BSL:Manual: Difference between revisions
m (this sample code was always cursed; should be more logical now) |
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|} | |} | ||
To | To illustrate the '!' ("not") operator, the following three lines are equivalent: | ||
!(some_bool eq true) | !(some_bool eq true) | ||
some_bool eq false | some_bool eq false | ||
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===Defining=== | ===Defining=== | ||
When beginning to define a function, you must | When beginning to define a function, you must start the line with "func"... | ||
func int prepare_fight(int count, string enemy_name) | func int prepare_fight(int count, string enemy_name) | ||
Line 586: | Line 586: | ||
===Calling=== | ===Calling=== | ||
When you call a function it will execute its statements from top to bottom or until it hits a "[[#Returning|return]]" statement. This means that when you call a second function from inside another function, the second function will be executed until its end and then the rest of the first function will be executed. | When you call a function it will execute its statements from top to bottom or until it hits a "[[#Returning|return]]" statement. This means that when you call a second function from inside another function, the second function will be executed until its end and then the rest of the first function will be executed. You can think of the function calls as nested parentheses, where the innermost statement must close before the next-innermost level can close, and so on. (For example, here is a parenthetical statement (and another one (and one more!) inside of it)). | ||
You do not use "func" when calling a function. You simply use its name: | You do not use "func" when calling a function. You simply use its name: | ||
Line 605: | Line 605: | ||
===Recursive calling=== | ===Recursive calling=== | ||
A function can call itself | A function can call itself by invoking its own name: | ||
var int global_iterator = 0; | |||
func void bad_loop_idea(void) | |||
{ | |||
global_iterator = global_iterator + 1 | |||
dmsg("Calling myself..."); | |||
bad_loop_idea(); | |||
} | |||
This might seem useful for producing a loop, but a function can only call itself recursively about four times before you hit a limit in BSL and the script fails silently. Open a level with the above code placed in its level script and call bad_loop_idea() from the dev console. After you stop seeing the "Calling myself..." messages, run the command "global_iterator" to query its value and you'll probably get "5", meaning the recursion failed between the fourth and fifth levels. | |||
This limit can be bypassed if you use "[[#fork|fork]]" when calling a function from within itself, though this is not technically recursing: the logic will not complete in a predictable inside-to-outside order like our nested parentheses example in the previous section; instead it will run concurrently through all of the forked function calls. This can be very bad if you're trying to get reliable results, however there are ways to mitigate this. For a discussion of looping reliably with "fork", see {{SectionLink||Looping}}. | |||
===Returning=== | ===Returning=== | ||
As mentioned under {{SectionLink||Flow interrupt}}, "return" | As mentioned under {{SectionLink||Flow interrupt}}, "return" allows you to exit the function at that point. But because of the bug documented in that section you cannot use "return" conditionally, that is, exit early from a function depending on some logical condition ("if"). Since "return" can thus only be placed at the end of a function, there is no need to use it at all unless you are passing back a value with it like so: | ||
func int add_ten(int input) | func int add_ten(int input) | ||
Line 616: | Line 628: | ||
} | } | ||
When a function returns a value, you can use the function to set a variable as follows: | |||
some_number = add_ten(enemy_count); | some_number = add_ten(enemy_count); | ||
Function return values can also be used in "if" statements | Function return values can also be used in "if" statements. If you have a function that returns a bool... | ||
func bool is_it_safe(void) | func bool is_it_safe(void) | ||
Line 631: | Line 643: | ||
...then it could be called this way in some other function: | ...then it could be called this way in some other function: | ||
if (is_it_safe()) | if (is_it_safe() eq true) | ||
dprint("It is safe."); | dprint("It is safe."); | ||
else | else | ||
dprint("It is not safe."); | dprint("It is not safe."); | ||
Bizarre bug warning: Calling dprint() and dmsg() more than once within a function will produce unexpected results. One of the dprint()/dmsg() calls may become the return value for the function (even if it it's type "void"), or create a return value of 0, and more than two calls also might be ignored. | |||
===Looping=== | ===Looping=== | ||
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} | } | ||
Note that calling the same function again before it finishes running the first time can have undesired effects. Using "sleep" before each call can prevent this overlapping execution. A short function like the example above should not need a "sleep" statement | Note that calling the same function again before it finishes running the first time can have undesired effects. Imagine if you have another thread in the code accessing "counter" while increment() is still running in a loop; what value will it have at that moment? Real-world scripting scenarios will be more complex and thus more problematic if multiple concurrent calls to a function are in play at the same time. Using "sleep" before each fork call can prevent this overlapping execution. A short function like the example above should not need a "sleep" statement as the remainder of the function after the "fork" call will complete in the same tick. But the more complex the function, the more ticks you will need to allow for it to complete, requiring "sleep(1);", "sleep(3);", etc. before the "fork" call. | ||
