Summary

YOLOL is a programming language used to control and manage electrical devices.

The code is written on lines in YOLOL chips which are then inserted into chip sockets, that read and relay their messages.

The programming language enables the programming and controlling of almost any device within the known universe.

Basic information

How it works

The code is written to and executed from programmable chips, and can be used to both monitor and control electrical devices connected to a data network.

Lines of code are executed in sequence from top to bottom, repeating the cycle of the chip after the last line has been executed, unless the script includes programmed instructions for specific line changes or stopping the execution completely.

To put it simply:

Code execution starts from line 1 After reading line 1, it proceeds to the next line based on the chip's time interval The process is then repeated for the line 2, 3, 4... etc. The chip will begin executing line 1 again after the last line has been executed (unless the last line contains a goto statement or execution has been paused)

So blank lines still use 0.2 seconds, and can be used as a brief execution delay. (lines with only a comment are effectively the same as a blank line.)

Related pages

Command references

Case insensitive

The programming language is fully case insensitive.

This means that the following two example scripts function identically to each other:

if ButtonState == 1 then DoorState = 1 end

IF buttonstate == 1 THEN doorstate = 1 END

Both scripts set the doorstate into 1, if buttonstate value is 1.

into 1, if value is 1. The characters in the programming language can be written in either lowercase or uppercase letters. They are still parsed as case insensitive. This way it's possible to have the code look a bit more organized.



Variables

The variables in the programming language are weakly typed (don't enforce type validity), and support two data types: Fixed-point decimals (up to 0.001 precision) and Strings . To put it simply, the variables can either be introduced as strings or numbers, ignoring the earlier variable type if the previous type is not identical, without causing an error.

(up to 0.001 precision) and . Each variable is always of a single type, though it will be implicitly converted when required.

The default value of an uninitialized variable is 0, and null values are not supported.

True/False are numerical values of non-0 and 0. True =! 0 False == 0



Assigning a value to a variable always converts the variable to the newly assigned value's type.

Example:

ultimateAutopilot= 128.643

This results in the variable ultimateAutopilot containing a numeric value of 128.643





ultimateAutopilot= "Error prone"

This results in the variable ultimateAutopilot to be a string variable "Error prone", and numeric value of 128.643 is removed.

Decimals

Numeric values in the programming language are 64-bit fixed-point decimals.

The variables hold decimal numbers up to three decimal accuracy.

As a result, the maximum value range (even during operations) is [-9223372036854775.808, 9223372036854775.807]

pieVariable= 3.142

The above script assigns a numeric value of 3.142 to the variable pieVariable . Supplying more precise values than the variables can store works, but doesn't affect the end result.

.

notPieVariable= 0.5772156649

The above script attempts to assign a numeric value of 0.5772156649 to the variable notPieVariable .

. The end result however is notPieVariable == 0.577 Here, the more precise values are cut, leaving only three decimals behind.



Strings

To specify a string literal in the programming language, the desired string value must be surrounded with double quotation marks.

badRobots= "saltberia"

This script assigns the string value of "saltberia" to the variable badRobots.

Device fields / External variables

External variables and device fields can be used in the programming language with the following syntax:



:variableName variableName being the configured device field id.



A colon prefix : is used to tell the script that an external variable is being accessed, instead of using one that may or may not be declared or used in the script.

A programmable chip that is connected to a device has access to all the devices in the same network.

It can then modify and listen to any device fields it has access to.



if :ButtonState == 1 then :DoorState = 1 end

The script above will send the value of 1 to any devices listening to the device field DoorState if the value of ButtonState is 1 in the data network.

Operators and commands

Note that the available operators may be limited by the type of the programmable chip.

Basic chips have a limited selection of functions while more advanced ones can perform more complex operations natively.

Basic arithmetic and assignment operators

Basic arithmetic and assignment

Operation Numeric operation String operation Chip availability A + B Addition String A is appended by String B. All A - B Subtraction The last appearance of String B in String A is removed from String A. All A * B Multiplication Runtime error. The rest of the line is skipped. All A / B Division Runtime error. The rest of the line is skipped. All A ++ PostIncrement (A=A+1) Appends a space to String A. Evaluates to the original value. All A -- PostDecrement (A=A-1) Removes the last character of the string. Results in runtime error when trying to remove "". Evaluates to the original value. All ++ A PreIncrement (A=A+1) Appends a space to String A. Evaluates to the modified value. All -- A PreDecrement (A=A-1) Removes the last character of the string. Results in runtime error when trying to remove "". Evaluates to the modified value. All A = B Assignment (Variable A is set to the value of variable B) Assignment All A += B Addition-assignment (A=A+B) A is assigned the value of string-operation A+B All A -= B Subtraction-assignment (A=A-B) A is assigned the value of string-operation A-B All A *= B Multiplication-assignment (A=A*B) Runtime error. The rest of the line is skipped. All A /= B Division-assignment (A=A/B) Runtime error. The rest of the line is skipped. All A %= B Modulo-assignment (A=A%B) Runtime error. The rest of the line is skipped. Advanced, Professional A ^ B Exponentiation Runtime error. The rest of the line is skipped. Advanced, Professional A % B Modulo Runtime error. The rest of the line is skipped. Advanced, Professional ABS A Modulus (absol value) (A=A if A>=0, else A=-A) Runtime error. The rest of the line is skipped. Advanced, Professional A! Factorial Runtime error. The rest of the line is skipped. Advanced, Professional SQRT A Square root of A Runtime error. The rest of the line is skipped. Advanced, Professional SIN A Sine of A (degrees) Runtime error. The rest of the line is skipped. Professional COS A Cosine of A (degrees) Runtime error. The rest of the line is skipped. Professional TAN A Tangent of A (degrees) Runtime error. The rest of the line is skipped. Professional ASIN A Inverse sine of A (degrees) Runtime error. The rest of the line is skipped. Professional ACOS A Inverse cosine of A (degrees) Runtime error. The rest of the line is skipped. Professional ATAN A Inverse tangent of A (degrees) Runtime error. The rest of the line is skipped. Professional

