap[face] = BitmapFactory.decodeStream(
               context.getResources().openRawResource(imageFileIDs[face]));
         int imgWidth = bitmap[face].getWidth();
         int imgHeight = bitmap[face].getHeight();
         float faceWidth = 2.0f;
         float faceHeight = 2.0f;
         // Adjust for aspect ratio
         if (imgWidth > imgHeight) {
            faceHeight = faceHeight * imgHeight / imgWidth; 
         } else {
            faceWidth = faceWidth * imgWidth / imgHeight;
         }
         float faceLeft = -faceWidth / 2;
         float faceRight = -faceLeft;
         float faceTop = faceHeight / 2;
         float faceBottom = -faceTop;
         
         // Define the vertices for this face
         float[] vertices = {
            faceLeft,  faceBottom, 0.0f,  // 0. left-bottom-front
            faceRight, faceBottom, 0.0f,  // 1. right-bottom-front
            faceLeft,  faceTop,    0.0f,  // 2. left-top-front
            faceRight, faceTop,    0.0f,  // 3. right-top-front
         };
         vertexBuffer.put(vertices);  // Populate
      }
      vertexBuffer.position(0);    // Rewind
  
      // Allocate texture buffer. An float has 4 bytes. Repeat for 6 faces.
      float[] texCoords = {
         0.0f, 1.0f,  // A. left-bottom
         1.0f, 1.0f,  // B. right-bottom
         0.0f, 0.0f,  // C. left-top
         1.0f, 0.0f   // D. right-top
      };
      ByteBuffer tbb = ByteBuffer.allocateDirect(texCoords.length * 4 * numFaces);
      tbb.order(ByteOrder.nativeOrder());
      texBuffer = tbb.asFloatBuffer();
      for (int face = 0; face < numFaces; face++) {
         texBuffer.put(texCoords);
      }
      texBuffer.position(0);   // Rewind
   }
   
   // Render the shape
   public void draw(GL10 gl) {
      gl.glFrontFace(GL10.GL_CCW);
      
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glEnableClientState(GL10.GL_TEXTURE_COORD_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
      gl.glTexCoordPointer(2, GL10.GL_FLOAT, 0, texBuffer);
  
      // front
      gl.glPushMatrix();
      gl.glTranslatef(0f, 0f, cubeHalfSize);
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[0]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // left
      gl.glPushMatrix();
      gl.glRotatef(270.0f, 0f, 1f, 0f);
      gl.glTranslatef(0f, 0f, cubeHalfSize);
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[1]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 4, 4);
      gl.glPopMatrix();
  
      // back
      gl.glPushMatrix();
      gl.glRotatef(180.0f, 0f, 1f, 0f);
      gl.glTranslatef(0f, 0f, cubeHalfSize);
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[2]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 8, 4);
      gl.glPopMatrix();
  
      // right
      gl.glPushMatrix();
      gl.glRotatef(90.0f, 0f, 1f, 0f);
      gl.glTranslatef(0f, 0f, cubeHalfSize);
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[3]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 12, 4);
      gl.glPopMatrix();
  
      // top
      gl.glPushMatrix();
      gl.glRotatef(270.0f, 1f, 0f, 0f);
      gl.glTranslatef(0f, 0f, cubeHalfSize);
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[4]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 16, 4);
      gl.glPopMatrix();
  
      // bottom
      gl.glPushMatrix();
      gl.glRotatef(90.0f, 1f, 0f, 0f);
      gl.glTranslatef(0f, 0f, cubeHalfSize);
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[5]);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 20, 4);
      gl.glPopMatrix();
   
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glDisableClientState(GL10.GL_TEXTURE_COORD_ARRAY);
   }
  
   // Load images into 6 GL textures
   public void loadTexture(GL10 gl) {
      gl.glGenTextures(6, textureIDs, 0); // Generate texture-ID array for 6 IDs
  
      // Generate OpenGL texture images
      for (int face = 0; face < numFaces; face++) {
         gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[face]);
         // Build Texture from loaded bitmap for the currently-bind texture ID
         GLUtils.texImage2D(GL10.GL_TEXTURE_2D, 0, bitmap[face], 0);
         bitmap[face].recycle();
      }
   }
}
MyGLRenderer.java
package com.test;
   
import javax.microedition.khronos.egl.EGLConfig;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.opengl.GLU;
   
public class MyGLRenderer implements GLSurfaceView.Renderer {
   private PhotoCube cube;     // (NEW)
   private static float angleCube = 0;     // rotational angle in degree for cube
   private static float speedCube = -1.5f; // rotational speed for cube
   
   // Constructor
   public MyGLRenderer(Context context) {
      cube = new PhotoCube(context);    // (NEW)
   }
   
   // Call back when the surface is first created or re-created.
   @Override
   public void onSurfaceCreated(GL10 gl, EGLConfig config) {
      gl.glClearColor(0.0f, 0.0f, 0.0f, 1.0f);  // Set color's clear-value to black
      gl.glClearDepthf(1.0f);            // Set depth's clear-value to farthest
      gl.glEnable(GL10.GL_DEPTH_TEST);   // Enables depth-buffer for hidden surface removal
      gl.glDepthFunc(GL10.GL_LEQUAL);    // The type of depth testing to do
      gl.glHint(GL10.GL_PERSPECTIVE_CORRECTION_HINT, GL10.GL_NICEST);  // nice perspective view
      gl.glShadeModel(GL10.GL_SMOOTH);   // Enable smooth shading of color
      gl.glDisable(GL10.GL_DITHER);      // Disable dithering for better performance
    
