OOP Introduction: Difference between revisions
No edit summary |
|||
(18 intermediate revisions by 8 users not shown) | |||
Line 1: | Line 1: | ||
{{ | {{Note|If you've contributed by editing and tweaking this forum page, if you've benefited from this tutorial, or if you have anything to say; please give me feedback in the forum link provided below.}} | ||
This is a scripting tutorial explaining to you what object orientated programming is and teaching you how to use the OOP features of MTA. This was originally created by [[User:Qais|qaisjp]] ([[User talk:Qais|talk]]) 22:48, 8 June 2014 (UTC). [http://forum.mtasa.com/viewtopic.php?f=148&t=76388 Forum post.] | This is a scripting tutorial explaining to you what object orientated programming is and teaching you how to use the OOP features of MTA. This was originally created by [[User:Qais|qaisjp]] ([[User talk:Qais|talk]]) 22:48, 8 June 2014 (UTC). [http://forum.mtasa.com/viewtopic.php?f=148&t=76388 Forum post.] | ||
Line 15: | Line 15: | ||
More often than not, you know what you're dealing with. The variable almost always links back to the type, you would name a vehicle that exploded as '''explodedVehicle''', or at-least in context you would understand that '''exploded''' implies a vehicle when in the '''onVehicleExplode''' event. So you have to write a long function ''and'' refer to the vehicle manually when working procedurally. Painful. Object orientated programming is very different to this and works with each "object" individually. Instead of having to call a function and referencing it inside the call, you actually call the function INSIDE the class. | More often than not, you know what you're dealing with. The variable almost always links back to the type, you would name a vehicle that exploded as '''explodedVehicle''', or at-least in context you would understand that '''exploded''' implies a vehicle when in the '''onVehicleExplode''' event. So you have to write a long function ''and'' refer to the vehicle manually when working procedurally. Painful. Object orientated programming is very different to this and works with each "object" individually. Instead of having to call a function and referencing it inside the call, you actually call the function INSIDE the class. | ||
You probably think everything you can create and pass to functions are elements. A vehicle is an element. A player is an element. Anything that is an element is also a class. Connections create an instance of a class, but "'''connection'''" isn't an element, it's an instance - an object. Throughout the tutorial when I say ''object'', I don't mean [[createObject]] (unless I actually mention it, but to make things clearer I will avoid mentioning physical objects as I write this article. Here is a fancy venn diagram I created to show the simple organisation of classes and elements. | You probably think everything you can create and pass to functions are elements. A vehicle is an element. A player is an element. Anything that is an element is also a class. Connections create an instance of a class, but "'''connection'''" isn't an element, it's an instance - an object. Throughout the tutorial when I say ''object'', I don't mean [[createObject]] (unless I actually mention it), but to make things clearer I will avoid mentioning physical objects as I write this article. Here is a fancy venn diagram I created to show the simple organisation of classes and elements. | ||
[[File:Classes,_Elements_and_Problem_children.png|500px|left|venn diagram]] | [[File:Classes,_Elements_and_Problem_children.png|500px|left|venn diagram]] | ||
The functions on the left are sorted to show what kind of category the returned value rests in. We've got Classes, Elements and "Problem children". | The functions on the left are sorted to show what kind of category the returned value rests in. We've got Classes, Elements and "Problem children". | ||
Line 22: | Line 22: | ||
Problem children are weird things. You can't do all the functions mentioned in (actually, all elements don't allow the full assortment of functions to be applied to them, but I've especially mentioned a few of them) in the "Element functions" section of the functions list, but you can do destroyElement() on them. | Problem children are weird things. You can't do all the functions mentioned in (actually, all elements don't allow the full assortment of functions to be applied to them, but I've especially mentioned a few of them) in the "Element functions" section of the functions list, but you can do destroyElement() on them. | ||
There are children of classes, for example, with players, the system goes like: ''Element -> Ped -> Player". All Players are Peds and all Peds are Elements. Not all Peds are Players, and certainly not all Elements are Players. The main point here is that almost everything that you can create or retrieve and then reuse later use a class. | There are children of classes, for example, with players, the system goes like: "''Element -> Ped -> Player''". All Players are Peds and all Peds are Elements. Not all Peds are Players, and certainly not all Elements are Players. The main point here is that almost everything that you can create or retrieve and then reuse later use a class. | ||