An alternate looping method: See the two variants of the "schedule" keyword under "Concurrency" below. | |||
===Concurrency=== | ===Concurrency=== | ||
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} | } | ||
As you can see, | As you can see, fork-called functions can delay actions within themselves without holding up the rest of the script; this not only allows the use of "sleep" without affecting outside functions, but also any built-in functions that hold up BSL by design, like [[chr_wait_animation]]. | ||
Be aware that accidentally calling a nonexistent function using "fork" will crash Oni; when "fork" is not used, BSL will successfully recognize it as an unknown function and thus will not attempt to call it. | |||
====schedule ... at ...==== | ====schedule ... at ...==== | ||
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schedule dprint("Is this annoying yet?") repeat 50 every 20; | schedule dprint("Is this annoying yet?") repeat 50 every 20; | ||
This is equivalent to the following loop in a C-style | This is equivalent to the following loop in a C-style language: | ||
int i = 0; | int i = 0; | ||
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schedule dprint("Is this annoying yet?") repeat 0 every 20; # repeats forever | schedule dprint("Is this annoying yet?") repeat 0 every 20; # repeats forever | ||
"schedule-repeat-every" can be used in place of recursive functions that call themselves ''n'' times using "fork". For | "schedule-repeat-every" can be used in place of recursive functions that call themselves ''n'' times using "fork". For example… | ||
func void hey(void) | func void hey(void) | ||
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} | } | ||
…can be replaced by… | |||
func void hey(void) | func void hey(void) |
Latest revision as of 03:58, 14 December 2023
Oni's level scripts are written in BFWBungieFrameWork, the underlying layer of the game engine. Scripting Language, or BSL. A scripting language allows you to create a set of plain-text files which employ branching logic and various operators according to certain rules of syntax in order to process data using functions that act upon variables. If any of those terms are not familiar to you now, keep reading. If you found that sentence boringly obvious, then you should be experienced enough to get by with the Introduction page, a sort of quick reference. This Manual page, by contrast, provides both a thorough and newbie-friendly introduction to the language and also documents every known bug in the language, which a modder writing a complex script will want to know about.
Script files
When Oni loads a level's resources, it also loads and parses all .bsl files in the level's designated IGMD folder (the name of this folder is specified by ONLV). The code automatically begins running with the function called "main", regardless of which .bsl file it is found in (Oni's scripts always place it in a file ending in "_main.bsl"). The code then flows through whichever functions are called by "main". You can also manually call any of those functions from the developer console – however, you cannot define variables or functions through the console.
Besides the automatic starting point represented by the "main" function, there are types of game data which specify the names of functions to be called upon certain events. For instance, characters can trigger script functions upon their death, and trigger volumes can call functions when they are entered or exited. See CHAR, BINA/CONS, BINA/DOOR, NEUT, and TRGV for all known places in the game data that can trigger BSL functions.
Note that the optional global folder is also loaded for all levels, but if you create global/ and add a .bsl file to it, there is nothing to run the code unless you call one of its functions from the console or edit one of the existing levels' BSL files to call it.
Built-in commands
The documentation on this page centers around creating your own functions and variables. But Oni contains about 500 built-in functions and variables, referred to collectively as commands. It's the calls to these commands which are responsible for driving level scripts. These calls are organized and managed using functions and variables of your own creation, which you'll learn how to make by reading this page.
Looking at a BSL script, there is no immediate way to tell whether a function or variable is built-in or defined elsewhere in the scripts for that level. For instance "you_win" is a function defined in various scripts and "win" is a built-in function, and they look the same when called. The answer can only be found by searching the level's scripts for a definition of the function/variable or by knowing the names of the built-in ones. You will find the built-in commands listed on BSL:Functions and BSL:Variables.
Unlike the code in Oni's .bsl files, built-in functions and variables such as ai2_allpassive and chr_big_head are hardcoded into Oni, that is, they were defined in the engine code and then registered as accessible from BSL. This means that they are essentially black boxes: you are only given an external description of the input they take and the outcome of this input, but you cannot see the actual code behind them.