      // Setup Texture, each time the surface is created (NEW)
      cube.loadTexture(gl);             // Load images into textures (NEW)
      gl.glEnable(GL10.GL_TEXTURE_2D);  // Enable texture (NEW)
   }
  
   // Call back after onSurfaceCreated() or whenever the window's size changes.
   @Override
   public void onSurfaceChanged(GL10 gl, int width, int height) {
      // NO CHANGE - SKIP
      ......
   }
  
   // Call back to draw the current frame.
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);
  
      // ----- Render the Cube -----
      gl.glLoadIdentity();                  // Reset the model-view matrix
      gl.glTranslatef(0.0f, 0.0f, -6.0f);   // Translate into the screen
      gl.glRotatef(angleCube, 0.15f, 1.0f, 0.3f); // Rotate
      cube.draw(gl);
      
      // Update the rotational angle after each refresh.
      angleCube += speedCube;
   }
}

Example 7a: User Inputs (Nehe Lesson 7 Part 1: Key-Controlled)

Nehe lesson 7 is far too complex, I shall break it into 3 parts: Key-controlled, Texture Filters, and Lighting.

TextureCube.java

No change, except using image "crate.png".

MyGLRenderer.java

We modify our renderer by adding variables and transformation methods to control the cube z-position, x and y rotational angles and speeds.

package com.test;
   
import javax.microedition.khronos.egl.EGLConfig;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.opengl.GLU;
   
public class MyGLRenderer implements GLSurfaceView.Renderer {
    
   private Context context;
   private TextureCube cube;
   // For controlling cube's z-position, x and y angles and speeds (NEW)
   float angleX = 0;   // (NEW)
   float angleY = 0;   // (NEW)
   float speedX = 0;   // (NEW)
   float speedY = 0;   // (NEW)
   float z = -6.0f;    // (NEW)
   
   // Constructor
   public MyGLRenderer(Context context) {
      this.context = context;
      cube = new TextureCube();
   }
  
   // Call back when the surface is first created or re-created.
   @Override
   public void onSurfaceCreated(GL10 gl, EGLConfig config) {
      gl.glClearColor(0.0f, 0.0f, 0.0f, 1.0f);  // Set color's clear-value to black
      gl.glClearDepthf(1.0f);            // Set depth's clear-value to farthest
      gl.glEnable(GL10.GL_DEPTH_TEST);   // Enables depth-buffer for hidden surface removal
      gl.glDepthFunc(GL10.GL_LEQUAL);    // The type of depth testing to do
      gl.glHint(GL10.GL_PERSPECTIVE_CORRECTION_HINT, GL10.GL_NICEST);  // nice perspective view
      gl.glShadeModel(GL10.GL_SMOOTH);   // Enable smooth shading of color
      gl.glDisable(GL10.GL_DITHER);      // Disable dithering for better performance
  
      // Setup Texture, each time the surface is created
      cube.loadTexture(gl, context);    // Load image into Texture
      gl.glEnable(GL10.GL_TEXTURE_2D);  // Enable texture
   }
   
   // Call back after onSurfaceCreated() or whenever the window's size changes.
   @Override
   public void onSurfaceChanged(GL10 gl, int width, int height) {
      // NO CHANGE - SKIP
      ......
   }
  
   // Call back to draw the current frame.
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);

      // ----- Render the Cube -----
      gl.glLoadIdentity();              // Reset the model-view matrix
      gl.glTranslatef(0.0f, 0.0f, z);   // Translate into the screen (NEW)
      gl.glRotatef(angleX, 1.0f, 0.0f, 0.0f); // Rotate (NEW)
      gl.glRotatef(angleY, 0.0f, 1.0f, 0.0f); // Rotate (NEW)
      cube.draw(gl);
      
      // Update the rotational angle after each refresh (NEW)
      angleX += speedX;  // (NEW)
      angleY += speedY;  // (NEW)
   }
}
MyGLSurfaceView.java

In order to capture the user inputs, we need to customize the GLSurfaceView by extending a subclass, so as to override the event handlers (such as onKeyUp(), onTouchEvent()).

package com.test;
   
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.view.KeyEvent;
import android.view.MotionEvent;
/*
 * Custom GL view by extending GLSurfaceView so as
 * to override event handlers such as onKeyUp(), onTouchEvent()
 */
public class MyGLSurfaceView extends GLSurfaceView {
   MyGLRenderer renderer;    // Custom GL Renderer
   
   // For touch event
   private final float TOUCH_SCALE_FACTOR = 180.0f / 320.0f;
   private float previousX;
   private float previousY;

   // Constructor - Allocate and set the renderer
   public MyGLSurfaceView(Context context) {
      super(context);
      renderer = new MyGLRenderer(context);
      this.setRenderer(renderer);
      // Request focus, otherwise key/button won't react
      this.requestFocus();  
      this.setFocusableInTouchMode(true);
   }
   
