-[[pf:particle_fleet|PF Home]] <-[[prpl:start|PRPL Home]]
====== PRPL Code Segments ======
Here I go over some PRPL code segments, each achieving some particular task (like moving a units/ships, creating units/particles, showing images or text, discovering units/ships/particles, input handling etc.). Each segment isn't enough to make a fully functional unit, but most units consist of several such segemnts working together.
If you are looking for what is possible in PRPL or some inspiration for your own units, this is a good place to start, provided you know [[prpl:prpltutorial|the fundamentals]]. Each segemnt will consist of the code doing the work, the explaination of the code and a little homework for you to modify it in some way.
(TODO: buildable/charable unit, creating a unit, work with images, work with text, communication betwee n scripts, work with ship inventory - this list is mostly for myself so I don't forget what I wanted to talk about)
===== Discovering units/ships/particles in a range =====
Let's start with "discovery" commands, since we will learn about cell and pixel coordinates, which will be usefull later. Let's start with ''GetAllShipsInRange # [int int float bool - list] (x y range square?)''. The first 2 arguments are the cell coordinates for the center of the search, next is the range of the search (in cells) and the final argument is the search mode (1=square, 0=circle). Let's look at a visual example:
50 50 20 0 GetAllShipsInRange ->list
{{:prpl:screenshot_3.png?800|}}
Here, we are looking for all ships in a ''cirlce'' centered at cell ''(50,50)'' with radius ''20''. The search area is visualized exactly with the range of the energy source. As noted in the comment, the center of the command module has to be in the range for the ship to be considered in range.
The ''(50,50)'' detonate the coordinates of the cell at the center of the search. when wrtitng coordinates as a pair, ''X'' is always first and ''Y'' is always second. The bottom-left cell has coordinates ''(0,0)'', you can also see the coordinates of the cell where your mouse on the bottom of your screen (left of the mid-bottom panel).
Lastly, if the mode was set to square, the area would be a square with side length ''2*length'' as shown in the image.
You can also discover units in the same way using ''GetAllUnitsInRange # [int int float bool - list]'', and there is also ''GetClosesShipInRange # [int int float bool - int]'' that works, simmilarly, but only returns the id of the closest ship in the search range, or ''-1'' if no ship is found.
==== Particle discovery commands ====
Particle discovery works in a completely different way. First, ''GetParticlesInRange # [int int float bool bool - list] (x y range square? enemy?)'' takes additional parameter: wheter to look for enemy particles or friendly (1=enemy, 0=friendly).
Moreover, ''range'' is now the diameter rather than the radius of the search (the diameter of the circle, or the side length of the square, depending on the mode), but you can still use ''GetParticlesInRadius'' if you want to use radius.
Lastly the coordinates for the center of the search as well as the search diameter/radius are now in //pixels//. Pixels are like cells, except they form a denser grid. The easy conversion is that ''1 cell = 4 pixels'', so for example the pixel equivalent of cell ''(10,20)'' would be ''(40,80)''. Ecxept, that is not entirely the case.
=== Cell coordinates vs pixel coordinates ===
Cell coordinates are always integers, and a cell coordinate always refer to the cell as a whole. Pixel coordinates, however, are float and they refer to a //specific// point on the game map. For example, ''(4.2,5)'' and ''(4.3,5)'' are different pixel coordinates, since they are different points on the game map, however ''(4.2,5)'' and ''(4.3,5)'' are the same cell coordiantes since they are converted to the same cell ''(4,5)''.
So, when I say that "''1 cell = 4 pixels'' isn't entirely accurate", what I mean is that if you take a cell coordinate and just multiply both components by 4, you will get a pixel coordinate refering to the //bottom-left// corner of the cell. If you want a pixel coordinate representing the //center// of the cell, you need to multiply the cell coordinates by 4 and then add 2.
==== The homework ====
Write a script that will find all units and enemy particles withing 20 cells distance from itself. (Use ''CurrentCoords # [ - int int]'' and ''CurrentPixelCoords # [ - float float]'' to get the current pixel/cell position of the PRPL core running the script.)