When using the developer console, you can manually call a built-in function, and can get and set the value of a built-in variable. However, you cannot actually define functions or declare variables through the console.
Syntax
As with natural languages like English, there are rules about punctuation, spacing, and word order in BSL.
Statements
All code consists of discrete statements. These statements can be gathered into larger structures like "blocks" and "functions" to create more efficient programs.
Statement separators
BSL accepts two statement separators: the semicolon (;) and the line-break. The following three pieces of code are equivalent:
dmsg("Statement 1"); dmsg("Statement 2");
and
dmsg("Statement 1"); dmsg("Statement 2");
and
dmsg("Statement 1") dmsg("Statement 2")
The third example is partly in old-style syntax, which is discussed under § Old vs. new syntax.
Compound statements
Compound statements are series of statements grouped together by a pair of curly braces:
{ dmsg("Statement 1"); dmsg("Statement 2"); dmsg("Statement 3"); }
The purpose of doing this is to place statements under either a function declaration (see § Declaration) or an "if" statement (see § Conditional). Such a group of statements is referred to as a "block", and sometimes also defines a "scope". Traditionally in programming, anything inside a certain scope can be seen from elsewhere within that scope, or from within a scope inside that scope, but not from a scope outside that scope. This allows careful management of which code can alter which data. In BSL's case, however, there are certain issues with scope not being respected (see § if). Variables outside of all scopes (including functions) are referred to as "globals".
Comments
Comments are notes from the programmer to explain some code. In BSL, the comment marker is the "#". Any text after that character is not interpreted as BSL. Comments are supposed to be placed after a line of code...
var int a = 4; # here is a trailing comment explaining why 'a' is 4
...or above a line or block of code:
# The following block of code calculates the meaning of life if (...) { ... }
Do not use a trailing comment unless you end the statement with a semicolon (see § Old vs. new syntax for explanation).
In documentation outside of source code or script files, such as this page's BSL samples, comments are sometimes used to tell the reader something in a way that won't break the actual code if the user copies the whole block of text into a script file, comments and all.
Old vs. new syntax
BSL allows two kinds of syntax to be used somewhat interchangeably, one of which is lighter on punctuation requirements. There's the simpler style, called "old style":
dprint "Hello"
and the more strict style, called "new style", which resembles the syntax of the C language:
dprint("Hello");
This dual syntax can make it more complicated to talk about the language, and you can also generate errors if you accidentally mix syntaxes. For instance, if you try to end a function call with a semicolon, but you don't use the new-style parentheses around the function arguments...
dprint "Hello";
...you'll get an error mentioning an "illegal token" (the semicolon) in an "old style" function call. There are also other potential pitfalls with "old style" syntax, such as the fact that trailing comments don't work:
dmsg "Hello" # this comment will disable the line below it a = 4
...and the fact that semicolons are always needed at the end of variable declarations:
# The following line is valid old-style syntax... a = 3 # ...but the following line is not var int a = 3
Thus, it's recommended to consistently use the "new" style of BSL. It requires a bit more typing, but it creates safer and more readable code. For consistency, the rest of the code on this page is written in new-style syntax.
Coding style
There are other aspects of the language which are flexible, and yet not connected to the old-style/new-style division. For instance, the quotes around "Hello" can be left out in both syntax versions of the above calls to dprint() and dmsg(). You can also omit stating the type and parameters of a function, with "void" being assumed in their absence (see § Functions if you need further explanation). You also do not need to use curly braces to enclose code that falls under an if/else statement if there is only a single line of code intended to be in that scope (see § Conditional for examples). None of these syntax choices are in conflict with the "new style" syntax.
Additionally, you can use whitespace and newlines in different ways:
if (counter eq 3) { # do something } else { # do something else }
The above is three lines shorter than the below, but look at the difference in readability with this standard style, used throughout most of Oni's BSL scripts:
if (counter eq 3) { # do something } else { # do something else }
Variables
A variable is a named storage space in memory for a value that you will want to access at different times, and perhaps change over time as well. The name of the variable is expected to start with a letter, but it can contain numbers and the underscore (_
) at any point after that. A variable name cannot be the same as one of BSL's reserved words, e.g. an int named "return", and obviously it cannot share a name with any built-in or declared function either.