   // Handler for key event
   @Override
   public boolean onKeyUp(int keyCode, KeyEvent evt) {
      switch(keyCode) {
         case KeyEvent.KEYCODE_DPAD_LEFT:   // Decrease Y-rotational speed
            renderer.speedY -= 0.1f;
            break;
         case KeyEvent.KEYCODE_DPAD_RIGHT:  // Increase Y-rotational speed
            renderer.speedY += 0.1f;
            break;
         case KeyEvent.KEYCODE_DPAD_UP:     // Decrease X-rotational speed
            renderer.speedX -= 0.1f;
            break;
         case KeyEvent.KEYCODE_DPAD_DOWN:   // Increase X-rotational speed 
            renderer.speedX += 0.1f;
            break;
         case KeyEvent.KEYCODE_A:           // Zoom out (decrease z)
            renderer.z -= 0.2f;
            break;
         case KeyEvent.KEYCODE_Z:           // Zoom in (increase z)
            renderer.z += 0.2f;
            break;
      }
      return true;  // Event handled
   }

   // Handler for touch event
   @Override
   public boolean onTouchEvent(final MotionEvent evt) {
      float currentX = evt.getX();
      float currentY = evt.getY();
      float deltaX, deltaY;
      switch (evt.getAction()) {
         case MotionEvent.ACTION_MOVE:
            // Modify rotational angles according to movement
            deltaX = currentX - previousX;
            deltaY = currentY - previousY;
            renderer.angleX += deltaY * TOUCH_SCALE_FACTOR;
            renderer.angleY += deltaX * TOUCH_SCALE_FACTOR;
      }
      // Save current x, y
      previousX = currentX;
      previousY = currentY;
      return true;  // Event handled
   }
}

Clearly, we use key 'A' and 'Z' for zoom out and zoom in. Touch events for modifying x and y rotational angles. Left, right, up and down buttons to control the x and y rotational speeds.

MyGLActivity.java

We need to modify our GL Activity to use the custom GL View.

package com.test;
  
import android.app.Activity;
import android.opengl.GLSurfaceView;
import android.os.Bundle;
/*
 * OpenGL Main Activity.
 */
public class MyGLActivity extends Activity {
   private GLSurfaceView glView;  // Use subclass of GLSurfaceView (NEW)
   
   @Override
   protected void onCreate(Bundle savedInstanceState) {
      super.onCreate(savedInstanceState);
      // Allocate a custom subclass of GLSurfaceView (NEW)
      glView = new MyGLSurfaceView(this);
      setContentView(glView);  // Set View (NEW)
   }
   
   @Override
   protected void onPause() {
      super.onPause();
      glView.onPause();
   }
   
   @Override
   protected void onResume() {
      super.onResume();
      glView.onResume();
   }
}

You can, similarly, capture and process other events. [MORE]

Example 7b: Texture Filters (Nehe Lesson 7 Part 2: Texture Filter)

TextureCube.java
package com.test;

import java.io.IOException;
import java.io.InputStream;
import java.nio.ByteBuffer;
import java.nio.ByteOrder;
import java.nio.FloatBuffer;
import javax.microedition.khronos.opengles.GL10;
import javax.microedition.khronos.opengles.GL11;
import android.content.Context;
import android.graphics.Bitmap;
import android.graphics.BitmapFactory;
import android.opengl.GLUtils;
/*
 * A cube with texture.
 * Three texture filters are to be set up. 
 */
public class TextureCube {
   private FloatBuffer vertexBuffer; // Buffer for vertex-array
   private FloatBuffer texBuffer;    // Buffer for texture-coords-array
  
   private float[] vertices = { // Vertices for a face
      -1.0f, -1.0f, 0.0f,  // 0. left-bottom-front
       1.0f, -1.0f, 0.0f,  // 1. right-bottom-front
      -1.0f,  1.0f, 0.0f,  // 2. left-top-front
       1.0f,  1.0f, 0.0f   // 3. right-top-front
   };
  
   float[] texCoords = { // Texture coords for the above face
      0.0f, 1.0f,  // A. left-bottom
      1.0f, 1.0f,  // B. right-bottom
      0.0f, 0.0f,  // C. left-top
      1.0f, 0.0f   // D. right-top
   };
   int[] textureIDs = new int[3];  // Array for 3 texture-IDs (NEW)
     
   // Constructor - Set up the buffers
   public TextureCube() {
      // Setup vertex-array buffer. Vertices in float. An float has 4 bytes
      ByteBuffer vbb = ByteBuffer.allocateDirect(vertices.length * 4);
      vbb.order(ByteOrder.nativeOrder()); // Use native byte order
      vertexBuffer = vbb.asFloatBuffer(); // Convert from byte to float
      vertexBuffer.put(vertices);         // Copy data into buffer
      vertexBuffer.position(0);           // Rewind
  
      // Setup texture-coords-array buffer, in float. An float has 4 bytes
      ByteBuffer tbb = ByteBuffer.allocateDirect(texCoords.length * 4);
      tbb.order(ByteOrder.nativeOrder());
      texBuffer = tbb.asFloatBuffer();
      texBuffer.put(texCoords);
      texBuffer.position(0);
   }
   
   // Draw the shape
   public void draw(GL10 gl, int textureFilter) {  // Select the filter (NEW)
      gl.glFrontFace(GL10.GL_CCW);    // Front face in counter-clockwise orientation
      gl.glEnable(GL10.GL_CULL_FACE); // Enable cull face 
      gl.glCullFace(GL10.GL_BACK);    // Cull the back face (don't display) 
   
      gl.glEnableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glVertexPointer(3, GL10.GL_FLOAT, 0, vertexBuffer);
      gl.glEnableClientState(GL10.GL_TEXTURE_COORD_ARRAY);  // Enable texture-coords-array
      gl.glTexCoordPointer(2, GL10.GL_FLOAT, 0, texBuffer); // Define texture-coords buffer