Instead of the code before, the code could be replaced with this: | Instead of the code before, the code could be replaced with this: | ||
<syntaxhighlight lang="lua"> | <syntaxhighlight lang="lua"> | ||
local vehicle = | local vehicle = Vehicle(411, 0, 0, 3) | ||
vehicle:setDamageProof(true) | vehicle:setDamageProof(true) | ||
vehicle:setFrozen(true) | vehicle:setFrozen(true) | ||
Line 36: | Line 36: | ||
Those functions are pretty useful, but there are more changes with OOP, I'll explain this below. | Those functions are pretty useful, but there are more changes with OOP, I'll explain this below. | ||
== Instantiation, variables == | == Instantiation, variables == | ||
OOP removes the need to say the "create" part of the function, so instead of saying '''createVehicle''', you just say '''Vehicle'''. It works exactly the same way, it's almost just like doing '''Vehicle = createVehicle'''. Fancy, isn't it? The only difference here is that you miss out on the extra things offered, Vehicle doesn't have these extra things, but Player definitely does. For example, instead of doing getPlayerFromName(), you would do Player.getFromName(). It's a nice and simple way to organise functions. | OOP removes the need to say the "create" part of the function, so instead of saying '''createVehicle''', you just say '''Vehicle'''. It works exactly the same way, it's almost just like doing '''Vehicle = createVehicle'''. Fancy, isn't it? The only difference here is that you miss out on the extra things offered, Vehicle doesn't have these extra things, but Player definitely does. For example, instead of doing getPlayerFromName(), you would do Player.getFromName(). It's a nice and simple way to organise functions. | ||
{{Tip|''Vehicle()'' works because it actually accesses the '''Vehicle.create''' function, this allows you to omit the '''.create''' when simply "creating an object"}} | |||
Since OOP sits on top of procedural, many things have been inherited from the style of procedural, but to make things easier we have variables for all the functions that require a single input. We've shortened '''getElementDimension()''' down to '''element:getDimension()''', but we can also go one layer deeper: '''element.dimension'''. Yep, just like a variable. You can set this variable just like a normal variable and read from it just like a normal variable. Hey, you could even do this: | Since OOP sits on top of procedural, many things have been inherited from the style of procedural, but to make things easier we have variables for all the functions that require a single input. We've shortened '''getElementDimension()''' down to '''element:getDimension()''', but we can also go one layer deeper: '''element.dimension'''. Yep, just like a variable. You can set this variable just like a normal variable and read from it just like a normal variable. Hey, you could even do this: | ||
<syntaxhighlight lang="lua">local function incrementDimension() | <syntaxhighlight lang="lua">local function incrementDimension() | ||
Line 50: | Line 45: | ||
player.dimension = player.dimension + 1 -- increment dimension | player.dimension = player.dimension + 1 -- increment dimension | ||
end | end | ||
Timer(incrementDimension, 60*1000, 10) -- set a timer for sixty thousand milliseconds, sixty seconds, one minute | |||
</syntaxhighlight> | </syntaxhighlight> | ||
This code would take a random player and move them to the next dimension every minute for the next ten minutes. | This code would take a random player and move them to the next dimension every minute for the next ten minutes. | ||
Line 66: | Line 61: | ||
</syntaxhighlight> | </syntaxhighlight> | ||
Yes, I used the negative sign. Vectors aren't just fancy ways for positions or 3d rotations or whatever, you can use maths on them. The '' | Yes, I used the negative sign. Vectors aren't just fancy ways for positions or 3d rotations or whatever, you can use maths on them. The ''special'' maths hasn't been documented yet, but I'll try and work on that. So, as you can see in line one, I created a 3D vector at ''300, -200, 2'' and then in line two I created the vehicle at that position. | ||
'''vehicle.position''' returned a vector and also takes a vector - it is pretty much setElementPosition() without the "()". Just a simple variable; so, in line three, I changed the vector value of the position of the vehicle. This is where the maths happened, in simple terms this is what is going on: | '''vehicle.position''' returned a vector and also takes a vector - it is pretty much setElementPosition() without the "()". Just a simple variable; so, in line three, I changed the vector value of the position of the vehicle. This is where the maths happened, in simple terms this is what is going on: | ||
<syntaxhighlight lang="lua"> | <syntaxhighlight lang="lua"> | ||
x = 300 - 300 | x = 300 - 300 | ||
y = -200 - -200 | y = -200 - -200 | ||
