W2513 Emergence & Lindenmayer Systems (Part 3)
Prerequisites[edit]
Experiment[edit]
Getting Started[edit]
Create a new Scenes shell project within your Experiences directory:
ty-cam@codermerlin:~$ cd ~/Experiences
ty-cam@codermerlin:~/Experiences$ git clone https://github.com/TheCoderMerlin/ScenesShellBasic LSystemScenes
Enter the Sources/ScenesShell directory of the new project:
ty-cam@codermerlin:~/Experiences$ cd LSystemScenes/Sources/ScenesShell/
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Run the program.
ty-cam@codermerlin:~/Experiences/LSystemScenes/Sources/ScenesShell$ run |
Ensure that you are logged on to the wiki. Then, click on the Tools menu followed by right-clicking on IGIS and selecting the menu item Open in New Window or Open in New Tab.
You'll know you're successful if you see the title bar change to "Coder Merlin: IGIS". (The browser window will be blank because we haven't added any graphics yet.)
Helpful Hint
First Steps[edit]
Add your LSystem File[edit]
Add your LSystem file from your previous project to your current project.
Depending upon your directory structure, execute a command similar to:
john-williams@codermerlin:~/Experiences$ cp ~/Merlin/M2512-10\ \(01\)\ LSystems/C100\ LSystems\ \[Swift\]/main.swift ~/Experiences/LSystemScenes/Sources/ScenesShell/LSystem.swift
Remove LSystem Global Functions[edit]
Remove your global functions and variables from LSystem.swift, leaving only the classes (e.g. ProductionRule, ProductionRules, LSystem) which you've defined. Then, ensure that you're able to successfully compile.
john-williams@codermerlin:~/Experiences/LSystemScenes/Sources/ScenesShell$ build
Geometric Structures[edit]
Recall from your previous lab that Lindenmayer Systems are defined by G = (V, ฯ, P) along with a mechanism to translate the generated strings into geometric structures. This lab will focus on this mechanism.
Getting Ready to Use the Turtle[edit]
Edit the file Background.swift:
Before the init constructor, add the following:
private var didRender = false
This will enable us to keep track of whether or not we need to render.
In order to use the turtle, we need to ensure that we know the size of the canvas in our render method. Add the following text:
override func render(canvas:Canvas) {
if let canvasSize = canvas.canvasSize, !didRender {
didRender = true
}
}
The render method is an event handler which is invoked periodically. The if let conditional provides us with syntactic sugar which assigns canvas.canvasSize to a new, local variable if (and only if) canvas.canvasSize is not nil and we haven't yet rendered. Note that canvas.canvasSize will be nil until the browser has calculated and reported the size of the canvas.
Creating the Turtle[edit]
Add a statement to create a new turtle. Remember that the turtle will be created in its home position, at the center of the screen, and facing north.
override func render(canvas:Canvas) {
if let canvasSize = canvas.canvasSize, !didRender {
let turtle = Turtle(canvasSize:canvasSize)
didRender = true
}
}
Rendering the Koch Curve[edit]
Let's add a function to render a Koch Curve. Place this function somewhere within the Background class.
func moveTurtleForKochCurve(turtle:Turtle, generationCount:Int, steps:Int) {
// Create the LSystem
let alphabet = Set<Character>(["F", "+", "-"])
let axiom = "F"
let productionRules = [ProductionRule(predecessor:"F", successor:"F+F-F-F+F")]
let lSystem = LSystem(alphabet:alphabet, axiom:axiom, productionRules:productionRules)
let production = lSystem.produce(generationCount:generationCount)
// Start in a good direction
turtle.right(degrees:90)
// Map the LSystem to turtle graphics
for letter in production {
switch (letter) {
case "F":
turtle.forward(steps:steps)
case "+":
turtle.left(degrees:90)
case "-":
turtle.right(degrees:90)
default:
fatalError("Unexepected letter '\(letter)' in production.")
}
}
}
We've defined the function but haven't invoked it from anywhere. Let's do that now from the render method. Modify the method so that it appears as:
override func render(canvas:Canvas) {
if let canvasSize = canvas.canvasSize, !didRender {
let turtle = Turtle(canvasSize:canvasSize)
moveTurtleForKochCurve(turtle:turtle, generationCount:3, steps:20)
canvas.render(turtle)
didRender = true
}
}
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Run the program and refresh the browser page. |
Add Button Functionality[edit]
We'll be using the library ScenesControls in order to enable us to easily add buttons to our project. To use this library:
Add the Library[edit]
Find the current version of the library. You can find the libraries at /usr/local/lib/merlin. In this case:
ty-cam@codermerlin:~/Experiences/LSystemScenes/Sources/ScenesShell ls -ld /usr/local/lib/merlin/ScenesControls*
You'll see something similar to:
drwxr-xr-x 3 root root 4096 Mar 14 11:20 /usr/local/lib/merlin/ScenesControls-0.1.0
In the above case, the most recent version of ScenesControls is 0.1.0. Now, edit the file dylib.manifest in the root of your project, adding the required library:
Igis 1.3.7
Scenes 1.1.5
ScenesControls 0.1.0
Finally, import the required libraries at the top of your InteractionLayer.swift:
import Igis
import Scenes
import ScenesControls
Implement Ability to Set GenerationCount[edit]
In Background.swift, add a variable to track the current generation count (above init):
private var didRender = false
private var generationCount = 1
Next, add a function to increment the generation count:
public func incrementGenerationCount() {
generationCount += 1
didRender = false
}
Also, change the moveTurtleForKochCurve function to use the generationCount property.
Create Button to Activate Functionality[edit]
In InteractionLayer.swift, add the following function to provide access to our Background object:
func background() -> Background {
guard let mainScene = scene as? MainScene else {
fatalError("mainScene of type MainScene is required")
}
let backgroundLayer = mainScene.backgroundLayer
let background = backgroundLayer.background
return background
}
In the same file, add a handler which will be invoked when the user clicks the mouse on the button:
func onIncreaseGenerationButtonClickHandler(control: Control, localLocation: Point) {
background().incrementGenerationCount()
}
Finally, again in the same file, create a button and link it to our handler in init:
init() {
super.init(name:"Interaction")
let increaseGenerationButton = Button(name: "IncreaseGenCount", labelString: "Increase Generation", topLeft: Point(x: 50, y: 50))
increaseGenerationButton.clickHandler = onIncreaseGenerationButtonClickHandler
insert(entity: increaseGenerationButton, at: .front)
}
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Run the program and refresh the browser page. |
Click on the button. What do you observe? Be sure that you thoroughly understand each of the above methods.
๐ See Also[edit]
๐บ Videos[edit]
Lindenmayer Systems and The Nature of Code
Procedural Plant Generation with L-Systems
๐ Texts[edit]
W2511 Emergence & Lindenmayer Systems (Part 1)
W2512 Emergence & Lindenmayer Systems (Part 2)
W2513 Emergence & Lindenmayer Systems (Part 3)
W2514 Emergence & Lindenmayer Systems (Part 4)
๐ References[edit]
Exercises[edit]
- Add a button to decrement the generation count
- Clear the canvas before painting so that the previous painting is erased
- Add logic to limit the generation count to reasonable values
- Add at least two additional L-Systems (as described here and that do not require saving/restoring the Turtle's state) and a single button to cycle through the current system being drawn
- Add buttons to control the number of steps used by the turtle for the current system being drawn
- Add a single button to cycle through at least five of your favorite colors
Supplemental Exercises
- Reposition the initial turtle position to a logical location based on the L-System presented. (For example, if the system grows up and to the right, a reasonable starting position would be the bottom-left of the canvas.)