      // Select the texture filter to use via texture ID (NEW)
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[textureFilter]);
  
      // front
      gl.glPushMatrix();
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // left
      gl.glPushMatrix();
      gl.glRotatef(270.0f, 0.0f, 1.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // back
      gl.glPushMatrix();
      gl.glRotatef(180.0f, 0.0f, 1.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // right
      gl.glPushMatrix();
      gl.glRotatef(90.0f, 0.0f, 1.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // top
      gl.glPushMatrix();
      gl.glRotatef(270.0f, 1.0f, 0.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      // bottom
      gl.glPushMatrix();
      gl.glRotatef(90.0f, 1.0f, 0.0f, 0.0f);
      gl.glTranslatef(0.0f, 0.0f, 1.0f);
      gl.glDrawArrays(GL10.GL_TRIANGLE_STRIP, 0, 4);
      gl.glPopMatrix();
  
      gl.glDisableClientState(GL10.GL_TEXTURE_COORD_ARRAY);
      gl.glDisableClientState(GL10.GL_VERTEX_ARRAY);
      gl.glDisable(GL10.GL_CULL_FACE);
   }
  
   // Load an image and create 3 textures with different filters (NEW)
   public void loadTexture(GL10 gl, Context context) {
      // Construct an input stream to texture image "res\drawable\crate.png"
      InputStream istream = context.getResources().openRawResource(R.drawable.crate);
      Bitmap bitmap;
      try {
         // Read and decode input as bitmap
         bitmap = BitmapFactory.decodeStream(istream);
      } finally {
         try {
            istream.close();
         } catch(IOException e) { }
      }

      gl.glGenTextures(3, textureIDs, 0);  // Generate texture-ID array for 3 textures (NEW)

      // Create Nearest Filtered Texture and bind it to texture 0 (NEW)
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[0]);
      gl.glTexParameterf(GL10.GL_TEXTURE_2D, GL10.GL_TEXTURE_MAG_FILTER, GL10.GL_NEAREST);
      gl.glTexParameterf(GL10.GL_TEXTURE_2D, GL10.GL_TEXTURE_MIN_FILTER, GL10.GL_NEAREST);
      GLUtils.texImage2D(GL10.GL_TEXTURE_2D, 0, bitmap, 0);

      // Create Linear Filtered Texture and bind it to texture 1 (NEW)
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[1]);
      gl.glTexParameterf(GL10.GL_TEXTURE_2D, GL10.GL_TEXTURE_MAG_FILTER, GL10.GL_LINEAR);
      GLUtils.texImage2D(GL10.GL_TEXTURE_2D, 0, bitmap, 0);

      // Create mipmapped textures and bind it to texture 2 (NEW)
      gl.glBindTexture(GL10.GL_TEXTURE_2D, textureIDs[2]);
      gl.glTexParameterf(GL10.GL_TEXTURE_2D, GL10.GL_TEXTURE_MAG_FILTER, GL10.GL_LINEAR);
      gl.glTexParameterf(GL10.GL_TEXTURE_2D, GL10.GL_TEXTURE_MIN_FILTER, GL10.GL_LINEAR_MIPMAP_NEAREST);
      if(gl instanceof GL11) {
         gl.glTexParameterf(GL11.GL_TEXTURE_2D, GL11.GL_GENERATE_MIPMAP, GL11.GL_TRUE);
      }
      GLUtils.texImage2D(GL10.GL_TEXTURE_2D, 0, bitmap, 0);

      bitmap.recycle();
   }
}
Dissecting TextureCube.java

[TODO]

MyGLRenderer.java
......
public class MyGLRenderer implements GLSurfaceView.Renderer {
   ......
   int currentTextureFilter = 0;  // Texture filter (NEW)
   ......
   
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);

      // ----- Render the Cube -----
      gl.glLoadIdentity();              // Reset the current model-view matrix
      gl.glTranslatef(0.0f, 0.0f, z);   // Translate into the screen
      gl.glRotatef(angleX, 1.0f, 0.0f, 0.0f); // Rotate
      gl.glRotatef(angleY, 0.0f, 1.0f, 0.0f); // Rotate
      
      cube.draw(gl, currentTextureFilter);    // (NEW)
      
      // Update the rotational angle after each refresh
      angleX += speedX;
      angleY += speedY;
   }
}
MyGLSurfaceView.java
......
public class MyGLSurfaceView extends GLSurfaceView {
   ......
   // Handler for key event
   @Override
   public boolean onKeyUp(int keyCode, KeyEvent evt) {
      switch(keyCode) {
         ......
         case KeyEvent.KEYCODE_DPAD_CENTER:  // Select texture filter (NEW)
            renderer.currentTextureFilter = (renderer.currentTextureFilter + 1) % 3;
            break;
      }
}

Example 7c: Lighting (Nehe Lesson 7 Part 3: Lighting)

MyGLRenderer.java
package com.test;
  
import javax.microedition.khronos.egl.EGLConfig;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.opengl.GLU;
  
public class MyGLRenderer implements GLSurfaceView.Renderer {
    
   private Context context;
   private TextureCube cube;
   // For controlling cube's z-position, x and y angles and speeds
   float angleX = 0;
   float angleY = 0;
   float speedX = 0;
   float speedY = 0;
   float z = -6.0f;
   
   int currentTextureFilter = 0;  // Texture filter

   // Lighting (NEW)
   boolean lightingEnabled = false;   // Is lighting on? (NEW)
   private float[] lightAmbient = {0.5f, 0.5f, 0.5f, 1.0f};
   private float[] lightDiffuse = {1.0f, 1.0f, 1.0f, 1.0f};
   private float[] lightPosition = {0.0f, 0.0f, 2.0f, 1.0f};
  
   // Constructor
   public MyGLRenderer(Context context) {
      this.context = context;
      cube = new TextureCube();
   }
  
   // Call back when the surface is first created or re-created.
   @Override
   public void onSurfaceCreated(GL10 gl, EGLConfig config) {
      gl.glClearColor(0.0f, 0.0f, 0.0f, 1.0f);  // Set color's clear-value to black
      gl.glClearDepthf(1.0f);            // Set depth's clear-value to farthest
      gl.glEnable(GL10.GL_DEPTH_TEST);   // Enables depth-buffer for hidden surface removal
      gl.glDepthFunc(GL10.GL_LEQUAL);    // The type of depth testing to do
      gl.glHint(GL10.GL_PERSPECTIVE_CORRECTION_HINT, GL10.GL_NICEST);  // nice perspective view
      gl.glShadeModel(GL10.GL_SMOOTH);   // Enable smooth shading of color
      gl.glDisable(GL10.GL_DITHER);      // Disable dithering for better performance

      // Setup Texture, each time the surface is created
      cube.loadTexture(gl, context);    // Load image into Texture
      gl.glEnable(GL10.GL_TEXTURE_2D);  // Enable texture
      
      // Setup lighting GL_LIGHT1 with ambient and diffuse lights (NEW)
      gl.glLightfv(GL10.GL_LIGHT1, GL10.GL_AMBIENT, lightAmbient, 0);
      gl.glLightfv(GL10.GL_LIGHT1, GL10.GL_DIFFUSE, lightDiffuse, 0);
      gl.glLightfv(GL10.GL_LIGHT1, GL10.GL_POSITION, lightPosition, 0);
      gl.glEnable(GL10.GL_LIGHT1);   // Enable Light 1 (NEW)
      gl.glEnable(GL10.GL_LIGHT0);   // Enable the default Light 0 (NEW)
   }
   
   // Call back after onSurfaceCreated() or whenever the window's size changes.
   @Override
   public void onSurfaceChanged(GL10 gl, int width, int height) {
      // NO CHANGE - SKIP
      .......
   }
  
   // Call back to draw the current frame.
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);
  
      // Enable lighting? (NEW)
      if (lightingEnabled) {
         gl.glEnable(GL10.GL_LIGHTING);
      } else {
         gl.glDisable(GL10.GL_LIGHTING);
      }
      
      // ----- Render the Cube -----
      gl.glLoadIdentity();              // Reset the model-view matrix
      gl.glTranslatef(0.0f, 0.0f, z);   // Translate into the screen
      gl.glRotatef(angleX, 1.0f, 0.0f, 0.0f); // Rotate
      gl.glRotatef(angleY, 0.0f, 1.0f, 0.0f); // Rotate
      cube.draw(gl, currentTextureFilter);
      
      // Update the rotational angle after each refresh
      angleX += speedX;
      angleY += speedY;
   }
}
MyGLSurfaceView.java
......
public class MyGLSurfaceView extends GLSurfaceView {
   .......
  
   // Handler for key event
   @Override
   public boolean onKeyUp(int keyCode, KeyEvent evt) {
      switch(keyCode) {
         .......
         case KeyEvent.KEYCODE_L:  // Toggle lighting on/off (NEW) 
            renderer.lightingEnabled = !renderer.lightingEnabled;
            break;
      }
      ......
   }
}

Example 8: Blending (Nehe Lesson 8: Blending)

TextureCube.java

Use texture image "glass.png". Remove the culling of back face.

MyGLRenderer.java
package com.test;
  
import javax.microedition.khronos.egl.EGLConfig;
import javax.microedition.khronos.opengles.GL10;
import android.content.Context;
import android.opengl.GLSurfaceView;
import android.opengl.GLU;
  
public class MyGLRenderer implements GLSurfaceView.Renderer {
   private Context context;
   private TextureCube cube;
   // For controlling cube's z-position, x and y angles and speeds
   float angleX = 0;
   float angleY = 0;
   float speedX = 0;
   float speedY = 0;
   float z = -6.0f;
   
   int currentTextureFilter = 0;  // Texture filter
  
   // Lighting
   boolean lightingEnabled = false;
   private float[] lightAmbient = {0.5f, 0.5f, 0.5f, 1.0f};
   private float[] lightDiffuse = {1.0f, 1.0f, 1.0f, 1.0f};
   private float[] lightPosition = {0.0f, 0.0f, 2.0f, 1.0f};
  
   // Blending (NEW)
   boolean blendingEnabled = false;  // Is blending on? (NEW)
  
   // Constructor
   public MyGLRenderer(Context context) {
      this.context = context;
      cube = new TextureCube();
   }
  