Logical operators

Logical operators are checks that identify if the statement is true or false.

All logical operations return either "0 for False" or "1 for True". The NOT, AND, and OR keywords consider 0 to be falsy and anything not 0 to be truthy.

Operation Numeric operation String operation Chip availability A < B Less than returns 1 if String A is first in alphabetical order, returns 0 if not. All A > B Greater than returns 0 if String A is first in alphabetical order, returns 1 if not. All A <= B Less than or equal to returns 1 if String A is first in alphabetical order or identical to String B, returns 0 if not. All A >= B Greater than or equal to returns 0 if String A is first in alphabetical order or identical to String B, returns 1 if not. All A != B Not equal to returns 1 if String A is not equal to String B, 0 if it is. All A == B Equal to returns 1 if String A is equal to String B, 0 if not. All NOT A Not Returns 1 if A is 0, otherwise returns 0. All A AND B And Returns 1 if neither A nor B are 0, otherwise returns 0. All A OR B Or Returns 1 if either A or B is not 0, otherwise returns 0. All

Mixing variable types in operations

Mixing variable types in an operation handles the operation using all parameters as strings.

previouslyNumber= "10" + 15

The above script results in previouslyNumber containing the string value "1015". Note that the involved parameters themselves don't change types, their values are just cast as strings for the purpose of the operation:

containing the string value "1015".

purelyNumber = 15 purelyString = "10" + purelyNumber

When this script has executed, purelyString contains the string value of "1015", while purelyNumber still contains the numeric value of 15.

Goto

Goto syntax is used when the normal script reading order from 1->20 is not desired, or needs to be altered.

Goto is used with the following syntax:

goto lineNumber lineNumber is the line which this command will take the script execution.

Any remaining script that is on the same line after the goto-command will not be executed. using if statements before goto ignores goto syntax, assuming the if-statement is false Multiple goto commands can be added on the same line using conditionals, as False goto commands are skipped. Numeric values outside the [1,20] range are clamped to this range. Non-integer values are floored. String values will result in a Runtime Error.



if variable == 5 then goto 4 end goto 6

The script above will go to line number 4, if variable has a value of 5.

Otherwise it will go to line number 6. Numerical operations can also be done "inside" the goto, e.g.

goto 4+1

If-else conditional

If-else statements are used to branch out the script into different paths.

They use the following syntax:

if condition then statement else statement end Condition is a statement that results in a numeric value (where 0 is parsed as False, anything else as True), and statements are pieces of script that are run. All If-else conditional stations must have end syntax written after statement is complete.



If can be used to branch script execution into two possible outcomes temporarily based on variable value(s).

Example:



if variable != 2 then endResult = 3 else endResult = 4 end

This script sets the value of endResult to 3 if variable does not have the value of 2.

to 3 if does not have the value of 2. If variable's value is 2, endResult is set to the value of 4.

Note that the else statement -part can be left out if not needed.

Example:



if variable != 2 then endResult = 3 end

This script only sets the value of 3 to endResult if variable does not have a value of 2, and doesn't do anything else.

Nesting if statements

It is possible to place if-conditionals inside the true/false statement blocks to achieve further branching of execution.

Example:



if variable == 0 then endResult = 1 else if variable == 1 then endResult = 2 end end

This script sets endResult to 1 if variable equals 0.

to 1 if equals 0. If variable doesn't equal 0, but it equals 1, endResult is set to 2.

Example:



if variable == 0 then if endResult == 1 then endResult = 2 end else endResult = 1 end

This script sets endResult to 2 if variable has a value of 0, and endResult equals to 1.

to 2 if has a value of 0, and equals to 1. Otherwise it sets endResult to 1.

Note that it may be easier to plan and debug the script flow by formatting the script containing nested if-statements to a neater indented form.



Note: writing the script like this won't work on the chip, but doing this can still be useful when debugging scripts.

This is the second nested example formatted:

if variable == 0 then if otherVariable == 1 then otherVariable = 2 end else otherVariable = 1 end

Comments are useful when writing code that is used by a lot of programmers.

Note that comments also use up space from the pre-determined 70 character line limit and are not excluded from it.



Commenting is used with the following syntax:

// text Text can be any single-line set of characters.



// This is a comment. It will explain how other lines of script work.

An example of a possible comment syntax

Errors

There are two types of errors that can happen with the programming language.

Syntax errors Runtime errors

Syntax errors come from invalid and unparseable script and will result in the whole line not being executed.

Runtime errors are only catchable while the script is being executed. They result in the execution of the line being interrupted, but any effects until the error will remain.