z = 2 - 0 | |||
</syntaxhighlight> | </syntaxhighlight> | ||
Vector maths is slightly complicated but it definitely allows for a wide variety of mathematical magic. Check out the useful links below related to Vectors and Matrices (Matrices = plural form of Matrix) to understand more about how this works. | Vector maths is slightly complicated but it definitely allows for a wide variety of mathematical magic. Check out the useful links below related to Vectors and Matrices (Matrices = plural form of Matrix) to understand more about how this works. | ||
== Understanding the documentation== | |||
The documentation for the OOP syntax intends to be very simplistic and is supported by the procedural syntax. To keep things simple, everything is consistently formatted in a certain way. | |||
<section name="Example" class="generic" show="true"> | |||
{{OOP|Set the variable to nil to execute [[removePedFromVehicle]]|[[ped]]:warpIntoVehicle|vehicle|getPedOccupiedVehicle}} | |||
</section> | |||
* Sometimes a note is added to the page. This will explain any special differences in the use of OOP for that function. | |||
* Methods can either start like ''[[player]]:'' or ''[[Player]].'' - the former is only for a function on an instance (setPlayerHealth) and the latter is a static method (getRandomPlayer). | |||
* The counterpart section this allows you to see at a glance how the variable can be used. In most cases this can be inferred from the function page. | |||
If you are a contributor to the wiki, please also consider reading [[Template:OOP|the OOP template]]. | |||
== Useful links == | == Useful links == | ||
Other useful OOP related | Other useful OOP related pages: | ||
* [[ | * [[OOP]] | ||
* [[ | * [[Vector]] | ||
* [[Matrix]] | |||
[[Category:OOP]] | |||
[[Category:Incomplete]] | [[Category:Incomplete]] | ||
[[Category:Tutorials]] | [[Category:Tutorials]] | ||
[[hu:OOP Introduction]] | |||
[[zh-cn:OOP介绍]] |
Latest revision as of 05:52, 6 November 2023
This is a scripting tutorial explaining to you what object orientated programming is and teaching you how to use the OOP features of MTA. This was originally created by qaisjp (talk) 22:48, 8 June 2014 (UTC). Forum post.
Introduction to OOP
OOP stands for object orientated programming. Three simple words, and you'll probably understand the last word the most. OOP is where all functions relating to a single instance are called on that instance, an instance being a creation of a class - an element class, a database class, a player, a vehicle. Originally, everything was procedural, you had to do things like:
local vehicle = createVehicle(411, 0, 0, 3) setVehicleDamageProof(vehicle, true) setElementFrozen(vehicle, true) setElementHealth(vehicle, 1000) setElementVelocity(vehicle, 0.2, 0.2, 0.2) destroyElement(vehicle)
More often than not, you know what you're dealing with. The variable almost always links back to the type, you would name a vehicle that exploded as explodedVehicle, or at-least in context you would understand that exploded implies a vehicle when in the onVehicleExplode event. So you have to write a long function and refer to the vehicle manually when working procedurally. Painful. Object orientated programming is very different to this and works with each "object" individually. Instead of having to call a function and referencing it inside the call, you actually call the function INSIDE the class.
You probably think everything you can create and pass to functions are elements. A vehicle is an element. A player is an element. Anything that is an element is also a class. Connections create an instance of a class, but "connection" isn't an element, it's an instance - an object. Throughout the tutorial when I say object, I don't mean createObject (unless I actually mention it), but to make things clearer I will avoid mentioning physical objects as I write this article. Here is a fancy venn diagram I created to show the simple organisation of classes and elements.
The functions on the left are sorted to show what kind of category the returned value rests in. We've got Classes, Elements and "Problem children". Problem children aren't real categories written in the code, just functions that break rules. Everything you can play with are classes: resources, vehicles, and teams.
All elements are classes, you can do:
destroyElement(ped)
but you can't do:
destroyElement(resource)
Problem children are weird things. You can't do all the functions mentioned in (actually, all elements don't allow the full assortment of functions to be applied to them, but I've especially mentioned a few of them) in the "Element functions" section of the functions list, but you can do destroyElement() on them. There are children of classes, for example, with players, the system goes like: "Element -> Ped -> Player". All Players are Peds and all Peds are Elements. Not all Peds are Players, and certainly not all Elements are Players. The main point here is that almost everything that you can create or retrieve and then reuse later use a class.