Declaring
When declaring a variable, the statement must begin with "var" and the type of the variable:
var int i = 0; # declare a variable named "i" and initialize it to the value zero
You don't have to initialize variables (set them to a value when declaring them), but it's usually a good idea. If you don't initialize, the engine will use a default value: "false" for bools, "0" for ints and floats, and "" (an empty string) for strings.
Accessing
After a variable has been declared, you don't use "var" or the type of the variable when getting or setting its value:
i = 4; if (i eq 0) [...]
Data types
When declaring a variable (more on this under § Variables), you must specify the type of data it contains. When declaring a function (more on this under § Functions), you can optionally specify the type of data it accepts and returns. You can choose from "bool" (can be "true" or "false", but see warning under § bool), "int" (can be any whole number), "float" (a value with a decimal point), or "string" (some text).
var int x; var bool happy_bomber = true; func string my_func(void) { ... }
Upon declaration, variables are automatically initialized to zero if no value is assigned explicitly, as in the above example with "x", or to a blank string in the case of a string variable.
void
See § Functions for the meaning of "void". Variables cannot be of type "void".
bool
(Note: See warning at bottom of this section; the bool type is not recommended for variables.) A Boolean number has one of two possible states. Thus, a bool can be assigned a value with the keywords "true" and "false".
var bool example = true; func bool are_we_there_yet(void) { ... }
Giving a bool any value other than 0 or "false" will set it to 1 or "true". For instance, assigning a float to a bool will make the bool "true" or "1" unless the float value is "0.0", which will become "false". On Macs, you can make reference to bools without any relational operator. The following statements are equivalent in Mac Oni:
if (example) if (example eq true)
However, Windows Oni will fail to evaluate bare references to bool variables, and testing indicates the possibility of other bugs existing in Windows Oni's handling of bools. Additionally, Bungie West uses virtually no bool variables in Oni's scripts (though they do use built-in functions that return bool values). Since ints are handled much more reliably, it's recommended to use int for variables instead of bool; the values 1 and 0 can be used to represent "true" and "false".
int
A 32-bit signed whole number; it can be positive, negative or zero, with a maximum value of 2,147,483,647 and a minimum value of -2,147,483,648.
var int example = -1000; func int get_enemy_count(void) { ... }
Note that the value wraps around, which means that once it passes its maximum or minimum value, it starts over from the other end. For instance, the function...
func void overflow_test(void) { var int overflow = -2147483648; overflow = overflow - 1; }
...will print the positive number "int32: 2147483647" to screen when it runs.
Adding a float or a bool to an int yields odd and very high results, even if the float or bool could in theory be seamlessly converted to an int. Assigning a float to an int correctly assigns the truncated integer to the int. Assigning a bool to an int works correctly, the bool being treated as either 0 or 1.
float
A floating-point number. Bungie West actually never used floats in their scripts for Oni, which explains why there are certain rough aspects to them. For instance, floats are limited to six decimal places of precision:
var float good_example = 10.5; # returns as "10.500000" var float too_precise = 3.141592653589793; # returns as "3.141593"
Thus, adding a value below the sixth decimal place to a float will have no effect, e.g. 3.000000 + 0.0000001 = 3.000000. Additionally, adding an int value (or a bool value) to a float has no effect:
func float test_float_addition(void) { var float add_to_me = 10.5; add_to_me = add_to_me + 1; return add_to_me; # returns "float: 10.500000" }
As opposed to proper float math:
func float float_test(void) { var float add_to_me = 10.5; add_to_me = add_to_me + 1.0; return add_to_me; # returns "float: 11.500000" }
string
A sequence of textual characters. BSL does not have any built-in way of performing the string manipulations that you would expect from a scripting language, such as concatenation and trimming, though see below for a simple trimming hack. It also does not provide a reliable method of string comparison (see HERE for a detailed examination).
var string example = "hello";
Trying to give a string a non-textual value (bool/int/float) gives the error "illegal type convertion" (sic). Trying to add two strings with a '+' operator crashes the game, rather than concatenating them as it would in some other languages. Adding a float to a string crashes too. Bools have no effect whatsoever.
Trying to add an int value to a string creates some cool and unexpected results. For instance, adding a number between 5 and 11 removes the first character from the string. A number greater than or equal to 12 removes the first two, and so on. Subtraction does not yield the reverse effect, even if you try it with the maximum int value (in which case Oni crashes). Subtracting numbers can, however, result in printing random strings from Oni's memory, such as BSL function names!