Solution:
CurrentCoords 20 0 GetAllUnitsInRange ->foundUnits
CurrentPixelCoords 80 0 1 GetParticlesInRadius ->foundParticles
Notes: the search type needs to be cirlce (0) to accurately check for range, and the radius needs to be 4 times larger for particles, since it is in pixels and one cell = 4 pixels when it comes to distance. Finally, ''CurrentPixelCoords'' already gives the pixel coordinates representing the //center// of the cell where the PRPL core is located (unless changed by ''SetUnitPixelCoords'' or course, but more on that later), so no need for further adjustments.
$Speed:2.0 #Move $Speed pixels per frame
$TargetX:202 #Pixel X of the target position
$TargetY:82 #Pixel Y of the target postiion
CurrentPixelCoords ->y ->x #save current position
<-x <-y <-TargetX <-TargetY Distance ->distance #distance to target, in pixels
<-distance <-Speed lte if #if the target is withing the reach, teleport there outright
Self <-TargetX 4 div <-TargetY 4 div SetUnitCoords
Self <-TargetX <-TargetY SetUnitPixelCoords
"Finished moving" Trace
else
#move $Speed pixels closer to the target
<-TargetX <-x sub <-distance div <-Speed mul <-x add ->x
<-TargetY <-y sub <-distance div <-Speed mul <-y add ->y
Self <-x 4 div <-y 4 div SetUnitCoords #set cell coordinates
Self <-x <-y SetUnitPixelCoords #set pixel coordinates
endif
We start relatively simply by first saving the current pixel coordinates and then computing the distance t othe targer. If the target is close enough (closer than $Speed), it means that the unit can move to the targer in this frame, so we do just that.
The more interesting is how we move the units closer if it's far ways. First, ''<-TargetX <-x sub'' is the "X distance" from the current core to the target. If we were to add this to the X position, it would move to the target directly. So we divide this by ''distance''. That way we only move 1 pixel closer to the target. Finally, we multiply by ''Speed'' to move ''Speed'' pixel closer to the target. ''... <-x add ->x'' Will then move the core by the specified amount.
Some image might be more helpful:
{{:prpl:move_unit.png?600|}}
The image explains the expression ''<-TargetX <-x sub <-distance div <-Speed mul'' and why adding it to the X position (and same with Y) will move the unit Speed pixels closer to the target. Then, ''<-x add ->x'' simply increases the position by that amount, moving the unit closer to the target.
Few important notes:
* ''SetUnitCoords'' will also set the pixel coordinates coresponding to that cell, so it's important to call this first.
* ''SetUnitCoords'' will convert the cell coordinates as integers, so it's important to move the unit alongside the pixel coordinates instead.
* Notice that the target is ''(202,82)''. This is very much on purpouse, as that pixel coordiantes are at the center of the cell ''(50,20)''.
==== Homework ====
Make a unit that accelerate towards the target point instead. Isntead of ''$Speed'' use ''$Accel'' and increase the speed by that amount every frame.
Solution:
$Accel:0.1 #Increase the speed by $Accel every frame
$TargetX:202 #Pixel X of the target position
$TargetY:82 #Pixel Y of the target postiion
once
0 ->speed
endonce
<-speed <-Accel add ->speed
CurrentPixelCoords ->y ->x #save current position
<-x <-y <-TargetX <-TargetY Distance ->distance #distance to target, in pixels
<-distance <-speed lte if #if the target is withing the reach, teleport there outright
Self <-TargetX 4 div <-TargetY 4 div SetUnitCoords
Self <-TargetX <-TargetY SetUnitPixelCoords
"Finished moving" Trace
else
#move speed pixels closer to the target
<-TargetX <-x sub <-distance div <-speed mul <-x add ->x
<-TargetY <-y sub <-distance div <-speed mul <-y add ->y
Self <-x 4 div <-y 4 div SetUnitCoords #set cell coordinates
Self <-x <-y SetUnitPixelCoords #set pixel coordinates
endif
$MaxHealth:200
$MaxEnergy:100
once
#healt
Self <-MaxHealth SetUnitMaxHealth # lathes will heal 1 health per frame
Self 0 SetUnitHasHealthBar # don't display healtb bar while it has only 1 health at start