Instead of the code before, the code could be replaced with this:
local vehicle = Vehicle(411, 0, 0, 3) vehicle:setDamageProof(true) vehicle:setFrozen(true) vehicle:setHealth(1000) vehicle:setVelocity(0.2, 0.2, 0.2) vehicle:destroy()
It works pretty similar to how a table works, it's just like customTable.setSomething() except the use of : makes Lua convert customTable:setSomething() convert to customTable.setSomething(customTable). This is pretty internal stuff about syntactic sugar and you don't really need to worry much about it.
Those functions are pretty useful, but there are more changes with OOP, I'll explain this below.
Instantiation, variables
OOP removes the need to say the "create" part of the function, so instead of saying createVehicle, you just say Vehicle. It works exactly the same way, it's almost just like doing Vehicle = createVehicle. Fancy, isn't it? The only difference here is that you miss out on the extra things offered, Vehicle doesn't have these extra things, but Player definitely does. For example, instead of doing getPlayerFromName(), you would do Player.getFromName(). It's a nice and simple way to organise functions.
Tip: Vehicle() works because it actually accesses the Vehicle.create function, this allows you to omit the .create when simply "creating an object" |
Since OOP sits on top of procedural, many things have been inherited from the style of procedural, but to make things easier we have variables for all the functions that require a single input. We've shortened getElementDimension() down to element:getDimension(), but we can also go one layer deeper: element.dimension. Yep, just like a variable. You can set this variable just like a normal variable and read from it just like a normal variable. Hey, you could even do this:
local function incrementDimension() local player = Player.getRandom() -- get a random player player.dimension = player.dimension + 1 -- increment dimension end Timer(incrementDimension, 60*1000, 10) -- set a timer for sixty thousand milliseconds, sixty seconds, one minute
This code would take a random player and move them to the next dimension every minute for the next ten minutes.
Vectors
player.position works too! But how do you change three arguments... using one variable? Vectors. Vectors are very powerful classes and they come in multiple forms, for the purpose of this introduction I'll just cover a three dimensional vector in terms of elements. Using a vector is very simple, and is, of course, optional. Wherever you can currently use positions, you can use a vector.
So, this is a simple example of creating a vehicle and moving it to the the centre of the map using vectors
-- First, create a three-dimensional vector local position = Vector3(300, -200, 2) -- some place far away local vehicle = Vehicle(411, position) -- create a vehicle at the position vehicle.position = centreOfMap - Vector3(300, -200, 0) -- move the vehicle two units above the center of the map
Yes, I used the negative sign. Vectors aren't just fancy ways for positions or 3d rotations or whatever, you can use maths on them. The special maths hasn't been documented yet, but I'll try and work on that. So, as you can see in line one, I created a 3D vector at 300, -200, 2 and then in line two I created the vehicle at that position.
vehicle.position returned a vector and also takes a vector - it is pretty much setElementPosition() without the "()". Just a simple variable; so, in line three, I changed the vector value of the position of the vehicle. This is where the maths happened, in simple terms this is what is going on:
x = 300 - 300 y = -200 - -200 z = 2 - 0
Vector maths is slightly complicated but it definitely allows for a wide variety of mathematical magic. Check out the useful links below related to Vectors and Matrices (Matrices = plural form of Matrix) to understand more about how this works.
Understanding the documentation
The documentation for the OOP syntax intends to be very simplistic and is supported by the procedural syntax. To keep things simple, everything is consistently formatted in a certain way.
OOP Syntax Help! I don't understand this!
- Note: Set the variable to nil to execute removePedFromVehicle
- Method: ped:warpIntoVehicle(...)
- Variable: .vehicle
- Counterpart: getPedOccupiedVehicle
- Sometimes a note is added to the page. This will explain any special differences in the use of OOP for that function.
- Methods can either start like player: or Player. - the former is only for a function on an instance (setPlayerHealth) and the latter is a static method (getRandomPlayer).
- The counterpart section this allows you to see at a glance how the variable can be used. In most cases this can be inferred from the function page.
If you are a contributor to the wiki, please also consider reading the OOP template.
Useful links
Other useful OOP related pages: