Difference between revisions of "Introduction to OBSE arrays"
imported>8asrun6aer m (Just displaying the toc for easier navigation) |
imported>QQuix m (→Declaring and initializing arrays: Formatting has been messed up. Fixed.) |
||
Line 168: | Line 168: | ||
1. Explicitly initializing it using ar_Construct | 1. Explicitly initializing it using ar_Construct | ||
::When initializing an array with ar_Construct, the type of array must be provided as the argument: | ::When initializing an array with ar_Construct, the type of array must be provided as the argument: | ||
:::let MyArray := ar_Construct array | |||
:::let MyArray := ar_Construct map | |||
:::let MyArray := ar_Construct stringmap | |||
2. Assigning the value of another array_var to it | 2. Assigning the value of another array_var to it | ||
:: In this case MyArray will be of the same type of SomeArray (actually, both refer to the same array) | :: In this case MyArray will be of the same type of SomeArray (actually, both refer to the same array) | ||
:::let SomeArray := ar_Construct array | |||
:::Let MyArray := SomeArray | |||
3. Assigning it the return value of a command returning an array such as GetItems. | 3. Assigning it the return value of a command returning an array such as GetItems. | ||
::Let MyArray := GetItems | |||
==Populating arrays== | ==Populating arrays== |
Revision as of 05:49, 29 December 2013
Foreword
This article presents the basics of OBSE arrays. Much of the text comes straight from the OBSE docs.
Arrays
An array is a collection of related information put together in a list-like structure.
Being a list, an array may hold many values, as opposed to regular script variables that hold only one information.
Some examples of everyday lists that could be stored in arrays:
Shopping list | Agenda | Personal data |
---|---|---|
- Bread | 08:30 - Sign in, Coffe | Name: Adoring Fan |
- Butter | 09:00 - Introduction | Date of birth: Morningstar 2, 415 |
- Milk | 09:30 - Presentation A | Age: 19 |
- Eggs | 10:30 - Coffe break | Address: Arena District, IC |
11:00 - Presentation B | Race: Wood Elf | |
ReferenceID: ArenaFan1ref |
Array keys and values
Each element of the array is composed of a Key and a Value.
- Key
- The Key identifies the element and must be unique within an array.
- An array key may be a number or a string, but all the keys in an array must be of the same type.
- Arrays are ordered by key, in ascending order.
- The key is represented within brackets, e.g., MyArray[0].
- Value
- Value is the information stored in the array element.
- The value may be of any type: a string, a number, a FormID (base object or reference) or another array.
- Any mix of value types may be stored in the same array.
Array types
There are three types of arrays, depending on the key used: Array, Map or StringMap.
Array
The "Array" type of array uses integers as keys.
The first element must have key = 0 and subsequent keys must be the next integer: 1, 2, 3, 4 etc.
There must be no gaps in the key sequence.
If an element is inserted or removed from the array, the keys are renumbered to comply with the above rules.
The Shopping List example would look like this when stored in an Array
Key | Value |
---|---|
0 | Bread |
1 | Butter |
2 | Milk |
3 | Eggs |
-
Quote from the OBSE doc:
- 1. Array: An Array behaves like arrays in most programming languages: the key is an unsigned integer starting at zero, and there are no gaps between elements. (In other words, if an element exists at indexes 1 and 3 then an element necessarily exists at 0 and 2). Attempting to access an element using a key which is greater than the highest key in the array results in an error. The only exception to this rule is during assignment: it is okay to assign a value to the key which is one greater than the highest key in the array.
Map
The Map array uses numbers as keys.
Keys may be any number, including negative and floating point numbers
The Agenda example would look like this when stored in a Map array:
Key | Value |
---|---|
8.5 | Sign in, Coffe |
9.0 | Introduction |
9.5 | Presentation A |
10.5 | Coffe break |
11.0 | Presentation B |
-
Quote from the OBSE doc:
- 2. Map: A Map associates numeric keys with values. Unlike an Array, a Map allows negative and floating point numbers to be used as keys and allows gaps to exist between elements.
StringMap
The StringMap array uses strings as keys.
The Personal Data example would look like this when stored in an StringMap array:
Key | Value | Value Type |
---|---|---|
Name | Adoring Fan | String |
Date of birth | Morningstar 2, 415 | String |
Age | 19 | Float |
Address | Arena District, IC | String |
Race | Wood Elf | Ref |
ReferenceID | ArenaFan1ref | Ref |
- Note: Although only this last example has a mixture of value types, arrays of ANY type may have mixed value types.
-
Quote from the OBSE doc:
- 3. StringMap: Like a Map, except the keys are strings. Keys are case-insensitive, so array[INDEX] and array[index] both refer to the same value. There is no practical limit on the length of the strings used as keys. StringMaps can be used to simulate C-style structs by associating named properties with data values.
