Generating a simple algebraic expression in swift

I'm looking to create a function that returns a solve for x math equation that can be preformed in ones head (Clearly thats a bit subjective but I'm not sure how else to phrase it).

Example problem: (x - 15)/10 = 6

Note: Only 1 x in the equation

I want to use the operations +, -, *, /, sqrt (Only applied to X -> sqrt(x))

I know that `let mathExpression = NSExpression(format: question)` converts strings into math equations but when solving for x I'm not sure how to go about doing this.

I previously asked Generating random doable math problems swift for non solving for x problems but I'm not sure how to convert that answer into solving for x

Edit: Goal is to generate an equation and have the user solve for the variable.

• Solving equations is not trivial, unless you restrict the allowed input to a very small set. Even with your restricted set of operations, you could have something like `sqrt(x) = 2*x+3`, which is doable, but already requires some algebraic transformation. Or what about polynomial equations, which do not have explicit solutions if the degree exceeds 4? Apr 9, 2017 at 20:36
• Is your goal to generate a string like "(x - 15)/10 = 6"? Or is the string supplied by the user, and you're trying to solve for x? Apr 9, 2017 at 20:37
• @Robert Goal is to generate the string and have the user solve for x. The equation cannot be sqrt(x) = 2*x+3 because there should only be 1 x (or variable) in the equation. Apr 9, 2017 at 20:39
• @MartinR see my comment above as to why that equation couldn't be. I am updating the question though Apr 9, 2017 at 20:40
• @huddie96 there is only 1 variable in that equation. It can appear twice. Apr 9, 2017 at 20:47

Since all you want is a string representing an equation and a value for x, you don't need to do any solving. Just start with x and transform it until you have a nice equation. Here's a sample: (copy and paste it into a Playground to try it out)

``````import UIKit

enum Operation: String {
case subtraction = "-"
case multiplication = "*"
case division = "/"

static func all() -> [Operation] {
}

static func random() -> Operation {
let all = Operation.all()
let selection = Int(arc4random_uniform(UInt32(all.count)))
return all[selection]
}

}

func addNewTerm(formula: String, result: Int) -> (formula: String, result: Int) {
// choose a random number and operation
let operation = Operation.random()
let number = chooseRandomNumberFor(operation: operation, on: result)
// apply to the left side
let newFormula = applyTermTo(formula: formula, number: number, operation: operation)
// apply to the right side
let newResult = applyTermTo(result: result, number: number, operation: operation)
return (newFormula, newResult)
}

func applyTermTo(formula: String, number:Int, operation:Operation) -> String {
return "\(formula) \(operation.rawValue) \(number)"
}

func applyTermTo(result: Int, number:Int, operation:Operation) -> Int {
switch(operation) {
case .addition: return result + number
case .subtraction: return result - number
case .multiplication: return result * number
case .division: return result / number
}
}

func chooseRandomNumberFor(operation: Operation, on number: Int) -> Int {
switch(operation) {
return Int(arc4random_uniform(10) + 1)
case .division:
// add code here to find integer factors
return 1
}
}

func generateFormula(_ numTerms:Int = 1) -> (String, Int) {
let x = Int(arc4random_uniform(10))
var leftSide = "x"
var result = x

for i in 1...numTerms {
(leftSide, result) = addNewTerm(formula: leftSide, result: result)
if i < numTerms {
leftSide = "(" + leftSide + ")"
}
}

let formula = "\(leftSide) = \(result)"

return (formula, x)
}

func printFormula(_ numTerms:Int = 1) {
let (formula, x) = generateFormula(numTerms)
print(formula, "                      x = ", x)
}

for i in 1...30 {
printFormula(Int(arc4random_uniform(3)) + 1)
}
``````

There are some things missing. The sqrt() function will have to be implemented separately. And for division to be useful, you'll have to add in a system to find factors (since you presumably want the results to be integers). Depending on what sort of output you want, there's a lot more work to do, but this should get you started.

Here's sample output:

``````(x + 10) - 5 = 11                       x =  6
((x + 6) + 6) - 1 = 20                       x =  9
x - 2 = 5                       x =  7
((x + 3) * 5) - 6 = 39                       x =  6
(x / 1) + 6 = 11                       x =  5
(x * 6) * 3 = 54                       x =  3
x * 9 = 54                       x =  6
((x / 1) - 6) + 8 = 11                       x =  9
``````
• I'll try when I get to my computer. Why do some output just x? Apr 9, 2017 at 22:24
• @huddie96 The sample output shows the generated equation on the left, value of x on the right. Apr 9, 2017 at 22:28
• Oh it's a problem with the stackoverflow app. My apologizes. It doesn't show what x = for some of the outputs Apr 9, 2017 at 22:30
• @huddie96 Division has to be by an integral factor to yield an int. I didn't write code to find factors, but I'm sure you can figure that out. Look for the comment that says "add code here to find integer factors". Apr 9, 2017 at 23:28
• Im looking to find integer factor of what number at that points? Apr 9, 2017 at 23:30

Okay, let’s assume from you saying “Note: Only 1 x in the equation” that what you want is a linear equation of the form `y = 0 = β1*x + β0`, where `β0` and `β1` are the slope and intercept coefficients, respectively.

The inverse of (or solution to) any linear equation is given by `x = -β0/β1`. So what you really need to do is generate random integers `β0` and `β1` to create your equation. But since it should be “solvable” in someone’s head, you probably want `β0` to be divisible by `β1`, and furthermore, for `β1` and `β0/β1` to be less than or equal to `12`, since this is the upper limit of the commonly known multiplication tables. In this case, just generate a random integer `β1 ≤ 12`, and `β0` equal to `β1` times some integer `n`, `0 ≤ n ≤ 12`.

If you want to allow simple fractional solutions like `2/3`, just multiply the denominator and the numerator into `β0` and `β1`, respectively, taking care to prevent the numerator or denominator from getting too large (`12` is again a good limit).

Since you probably want to make `y` non-zero, just generate a third random integer `y` between `-12` and `12`, and change your output equation to `y = β1*x + β0 + y`.

Since you mentioned `√` could occur over the `x` variable only, that is pretty easy to add; the solution (to `0 = β1*sqrt(x) + β0`) is just `x = (β0/β1)**2`.

Here is some very simple (and very problematic) code for generating random integers to get you started:

``````import func Glibc.srand
import func Glibc.rand
import func Glibc.time

srand(UInt32(time(nil)))
print(rand() % 12)
``````

There are a great many answers on this website that deal with better ways to generate random integers.