"(null)" is the value that strings assume when they have not been given a value yet; it cannot be assigned to a string manually.
func string string_test(void) { var string example; return example; # prints "string: (null)" }
Operators
Here are all the operators you can use in BSL.
Assignment
Symbol | Name | Description |
---|---|---|
= | Equals | Sets the variable on the left-hand side to the right-hand value. |
Note that "=" is not for checking if one entity is equal to another (see "eq" under § Relational for that).
Arithmetical
These operations do not change the numbers that the operators act upon; they merely provide a resulting number for your use. Note that there is no operator for multiplication or division. Bungie West was only concerned with creating enough scripting power to drive Oni, and they did not need "higher math" for this. See § Data types to learn the details of how math works between different data types.
Symbol | Name | Description |
---|---|---|
+ | Add | Provides the sum of two numbers. |
- | Subtract | Gives the result of subtracting the second number from the first. |
A quirk of the subtraction operator is that it is sensitive to whitespace. For instance, the following code will print "NOT -1":
if (5-6 eq -1) { dmsg("-1"); } else { dmsg("NOT -1"); # this code will run }
In order for the operator "-" to work correctly, you need to have a space between it and the numbers being subtracted, otherwise it may return unexpected results! So to fix the code above, you should write it like this:
if (5 - 6 eq -1) { dmsg("-1"); # this code will run } else { dmsg("NOT -1"); }
Alternatively you can use the sum operator, which doesn't suffer from this issue:
if (5+-6 eq -1) { dmsg("-1"); # this code will run } else { dmsg("NOT -1"); }
Relational
These operators return true/false values for use in "if" statements.
Symbol | Name | Description |
---|---|---|
eq | Equal to | Tests if two values are equal. |
ne | Not equal to | Tests if two values are different. |
> | Greater than | Tests if first number is greater than second one. |
< | Less than | Tests if first number is smaller than second one. |
>= | Greater than or equal to | Tests if a number is greater than, or equal to, another. |
<= | Less than or equal to | Tests if a number is smaller than, or equal to, another. |
Note: These operators are intended for use with numbers; strings cannot make reliable use of comparators, as explained under § string.
Logical
Symbol | Name | Description |
---|---|---|
! | Not | Logical Not. Reverses the result of a test. |
and | And | Logical And. |
or | Or | Logical Or. |
To illustrate the '!' ("not") operator, the following three lines are equivalent:
!(some_bool eq true) some_bool eq false some_bool ne true
See § if for detailed examples of using the logical operators.
Reserved words
Here are the keywords that have special meaning in BSL. If you attempt to use these words as names for variables or functions, you will confuse the BSL parser and your script will fail.
Declaration
Before using a variable for the first time, you need to declare it with the "var" keyword. Function definitions must start with the "func" keyword.
var
var int a = 0;
After this, you refer to the variable merely as "a". See § Variables for details on declaring variables.
func
func void spawn_team(void) { ... }
After this, you call the function merely by writing its name; "spawn_team" would work, but the proper new-style syntax is "spawn_team();". See § Functions for details on declaring functions.
Type specification
When declaring a variable or defining a function, you need to state the type of data that is contained in that variable or that is returned by the function.
void, bool, int, float, string
var int a = 0; func int spawn_team(int flag) { ... }
Besides "void", which is only used in function definitions (indicating that no data is returned), these are the types of data that can be assigned to variables, passed into functions, and returned by functions. See § Data types for details.
Conditional
if
The only conditional statement in BSL is "if", with optional follow-up statements "else if" and "else", discussed below.
if (a operator b) { # ... }
For examples of operators, see § Operators. A typical example would be:
if (kills < 10)
The result of the operation within the parentheses will always boil down to either "true" or "false" (a "yes" or a "no"), even if you would think that the result would be a number. For instance:
if (8 - 8) # evaluates as false because 8 minus 8 is zero if (8 - 7) # evaluates as true because 8 minus 7 is non-zero
Braces are optional when you only have one line of code under the "if" (this is also true for "else" and "else if", discussed below):
if (a > 0) spawn_enemy_at_flag(a); spawn_considered = 1;
Here, "spawn_considered" will be set to 1 regardless of whether the "if" condition was true and spawn_enemy_at_flag() was run. (The indentation has no effect on how the code runs; it's simply to guide the reader.) Though it's nice to save the vertical space by omitting the braces, the danger is in writing something like this:
if (a > 0) spawn_enemy_at_flag(a); spawn_considered = 1;
That indentation on "spawn_considered" is misleading; when glancing at this code, you might expect that "spawn_considered" only is changed if "a" is greater than zero. It could be the script's writer really did want that line to be subject to the "if" statement, but he forgot to add braces. Always using braces around an "if" statement's body, even when it's one line long, will prevent that mistake.
