Tuesday, August 30, 2016

12 Essential Unity or Unity3D Interview Questions

Answer the following questions about threading. Explain your answers:
  1. Can threads be used to modify a Texture on runtime?
  2. Can threads be used to move a GameObject on the scene?
  3. Consider the snippet below:
class RandomGenerator : MonoBehaviour
{
    public float[] randomList;

    void Start()
    {
        randomList = new float[1000000];
    }

    void Generate()
    {
        System.Random rnd = new System.Random();
        for(int i=0;i<randomList.Length;i++) randomList[i] = (float)rnd.NextDouble();
    }
}
Improve this code using threads, so the 1000000 random number generation runs without spoiling performance.
  1. No. Texture and Meshes are examples of elements stored in GPU memory and Unity doesn’t allow other threads, besides the main one, to make modifications on these kinds of data.
  2. No. Fetching the Transform reference isn’t thread safe in Unity.
  3. When using threads, we must avoid using native Unity structures like the Mathf and Random classes:
class RandomGenerator : MonoBehaviour
{
    public float[] randomList;

    void Start()
    {
        randomList = new float[1000000];
        Thread t = new Thread(delegate()
        {
            while(true)
            {
                Generate();
                Thread.Sleep(16); // trigger the loop to run roughly every 60th of a second
            }            
        });
        t.Start();
    }

    void Generate()
    {
      System.Random rnd = new System.Random();
      for(int i=0;i<randomList.Length;i++) randomList[i] = (float)rnd.NextDouble();
    }
}
Explain what a vertex shader is, and what a pixel shader is.
Vertex shader is a script that runs for each vertex of the mesh, allowing the developer to apply transformation matrixes, and other operations, in order to control where this vertex is in the 3D space, and how it will be projected on the screen.
Pixel shader is a script that runs for each fragment (pixel candidate to be rendered) after three vertexes are processed in a mesh’s triangle. The developer can use information like the UV / TextureCoords and sample textures in order to control the final color that will be rendered on screen.
Explain why deferred lighting optimizes scenes with a lot of lights and elements.
During rendering, each pixel is calculated whether it should be illuminated and receive lightning influence, and this is repeated for each light. After approximately eight repeated calculations for different lights in the scene, the overhead becomes significant.
For large scenes, the number of pixels rendered is usually bigger than the number of pixels in the screen itself.
Deferred Lighting makes the scene render all pixels without illumination (which is fast), and with extra information (at a cost of low overhead), it calculates the illumination step only for the pixels of the screen buffer (which is less than all pixels processed for each element). This technique allow much more light instances in the project.
What are the benefits of having a visualization mode for rendering optimization, as shown on the picture bellow?
The “overdrawn” mode helps the user to profile the number of pixels being rendered in the same “area”. Yellow to white areas are “hot” areas where too many pixels are being rendered.
Developers can use this information to adjust their materials and make better use of the Z-Test and optimize the rendering.
Explain why Time.deltaTime should be used to make things that depend on time operate correctly.
Real time applications, such as games, have a variable FPS. They sometimes run at 60FPS, or when suffering slowdowns, they will run on 40FPS or less.
If you want to change a value from A to B in 1.0 seconds you can’t simply increase A by B-A between two frames because frames can run fast or slow, so one frame can have different durations.
The way to correct this is to measure the time taken from frame X to X+1 and increment A, leveraging this change with the frame duration deltaTime by doing A += (B-A) * DeltaTime.
When the accumulated DeltaTime reaches 1.0 second, A will have assumed B value.
Explain why vectors should be normalized when used to move an object.
Normalization makes the vector unit length. It means, for instance, that if you want to move with speed 20.0, multiplying speed * vector will result in a precise 20.0 units per step. If the vector had a random length, the step would be different than 20.0 units.
Consider the following code snippet below:
class Mover : MonoBehaviour
{
  Vector3 target;
  float speed;

  void Update()
  {
  
  }
}
Finish this code so the GameObject containing this script moves with constant speedtowards target, and stop moving once it reaches 1.0, or less, units of distance.
class Mover : MonoBehaviour
{

  Vector3 target;
  float speed;

  void Update()
  {
      float distance = Vector3.Distance(target,transform.position);

      // will only move while the distance is bigger than 1.0 units
      if(distance > 1.0f)
      {
        Vector3 dir = target - transform.position;
        dir.Normalize();                                    // normalization is obligatory
        transform.position += dir * speed * Time.deltaTime; // using deltaTime and speed is obligatory
      }     
  }
}
Can two GameObjects, each with only an SphereCollider, both set as trigger and raise OnTrigger events? Explain your answer.
No. Collision events between two objects can only be raised when one of them has a RigidBody attached to it. This is a common error when implementing applications that use “physics.”
Which of the following examples will run faster?
  1. 1000 GameObjects, each with a MonoBehaviour implementing the Update callback.
  2. One GameObject with one MonoBehaviour with an Array of 1000 classes, each implementing a custom Update() callback.
Explain your answer.
The correct answer is 2.
The Update callback is called using a C# Reflection, which is significantly slower than calling a function directly. In our example, 1000 GameObjects each with a MonoBehaviour means 1000 Reflection calls per frame.
Creating one MonoBehaviour with one Update, and using this single callback to Update a given number of elements, is a lot faster, due to the direct access to the method.
Explain, in a few words, what roles the inspector, project and hierarchy panels in the Unity editor have. Which is responsible for referencing the content that will be included in the build process?
The inspector panel allows users to modify numeric values (such as position, rotation and scale), drag and drop references of scene objects (like Prefabs, Materials and Game Objects), and others. Also it can show a custom-made UI, created by the user, by using Editor scripts.
The project panel contains files from the file system of the assets folder in the project’s root folder. It shows all the available scripts, textures, materials and shaders available for use in the project.
The hierarchy panel shows the current scene structure, with its GameObjects and its children. It also helps users organize them by name and order relative to the GameObject’s siblings. Order dependent features, such as UI, make use of this categorization.
The panel responsible for referencing content in the build process is the hierarchy panel. The panel contains references to the objects that exist, or will exist, when the application is executed. When building the project, Unity searches for them in the project panel, and adds them to the bundle.
Arrange the event functions listed below in the order in which they will be invoked when an application is closed:
Update()
OnGUI()
Awake()
OnDisable()
Start()
LateUpdate()
OnEnable()
OnApplicationQuit()
OnDestroy()
The correct execution order of these event functions when an application closes is as follows:
Awake()
OnEnable()
Start()
Update()
LateUpdate()
OnGUI()
OnApplicationQuit()
OnDisable()
OnDestroy()
Note: You might be tempted to disagree with the placement of OnApplicationQuit() in the above list, but it is correct which can be verified by logging the order in which call occurs when your application closes.
Explain the issue with the code below and provide an alternative implementation that would correct the problem.
using UnityEngine;
using System.Collections;

public class TEST : MonoBehaviour {
    void Start () {
        transform.position.x = 10;
    }
}
The issue is that you can’t modify the position from a transform directly. This is because the position is actually a property (not a field). Therefore, when a getter is called, it invokes a method which returns a Vector3 copy which it places into the stack.
So basically what you are doing in the code above is assigning a member of the struct a value that is in the stack and that is later removed.
Instead, the proper solution is to replace the whole property; e.g.:
using UnityEngine;
using System.Collections;

public class TEST : MonoBehaviour {
   void Start () {
        Vector3 newPos = new Vector3(10, transform.position.y, transform.position.z);
        transform.position = newPos;
    }
}s later removed.
Source: Toptal

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