Declaring and initializing arrays
Arrays must be declared as an array_var variable, e.g., "array_var MyArray"
An array_var must be initialized before it can be used in expressions, either by
1. Explicitly initializing it using ar_Construct
- When initializing an array with ar_Construct, the type of array must be provided as the argument:
- let MyArray := ar_Construct array
- let MyArray := ar_Construct map
- let MyArray := ar_Construct stringmap
- When initializing an array with ar_Construct, the type of array must be provided as the argument:
2. Assigning the value of another array_var to it
- In this case MyArray will be of the same type of SomeArray (actually, both refer to the same array)
- let SomeArray := ar_Construct array
- Let MyArray := SomeArray
- In this case MyArray will be of the same type of SomeArray (actually, both refer to the same array)
3. Assigning it the return value of a command returning an array such as GetItems.
- Let MyArray := GetItems
Populating arrays
Arrays are populated by assigning values to its elements.
An array element is identified by the array name followed by the element key within brackets.
The keys, of course, must comply with the type of array:
- let MyArray := ar_Construct array Let MyArray[0] := 123 Let MyArray[1] := 456 Let MyArray[2] := 789
- let MyArray := ar_Construct map Let MyArray[-1.5] := 123 Let MyArray[2.5] := 456 Let MyArray[3] := 789
- let MyArray := ar_Construct stringmap Let MyArray["Cost"] := 123 Let MyArray["Qty"] := 456 Let MyArray["Taxes"] := 789
Accessing array elements
Using the data stored in arrays usually requires that you copy the information into a 'normal' script variable because array elements cannot be passed directly to most commands as arguments.
The Let statement is array-aware and is the most common way of accessing array elements
- float MyFloat . . . Let MyFloat := MyArray["PosX"] Player.setpos x MyFloat
- ref MyRef . . . Let MyRef := MyArray["ReferenceID"] MyRef.Kill
- string_var MyString . . . Let MyString := MyArray[3.7] MessageBoxEX "The element text is: %z" MyString
In all examples up to here, keys were explicitly coded, but they may also be in a variable and the variable itself going within the brackets:
- string_var MyString . . . Let MyString := "Item value" Let MyArray[MyString] := 300
- short MyShort . . . Let MyShort := 3 Let MyArray[MyShort] := "Text"
Which is very handy to . . .
Walking an array
Walking an array means going over each element of the array, one at a time.
OBSE provides functions to do exactly that: ForEach and While loops
ForEach
ForEach loops iterate over the elements of an array.
- array_var item short MyShort string_var MyString . . . ForEach item <- MyArray Let MyShort := item["key"] Let MyString := item["value"] MessageEX "The element %g is: %z" MyShort MyString Loop
At each iteration, "item" is initialized with two elements:
- "key", which holds the key of the current element
- "value", which holds the value associated with that key
Therefore, as in the example above, within a ForEach loop you can access both fields via item["key"] and item["value"].
NOTE: In the example, the key is copied to a Short, which implies that MyArray is either an Array or a Map that has only integers as keys.
While
While loops are handy for handling Arrays because the keys are known in advance and are consecutive (0,1,2,3, ...)
The same example as above using a While loop:
- short MyIndex string_var MyString . . . Let MyIndex := 0 While MyIndex < ar_size MyArray Let MyString := MyArray[MyIndex] MessageEX "The element %g is: %z" MyIndex MyString MyIndex += 1 Loop
Notice that with while loops, you have to increase the index yourself, as opposed to ForEach loops that automatically go to the next element.
A somewhat different (perhaps more elegant) way of increasing the index
- short MyIndex string_var MyString . . . Let MyIndex := -1 While (MyIndex += 1) < ar_size MyArray Let MyString := MyArray[MyIndex] MessageEX "The element %g is: %z" MyIndex MyString Loop
While loops also allows for walking Arrays backward:
- short MyIndex string_var MyString . . . Let MyIndex := ar_size MyArray While (MyIndex -= 1) >= 0 Let MyString := MyArray[MyIndex] MessageEX "The element %g is: %z" MyIndex MyString Loop
Some final, miscellaneous notes
- All elements within an array must have the same type of key.
- References cannot be used as array keys.
- An array can contain any mix of types for its values.
- As array elements may contain any type of data, it is the script responsibility to know which is which, so you don't try to assign a string to a ref variable.
- OBSE keeps track of the number of references to each array and destroys the array when no references to it remain. This makes it unnecessary for scripts to worry about destroying arrays explicitly.
- ForEach and While loops both define structured blocks in the same way that If and Endif or Begin and End do. Every While or ForEach in a script must be matched by exactly one Loop command.
- Category:Array Functions (OBSE) has a list of OBSE array functions.