Unfortunately, even with braces, BSL does not always respect scope for blocks of code under "if" statements; for instance, a "return" statement will fire even when the surrounding "if" condition is false (see § Flow interrupt for an example). An even more alarming example of bad scoping is this:
func void broken_if(void) { var int one = 1; var int two = 2; var int one_equals_two = 0; if (one eq two) # this condition will evaluate to false, but... one_equals_two = 1; # ...this will still run if (one_equals_two eq 1) dprint("Uh-oh."); else dprint("Phew."); }
Bungie West was aware of this bug, and avoided it by never setting variables under "if" statements. However, you can safely do so as long as you use a global variable. For some reason, assigning a global variable under an "if" will not fire out of scope:
var int one_equals_two = 0; func void fixed_if(void) { var int one = 1; var int two = 2; if (one eq two) one_equals_two = 1; if (one_equals_two eq 1) dprint("Uh-oh."); else dprint("Phew."); }
One very handy feature that you won't see used in Oni's game scripts is that the logical operators "and" and "or" can string together multiple conditions:
if ((a < b) and (c > d)) { # ... }
Another unused feature of BSL is that you can express the opposite of some condition by using the "!" operator (pronounced "not"). The following two statements have the same meaning:
if (!(one_equals_two eq 1)) if (one_equals_two eq 0)
else
When an "if" statement evaluates as false, you can use "else" to perform an alternate action:
var int one = 1; var int two = 2; if (one eq two) { # these commands will not run } else { # these are the commands that will run }
Though "else" is not used in Oni's existing BSL scripts, it seems to work fine.
else if
As is common in other programming languages, you can also specify an "if" condition that should only be evaluated if the previous condition was false, by writing "else if":
if (error eq 0) dprint("Everything is fine."); else if (error eq 1) dprint("There are too many enemies to add one more."); else # handle all other possibilities dprint("Unknown error code!");
Programmers commonly use "else if" statements to save some CPU cycles. For instance, if you had a long string of "if" statements to handle different possible values for a variable, why should they all be evaluated once you have already found the one that is true? Imagine the above example, but with 30 possible values for "error". In reality, you won't find much benefit in trying to save cycles with BSL since typical game scripts are not computationally expensive. However, "else if" can also simplify the flow of logic:
if (d eq 10) # special-case code for d being 10 if ((d ne 10) and (d eq 3)) # special-case code for d being 3 if ((d ne 10) and (d ne 3) and (d > 0)) # code for handling any other positive value for d
In checking the condition of "d" in this example, we have to keep checking after the first statement whether our previous conditions were not true; if we didn't, multiple "if" statements could evaluate to true and execute their code, and we only want to act on one of these possible situations. Using "else if" allows us to be confident that only one statement can run:
if (d eq 10) # special-case code for d being 10 else if (d eq 3) # special-case code for d being 3 else if (d > 0) # code for handling any other positive value for d
Thanks to the "else" keyword, "d" is implicitly guaranteed to not be 10 if statement 2's code is being run, and to not be 10 or 3 if statement 3's code is being run.
Flow interrupt
Use the keywords below to interrupt the execution of BSL. Note that Bungie West also frequently used these built-in commands to halt the execution of a script until the current or previous command finished: chr_animate_block, chr_envanim_block, chr_playback_block, cm_anim_block, cm_interpolate_block, cm_orbit_block, env_anim_block, env_setanim_block, sound_dialog_play_block.
return
On its own, "return" exits the function early. You can also place a variable or constant after the keyword to pass that value back to a calling function. The fact that "return" is not used in Oni's scripts might explain this bug:
var int one = 1; var int two = 2; if (one eq two) { return; # this could not possibly be reached... or could it? } else { # this code should run, right? }
Yes, "return" is also subject to the scope bug discussed under § Conditional. The statements under "else" will never run. The "return" will actually kick in and the function will exit, even though the surrounding control statement did not evaluate to true.
