An esoteric programming language, in TypeScript for heaven's sake.
P.S. Install the VSCode extension for syntax highlighting!
- To run a specific file:
npm run bussin <FILENAME>
- To run in repl mode (Bussin only):
npm run bussin
You can find an example at /examples/main.bs
We, at Bussin, believe everyone should be entertained while coding. Meet our alternative: .bsx.
Inside Bussin X, you can use BS syntax, however, it's recommended to use the BSX syntax described below.
import
will import data from another file.lit db be import("./database.bs") rn
objects
is available for dynamic object keys.objects.get(obj, yap("Name> "))
hollup
will create a timeout.hollup(bruh perform() { waffle("ok") }, 1000)
yappacino
will create an interval.yappacino(bruh perform() { waffle("ok") }, 1000)
- Object property setting is fixed!
lit obj be {} rn obj.e = nocap waffle(obj)
Mutable variables are created with:
lit x be 0 rn
You can also create a constant variable:
mf x be 0 rn
Note: You can only use rn
on variables.
Strings can be created with:
lit x be "Hello, World!" rn
You can also insert variables by using:
lit x be 0 rn
lit y be strcon("Hello, ", x) rn
Or you can format your string to include variables:
waffle(format("Hello, ${}", "World"))
However, you must use your regional currency symbol.
waffle(format("Hello, ${}", "World"))
waffle(format("Hello, €{}", "World"))
waffle(format("Hello, £{}", "World"))
waffle(format("Hello, ¥{}", "World"))
Numbers are simple:
lit x be 34 rn
lit y be 12 rn
lit z be x minus y rn
lit abc be fake rn
Booleans are also simple:
lit x be nocap rn
lit y be cap rn
Objects are essential in programming languages. Bussin X supports them too:
lit x be cap rn
lit obj be { key: nocap, x } rn
obj.key be cap
waffle(obj.key)
We, at Bussin X, believe arrays are redundant.
We, at Bussin X, believe comments are redundant. Code must be understandable without English.
Functions in programming are intricate entities that serve as modular units of code designed to perform specific tasks with a high degree of abstraction and reusability. These multifaceted constructs encapsulate a series of instructions, often comprising algorithmic operations and logical conditions, which execute a well-defined purpose within a larger program. Functionality is delineated through a meticulously crafted signature, encompassing parameters and return types, allowing for parameterization and value transmission between the calling code and the function body. The complexity further burgeons as functions may exhibit a plethora of characteristics, including but not limited to recursion, closures, and the ability to manipulate variables within their designated scopes. Their utility extends beyond mere procedural decomposition, often intertwining with the paradigms of object-oriented, functional, or imperative programming, depending on the programming language employed. The orchestration of functions, with their nuanced interplay, results in the orchestration of intricate software systems, promoting maintainability, readability, and the efficient allocation of computational resources. In essence, functions epitomize the sophisticated essence of programming, embodying the elegance and subtlety required to navigate the intricacies of algorithmic design and software engineering. You can create functions by using:
bruh perform(x, y) {
x minus y
}
We, at Bussin X, think return
statements are redundant. Instead, our superior functions return the last value emitted.
bruh perform(x, y) {
x plus y // will do nothing
x minus y
}
You can also run the function after a specified timespan:
hollup(bruh perform() {
waffle("A second later...")
}, 1000)
And you can also make it run at an interval:
yappacino(bruh perform() {
waffle("Spam!!!")
}, 1000)
If statements in Bussin X are very intuitive:
sus (1 fr 1){
waffle("1 is 1")
} impostor sus (1 nah 2){
waffle("1 is NOT 2")
} impostor sus (1 fr 3 carenot 1 fr 1){
waffle("1 is 1 or 3")
} impostor sus (1 fr 3 btw 1 fr 1){
waffle("1 is 1 and 3. how's that possible hello??")
} impostor {
waffle("How did we get here?")
}
Loops in Bussin X are very easy:
yall(lit i be 0 rn i smol 10 rn i plusplus){}
Because we, at Bussin X, believe programmers should be responsible for their code, we did not add any break
or continue
keyword functionality to loops.
Types in Bussin X are very important!
lit num: number be 0 rn
You can assign types on non-matching values too.
lit num: object be 0 rn
You can also assign types on values themselves.
lit x be nocap: boolean rn
You can assign types on types too.
lit x: number: number: object: string be 3 rn
In fact, you can use types anywhere!
yall: number(lit: object i: number be 0: object rn i smol 10 rn i plusplus){
waffle(strcon("Currently at ", i): object)
}: object: object: string
Note: Types don't do anything, in fact, they're removed before the lexer kicks in.
Bussin X also supports try
catch
statements:
fuck_around {
waffle(null plus hogrider)
} find_out {
waffle(error)
}
Cannot resolve 'hogrider' as it does not exist.
Note: find_out
doesn't return anything, "error" is a global variable.
You can utilize the math
helper by using:
waffle(nerd.random())
waffle(nerd.sqrt(144))
waffle(nerd.pi)
We also added helper functions for your anxiety:
waffle(nerd.ceil(3.4))
waffle(nerd.round(3.9))
waffle(nerd.abs(-2))
You can also simplify your math equations:
x beplus 5
y betimes 6
i plusplus
You can access the current time by using:
waffle(time())
You can import data from another bussin file like this:
lit stuff be import("./stuff.bsx") rn
The last value emitted in a file will be the exported data:
bruh printStuff() {
waffle("Bussin X")
}
bruh printStuff2() {
waffle("Also Bussin X")
}
{
printStuff,
printStuff2
}
If imported, the result will be an object which you can do obj.printStuff and obj.printStuff2
You can exit your program like this:
exit()
You can run terminal commands by using our Blazingly Fast 🚀 ClapBack() feature:
mf res be clapback("ls") rn
waffle(res)
Note: Clapback will throw an error if failed. Better pair it with fuck_around
& find_out
.
fuck_around {
lit insult be clapback("rm -rf /") rn
waffle(insult)
} find_out {
waffle(error, ":(")
}
lit x be yap("watcho name > ") rn
waffle(x)
Note: The user won't see the text they type, but you will successfully receive the text after the user presses Enter.
- Huge thanks to Tyler Laceby for creating the Guide to Interpreters!
- Thanks to Linker for showing me his compiler
- macromates.com for documenting TextMate Language syntax
- DreamBerd for the inspiration
- AST explorer for the helpful tool
Created with pure fucking hate by Face ♥