   // Call back when the surface is first created or re-created.
   @Override
   public void onSurfaceCreated(GL10 gl, EGLConfig config) {
      gl.glClearColor(0.0f, 0.0f, 0.0f, 1.0f);  // Set color's clear-value to black
      gl.glClearDepthf(1.0f);            // Set depth's clear-value to farthest
      gl.glEnable(GL10.GL_DEPTH_TEST);   // Enables depth-buffer for hidden surface removal
      gl.glDepthFunc(GL10.GL_LEQUAL);    // The type of depth testing to do
      gl.glHint(GL10.GL_PERSPECTIVE_CORRECTION_HINT, GL10.GL_NICEST);  // nice perspective view
      gl.glShadeModel(GL10.GL_SMOOTH);   // Enable smooth shading of color
      gl.glDisable(GL10.GL_DITHER);      // Disable dithering for better performance
  
      // Setup Texture, each time the surface is created
      cube.loadTexture(gl, context);    // Load image into Texture
      gl.glEnable(GL10.GL_TEXTURE_2D);  // Enable texture
      
      // Setup lighting GL_LIGHT1 with ambient and diffuse lights
      gl.glLightfv(GL10.GL_LIGHT1, GL10.GL_AMBIENT, lightAmbient, 0);
      gl.glLightfv(GL10.GL_LIGHT1, GL10.GL_DIFFUSE, lightDiffuse, 0);
      gl.glLightfv(GL10.GL_LIGHT1, GL10.GL_POSITION, lightPosition, 0);
      gl.glEnable(GL10.GL_LIGHT1);   // Enable Light 1
      gl.glEnable(GL10.GL_LIGHT0);   // Enable the default Light 0
      
      // Setup Blending (NEW)
      gl.glColor4f(1.0f, 1.0f, 1.0f, 0.5f);           // Full brightness, 50% alpha (NEW)
      gl.glBlendFunc(GL10.GL_SRC_ALPHA, GL10.GL_ONE); // Select blending function (NEW)
   }
   
   // Call back after onSurfaceCreated() or whenever the window's size changes.
   @Override
   public void onSurfaceChanged(GL10 gl, int width, int height) {
      // NO CHANGE - SKIP
      ......
   }
  
   // Call back to draw the current frame.
   @Override
   public void onDrawFrame(GL10 gl) {
      // Clear color and depth buffers
      gl.glClear(GL10.GL_COLOR_BUFFER_BIT | GL10.GL_DEPTH_BUFFER_BIT);
  
      // Enable lighting?
      if (lightingEnabled) {
         gl.glEnable(GL10.GL_LIGHTING);
      } else {
         gl.glDisable(GL10.GL_LIGHTING);
      }
      
      // Blending Enabled? (NEW)
      if (blendingEnabled) {
         gl.glEnable(GL10.GL_BLEND);       // Turn blending on (NEW)
         gl.glDisable(GL10.GL_DEPTH_TEST); // Turn depth testing off (NEW)
         
      } else {
         gl.glDisable(GL10.GL_BLEND);      // Turn blending off (NEW)
         gl.glEnable(GL10.GL_DEPTH_TEST);  // Turn depth testing on (NEW)
      }
      
      // ----- Render the Cube -----
      gl.glLoadIdentity();              // Reset the model-view matrix
      gl.glTranslatef(0.0f, 0.0f, z);   // Translate into the screen
      gl.glRotatef(angleX, 1.0f, 0.0f, 0.0f); // Rotate
      gl.glRotatef(angleY, 0.0f, 1.0f, 0.0f); // Rotate
      cube.draw(gl, currentTextureFilter);
        
      // Update the rotational angle after each refresh
      angleX += speedX;
      angleY += speedY;
   }
}
MyGLSurfaceView.java
......
public class MyGLSurfaceView extends GLSurfaceView {
   .......
  
   // Handler for key event
   @Override
   public boolean onKeyUp(int keyCode, KeyEvent evt) {
      switch(keyCode) {
         .......
         case KeyEvent.KEYCODE_B:  // Toggle Blending on/off (NEW)
            renderer.blendingEnabled = !renderer.blendingEnabled;
            break;
      }
      ......
   }
}

Example 8a: Bouncing Ball in Cube

[TODO] No primitive to draw a sphere in OpenGL ES.

Android Port for Nehe's Lessons

I have ported some of the Nehe's lessons into Android. Refer to Nehe for the problem descriptions.

Setting Up:

  • Nehe's Lesson #1: Setting up OpenGL's window. (Refer to above examples.)

OpenGL Basics: I consider Lessons 2-8 as OpenGL basic lessons, that are extremely important! (Refer to above examples.)

  • Nehe's Lesson #2: Your first polygon
  • Nehe's Lesson #3: Adding Color
  • Nehe's Lesson #4: Rotation
  • Nehe's Lesson #5: 3D Shape
  • Nehe's Lesson #6: Texture
  • Nehe's Lesson #7: Texture Filter, Lighting, and key-controlled
  • Nehe's Lesson #8: Blending

Intermediate: [TODO]

 

REFERENCES & RESOURCES

Friday, October 23, 2020

Learn to code

Learn Coding

Before Getting Started...

IM1003 Object-oriented Programming

Java Basics
Java OOP
Java Graphics
Case Study / Assignment

IM2073 Web Programming

IM2073 Mobile (Android) Programming

How to Install & Get Started...