However, "return" is still useful at the end of a function for returning data to the function that called that one; see § Returning.
sleep
You can also delay execution of a script using "sleep", passing it a number in sixtieths of a second. This keyword was heavily used by Bungie West and could be considered their primary method of executing events with the right timing. Its usage is simple:
sleep(60); # pause execution of BSL at this point for one second
In Oni's level scripts, you will often see a call to "sleep" with an 'f' preceding the sixtieths of a second like this: "sleep(f60)". There is no change in functionality when using this character (it may be a relic of an earlier version of "sleep"), so you can leave it out.
Note that you cannot have a sleep statement in a function that returns a value, probably to avoid variables being changed at unexpected times.
Loop
It is generally desirable in any program to be able to run the same code over and over, such as repeatedly spawning enemies. This is one of BSL's biggest limitations, as it has no conventional loop statement like C's "for" or "while", but there are two indirect methods for looping: (1) use "fork" on a function (see § Looping), and (2) "schedule-at"/"schedule-repeat-every" (see § Concurrency).
Multi-threading
fork, schedule-at, schedule-repeat-every
See § Concurrency for the use of these keywords.
Obsolete
iterate over ... using ...
An unfinished feature, "iterate" was going to utilize "iterator variables", but these don't exist.
for
Bungie West may have once intended to create a C-like "for loop", but this keyword doesn't do anything.
Functions
A function is a block of code that can be accessed repeatedly whenever you want to perform a certain task. As in mathematics, functions can be passed input and can return output, though unlike in mathematics, they do not need to do either of those things in order to be useful, as BSL functions can affect external data by modifying global variables and by calling built-in functions which affect the game environment (see § Built-in commands).
Defining
When beginning to define a function, you must start the line with "func"...
func int prepare_fight(int count, string enemy_name) { ... }
This line is known as the function signature. The type of the function comes after the "func" keyword, in this case "int", which means it can return a value of type "int". The input which the function accepts is listed between the parentheses and separated by commas. First the type of the input is given ("int" in the first case), then the name of that input is given; this name will be used within the function to refer to that input but has no meaning outside of it. These inputs are known as "parameters" or "arguments". BSL functions cannot accept more than eight parameters.
void
Functions do not need to accept or return data. When they don't, you use "void" to indicate this. Note that both "void"s can be omitted and will be assumed implicitly.
func void func_start(string ai_name) # returns nothing to calling function, but accepts a string { ... }
func void music_force_stop(void) # neither returns nor accepts any data { ... }
func music_force_stop # same signature as previous function { ... }
Calling
When you call a function it will execute its statements from top to bottom or until it hits a "return" statement. This means that when you call a second function from inside another function, the second function will be executed until its end and then the rest of the first function will be executed. You can think of the function calls as nested parentheses, where the innermost statement must close before the next-innermost level can close, and so on. (For example, here is a parenthetical statement (and another one (and one more!) inside of it)).
You do not use "func" when calling a function. You simply use its name:
music_force_stop();
Since no parameters are expected by music_force_stop(), we call it with empty parentheses. However, if parameters are expected, it looks like this:
prepare_fight(3, "Jojo");
In this case, we are passing a constant value of three into prepare_fight() (the function defined at the start of this section), inside of which it will be known as "count", and we are passing a constant string in as "enemy_name", but we could also have passed in variables by name:
var int num_heroes = 3; var string enemy = "Jojo"; prepare_fight(num_heroes, enemy);
The values of these variables will still be referred to as "count" and "enemy_name" inside prepare_fight().
Recursive calling
A function can call itself by invoking its own name:
var int global_iterator = 0; func void bad_loop_idea(void) { global_iterator = global_iterator + 1 dmsg("Calling myself..."); bad_loop_idea(); }
This might seem useful for producing a loop, but a function can only call itself recursively about four times before you hit a limit in BSL and the script fails silently. Open a level with the above code placed in its level script and call bad_loop_idea() from the dev console. After you stop seeing the "Calling myself..." messages, run the command "global_iterator" to query its value and you'll probably get "5", meaning the recursion failed between the fourth and fifth levels.
This limit can be bypassed if you use "fork" when calling a function from within itself, though this is not technically recursing: the logic will not complete in a predictable inside-to-outside order like our nested parentheses example in the previous section; instead it will run concurrently through all of the forked function calls. This can be very bad if you're trying to get reliable results, however there are ways to mitigate this. For a discussion of looping reliably with "fork", see § Looping.
Returning
As mentioned under § Flow interrupt, "return" allows you to exit the function at that point. But because of the bug documented in that section you cannot use "return" conditionally, that is, exit early from a function depending on some logical condition ("if"). Since "return" can thus only be placed at the end of a function, there is no need to use it at all unless you are passing back a value with it like so:
func int add_ten(int input) { var int the_result = input + 10; return(the_result); }
When a function returns a value, you can use the function to set a variable as follows:
some_number = add_ten(enemy_count);
Function return values can also be used in "if" statements. If you have a function that returns a bool...
func bool is_it_safe(void) { var bool result = false; # do some investigation here and set result to true if it is safe return(result); }
...then it could be called this way in some other function:
if (is_it_safe() eq true) dprint("It is safe."); else dprint("It is not safe.");
Bizarre bug warning: Calling dprint() and dmsg() more than once within a function will produce unexpected results. One of the dprint()/dmsg() calls may become the return value for the function (even if it it's type "void"), or create a return value of 0, and more than two calls also might be ignored.
Looping
The following function creates a loop using "fork".
var int counter; func void increment_counter_to(int limit) { counter = 0; fork increment(limit); } func void increment(int limit) { counter = counter + 1; if (counter < limit) fork increment(limit); }
Note that calling the same function again before it finishes running the first time can have undesired effects. Imagine if you have another thread in the code accessing "counter" while increment() is still running in a loop; what value will it have at that moment? Real-world scripting scenarios will be more complex and thus more problematic if multiple concurrent calls to a function are in play at the same time. Using "sleep" before each fork call can prevent this overlapping execution. A short function like the example above should not need a "sleep" statement as the remainder of the function after the "fork" call will complete in the same tick. But the more complex the function, the more ticks you will need to allow for it to complete, requiring "sleep(1);", "sleep(3);", etc. before the "fork" call.
An alternate looping method: See the two variants of the "schedule" keyword under "Concurrency" below.
Concurrency
When you call a function, all the code inside that function will finish running before giving control back to the calling function; that is, unless you use one of the following keyword sets to run parallel "threads" of BSL at the same time. Unlike robust programming languages, there is very little control over BSL's version of "multi-threading", so see the caveats at the end of the "fork" section.
fork
If you call a function with "fork" before its name, the code below the function call continues without waiting for the function to return. If you place this sample code in a script and enter "fork_test" on the dev console, you will immediately see the output "int: 3" even though wait_for_a_second() was called before the value of "enemies" was printed to screen. You can remove the "fork" keyword to see the difference.
func void fork_test(void) { var int counter = 0; fork wait_for_a_second(); var int enemies = count_enemies(); enemies; } func int count_enemies(void) { return(3); } func void wait_for_a_second(void) { sleep(60); dprint("Done waiting."); }
As you can see, fork-called functions can delay actions within themselves without holding up the rest of the script; this not only allows the use of "sleep" without affecting outside functions, but also any built-in functions that hold up BSL by design, like chr_wait_animation.
Be aware that accidentally calling a nonexistent function using "fork" will crash Oni; when "fork" is not used, BSL will successfully recognize it as an unknown function and thus will not attempt to call it.
schedule ... at ...
Allows you to schedule a function call a certain number of ticks in the future. Unused in Oni's scripts, but here's a working example:
schedule dmsg("BOOM") at 300; schedule dmsg("1...") at 240; schedule dmsg("2...") at 180; schedule dmsg("3...") at 120; schedule dmsg("4...") at 60; dmsg("5...");
You are not allowed to set a variable to the return value of a scheduled function call, just like you cannot use "sleep" in a function that returns a value. This is presumably to avoid unpredictable changes being made to variables that share scope with other code.
schedule ... repeat ... every ...
Allows you to schedule a function call to repeat x times at a rate of y ticks. Unused in Oni's scripts, but here's a working example:
schedule dprint("Is this annoying yet?") repeat 50 every 20;
This is equivalent to the following loop in a C-style language:
int i = 0; do { print("Is this annoying yet?"); wait(20); i++; } while (i != 50);
To create an infinite loop, you can use "0" or a negative number as the repeat value:
schedule dprint("Is this annoying yet?") repeat 0 every 20; # repeats forever
"schedule-repeat-every" can be used in place of recursive functions that call themselves n times using "fork". For example…
func void hey(void) { dmsg("hey"); sleep(60); fork hey(); } func void main(void) { fork hey(); }
…can be replaced by…
func void hey(void) { dmsg("hey"); } schedule hey() repeat 0 every 60;