Windows
Unix, Ubuntu Linux & macOS

Android

Arduino

Power User Software Notes

ICPC

Java Programming - Part I

For First-Time Programmers
For New Comers to Java & OOP

Power Programmers

Java Programming - Part II

Intermediate Java
Special Topics in Java
Java Appendices

Java ME (Obsoleted)

Java Game Programming

Client-Side Programming

HTML/CSS
JavaScript
Client-Side Frameworks
Node.js & Server-Side JavaScript

Database Programming

MySQL
JDBC
PostgreSQL
MongoDB

Server-side Programming

Java Servlet/JSP
PHP
Perl
Python

Webapps

Basics
Testing
Security
Misc

Dapps

Blockchain

Web Protocols

3D Graphics & OpenGL

Setup on Various Platforms
Computer Graphics with OpenGL
OpenGL|ES
Physics Engine

C/C++ Programming

C++ Programming Language
C Programming Language
C/C++ Compilers and IDEs
Salesforce Admin and developer Tutorials
Web Hits

Friday, June 26, 2020

How to get 20 -30 lakhs per annum with 4 years of IT experience

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Learn Salesforce the sure shot way to get better pay






Pasta and Wine

Master React Js in 4 days

React is a declarative, efficient, and flexible JavaScript library for building Web Applications. It follows component-based approach. Easy to create smaller components and build large-scale applications. The main goal is to help new  or experience developers quickly understand the concepts with examples and then be able to actually use them in the real world.

Tuesday, June 23, 2020

Western media biased reporting on corona virus

 1. Using azithro to fight pneumonia
2. use dexamethosse to fight lung infection
3. why not also use holiistic approach like ayyurveda,along with allopathy
4. does not discuss previous current health history of patients
5. does not discuss smoking as soon as getting up,drug habits ,drinking pepsi and having fried burgers on regular basis are some of the terrbile habits in usa
6. using cars all the time even for small commute all the time drinking pepsi
7. do these patients being interviewed,stop smoking ,drinking pepsit coke,and other harmful habits when they are infected
8 patients with comorbidiyt,were they taking there diabetes medicine,bp medicine or time ,or where having burggers and cokes and smoking morning to evening

Friday, June 12, 2020

Cracking the Code: How to Ace the Salesforce Admin Certification Exam

Cracking the Code: How to Ace the Salesforce Admin Certification Exam

Unlocking Your Potential: The Benefits of Salesforce Certification in Today's Competitive Job Market






In today's competitive job market, standing out from the crowd is essential. And one way to do that is by obtaining a Salesforce certification. Salesforce is a leading customer relationship management (CRM) platform used by businesses worldwide. By becoming certified in Salesforce, you can demonstrate your expertise in utilizing this powerful tool and gain a competitive advantage in your job search.

But what exactly are the benefits of Salesforce certification? First and foremost, it enhances your credibility and validates your knowledge. Employers value individuals who have invested the time and effort into obtaining a Salesforce certification, as it shows a commitment to professional development and mastery of the platform.

Additionally, Salesforce certification opens up new career opportunities. With more and more businesses relying on Salesforce for their CRM needs, the demand for certified professionals is rapidly increasing. By becoming certified, you become a sought-after candidate in areas such as sales, marketing, customer service, and software development.

So, if you're looking to unlock your potential and take your career to the next level, consider obtaining a Salesforce certification. The benefits are tangible and can help you stand out in today's competitive job market.

Why is the Salesforce Admin Certification Exam important?

The Salesforce Admin Certification Exam is a crucial step towards becoming a certified Salesforce administrator. It serves as a validation of your skills and knowledge in using the Salesforce platform to manage and optimize customer relationships. Whether you are a seasoned professional or just starting your career in the CRM field, the Salesforce Admin Certification Exam provides a recognized standard by which your abilities can be assessed.

By passing the exam, you demonstrate your proficiency in various aspects of Salesforce administration, including data management, security, automation, and customization. This certification not only enhances your credibility but also increases your chances of landing job opportunities and advancing your career in the Salesforce ecosystem.

Moreover, the Salesforce Admin Certification Exam is continuously updated to reflect the latest features and functionalities of the platform. By keeping up with these changes and staying certified, you ensure that your skills remain relevant and up-to-date in a fast-paced technological landscape.

Preparing for the Salesforce Admin Certification Exam

Preparing for the Salesforce Admin Certification Exam requires a strategic approach and a comprehensive study plan. By following these steps, you can increase your chances of success and maximize your learning experience:

Understanding the exam structure and format

Before diving into the study material, it is vital to familiarize yourself with the exam structure and format. The Salesforce Admin Certification Exam consists of multiple-choice questions and is conducted online. It is a proctored exam, meaning that you will be monitored throughout the duration of the test to ensure its integrity.

The exam covers various topics related to Salesforce administration, such as data management, security and access, automation, and customization. Understanding the weightage of each topic and the number of questions you can expect from each area will help you allocate your study time effectively.

Key topics covered in the Salesforce Admin Certification Exam

To excel in the Salesforce Admin Certification Exam, you need to have a solid understanding of the key topics that will be tested. Some of the essential areas you should focus on include:

- Data management: Knowing how to import, export, and manage data within Salesforce, as well as understanding data validation rules and data quality best practices.

- Security and access: Understanding user management, profiles, roles, and permission sets, as well as implementing security controls and maintaining data integrity.

- Automation: Mastering the use of workflow rules, process builder, and approval processes to automate business processes and improve efficiency.

- Customization: Being proficient in customizing Salesforce objects, fields, page layouts, and record types to meet specific business requirements.

Tips and strategies for studying effectively

Studying for the Salesforce Admin Certification Exam requires discipline and a well-structured approach. Here are some tips and strategies to help you make the most of your study time:

- Create a study schedule: Plan your study sessions in advance and allocate specific time slots for each topic. This will help you stay organized and ensure that you cover all the necessary material.

- Utilize official Salesforce documentation: Salesforce provides comprehensive documentation and trailhead modules that cover all the topics included in the exam. Make use of these resources to gain a deep understanding of the concepts and functionalities.

- Practice with sample questions: Familiarize yourself with the types of questions you may encounter in the exam by practicing with sample questions and quizzes. This will help you assess your knowledge and identify areas that require further study.

- Join study groups or online forums: Engaging with other Salesforce certification aspirants can be highly beneficial. Join study groups or online forums where you can discuss concepts, share resources, and learn from others' experiences.

Practice exams and resources for exam preparation

In addition to studying the official Salesforce documentation, it is essential to test your knowledge and assess your readiness with practice exams. Several resources can help you prepare for the Salesforce Admin Certification Exam:

- Official Salesforce practice exams: Salesforce offers practice exams that simulate the real exam experience. These practice tests can help you familiarize yourself with the exam format and evaluate your level of preparedness.

- Online training courses: Various online platforms provide comprehensive training courses specifically designed for Salesforce certification exams. These courses cover all the exam topics and often include practice quizzes and mock exams to gauge your progress.

- Community resources: The Salesforce community is vast and supportive. Take advantage of online forums, blogs, and user groups to access additional study materials, tips, and guidance from experienced professionals.

By utilizing these resources and dedicating sufficient time to studying and practicing, you can significantly improve your chances of acing the Salesforce Admin Certification Exam.

Taking the Salesforce Admin Certification Exam

After thorough preparation and study, the next step is to schedule and take the Salesforce Admin Certification Exam. Here's what you can expect on exam day:

What to expect on exam day

- Technical requirements: Ensure that you have a reliable internet connection and a compatible computer or device that meets the exam's technical requirements. It is also recommended to use a quiet and distraction-free environment for optimal focus.

- Check-in process: Before starting the exam, you will need to complete a check-in process, which may include verifying your identity and ensuring that your testing environment meets the requirements.

- Exam duration: The Salesforce Admin Certification Exam typically has a time limit of 90 minutes. This duration may vary, so it's essential to check the specific exam details beforehand.

- Question format: The exam consists of multiple-choice questions, where you will be presented with several answer options for each question. Read each question carefully and choose the best answer based on your knowledge and understanding of the topic.

- Scoring and passing criteria: The passing score for the Salesforce Admin Certification Exam is set by Salesforce and may vary. After completing the exam, you will receive your score immediately, along with a detailed breakdown of your performance in each topic area.

- Retaking the exam: In the event that you do not pass the exam on your first attempt, don't be discouraged. Salesforce allows you to retake the exam after a waiting period of 15 days. Use this time to identify your weak areas and focus on improving your knowledge and understanding.

Conclusion and next steps after passing the exam

Congratulations on passing the Salesforce Admin Certification Exam! By achieving this milestone, you have demonstrated your expertise in Salesforce administration and opened up a world of opportunities.

Now that you are certified, it's time to leverage your achievement and take the next steps in your career:

- Update your resume and online profiles: Highlight your Salesforce certification prominently on your resume, LinkedIn profile, and other professional platforms. This will catch the attention of potential employers and increase your chances of landing job interviews.

- Explore job opportunities: With your Salesforce Admin Certification in hand, you are now qualified for a wide range of job roles, including Salesforce administrator, business analyst, and consultant. Research job openings, network with industry professionals, and apply for positions that align with your career goals.

- Continue learning and expanding your skills: The Salesforce platform is continuously evolving, and staying up-to-date with the latest developments is crucial. Take advantage of additional Salesforce certifications, attend webinars and workshops, and participate in the Salesforce Trailblazer community to expand your knowledge and enhance your professional growth.

Remember, obtaining the Salesforce Admin Certification is just the beginning of your journey. With dedication, continuous learning, and a passion for Salesforce, you can unlock countless opportunities and excel in the dynamic world of CRM.

Congratulations on completing this comprehensive guide to cracking the Salesforce Admin Certification Exam. Now it's time to put your knowledge into action and take the first step towards achieving your professional goals!


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Thursday, June 4, 2020

Full React Js tutorial for beginners -Building your first react app step by step ,complete video series


Links to salesforce trainings -> Get Salesforce Certification
ReactJS Training Overview- above videos will keep on scrolling to next video,one one video ends React is a declarative, efficient, and flexible JavaScript library for building Web Applications. It follows component-based approach. Easy to create smaller components and build large-scale applications. The main goal is to help new or experience developers quickly understand the concepts with examples and then be able to actually use them in the real world. Sample code is given for all the below topics Main topics React with Node Creating an application using Create React App. Life Cycle Debugging Default values SetState in depth Creating Forms Handling Events Validations Applying Styles Backend calls Stateful Components Stateless Components Local Storage Routing Routing Http calls Creating Reusable Components Fragments FORMS How to use React Redux framework