Self -1 SetUunitLatheDamageAmt # negative value - lathe heals the unit
Self 1 SetUnitLatheTargets # make lathes target this unit
#energy
Self 0 SetUnitReceivesPackets # set 0 for now, so it doesn't accept enemy packets
Self <-MaxEnergy SetUnitMaxEnergy
Self 3 SetUnitPacketDelay # accept 1 energy packet every X frames
Self 0 SetUnitHasEnergyBar # hide energy bar for now
#reset
Self 1 SetUnitHealth # start at 1 health - it would destroy itself at 0
Self 0 SetUnitEnergy # reset energy to 0
Self 1 SetUnitIsEnemy # make the unit enemy, so that friendly lathes will target it and heal it
endonce
Self GetUnitIsEnemy if
#while "constructing" with lathe
#display health bar only if health > 1
Self GetUnitHealth 1.5 lt if
Self 1 SetUnitHealth # work around some wierd float calcualtion issues
else
Self 1 SetUnitHasHealthBar # show energy bar once it's being "constructed" by the lathes
endif
#flip to gather energy when built
Self GetUnitHealth gte (Self GetUnitMaxHealth) if # check if at full health
Self 0 SetUnitIsEnemy # make unit no longer enemy, so it can receive friendly energy
Self 1 SetUnitReceivesPackets # receive friendly energy packets
Self 0 SetUnitHasHealthBar # hide health bar once it's build
Self 1 SetUnitHasEnergyBar # show energy bar isntead
Self 0 SetUnitLatheTargets # so enemies don't destroy it once built
endif
else
# already build
Self GetUnitEnergy gte (Self GetUnitMaxEnergy) if # check if at full energy
"Full energy!" Trace #todo: actaully do something useful here
Self 0 SetUnitEnergy #reset energy back to 0
endif
endif
Now that's a lot of code, but the comments should explain it well enought. The only wierd bit might be hiding/showing the ehalth bar. It is hidden at first, because it would render a tiny red dot when the unit is at 1 health, which wouldn't look very nice, since the unit starts at 1 health even before yo ustart building it with lathes.
You can go and make it do something usefull once it cahrges with energy, or you can remove the nergy reset and have it provide a pasive bonus while at full energy, the possibilites are endless.
==== Homework ====
Change the unit to be symetrical for both the player and the enemy - once the player captures it with lathes, the enemy can capture it as well. When in enemy control, make the unit accept enemy energy packets and up build energy as well. Finally, make the health go from 100% to 0% when being captured by the lathes, as that would more suit a flipable unit like this.
$MaxHealth:200
$MaxEnergy:100
$StartAsEnemy:1
once
#healt
Self <-MaxHealth SetUnitMaxHealth
Self 0 SetUnitHasHealthBar # don't display health bar on 100% health
Self 1 SetUunitLatheDamageAmt # positive value - lathe damages the unit
Self 1 SetUnitLatheTargets # always stay a valid lathe target
#energy
Self 1 SetUnitReceivesPackets # always accept energy packets
Self <-MaxEnergy SetUnitMaxEnergy
Self 3 SetUnitPacketDelay #accept 1 energy packet every X frames
Self 1 SetUnitHasEnergyBar # always show energy bar: it will be empty when at 0 energy
#reset
<-StartAsEnemy ->isEnemy
Self Self GetUnitMaxHealth SetUnitHealth # fully heal
Self 0 SetUnitEnergy # start at 0 energy
Self <-isEnemy SetUnitIsEnemy
@SetImageColor
endonce
#check health
Self GetUnitHealth 10 lt if # health is low enought to flip
# flip from enemy to player or wise versa
<-isEnemy neg ->isEnemy
Self Self GetUnitMaxHealth SetUnitHealth # reset to full health
Self 0 SetUnitEnergy # reset to 0 energy
Self <-isEnemy SetUnitIsEnemy # set enemy to new value
Self 0 SetUnitHasHealthBar # don't display health bar on 100% health
@SetImageColor
return # end script execution for this frame
endif
Self GetUnitMaxHealth sub (Self GetUnitHealth) lt (0.5) if #current health is at most 0.5 lett than max health = unit at full health
Self Self GetUnitMaxHealth SetUnitHealth # force set unit to full health, fixes a wierd float issue
else
Self 1 SetUnitHasHealthBar #unit has taken damage - display the health bar
endif
#flip to gather energy when built
Self GetUnitHealth gte (Self GetUnitMaxHealth) if
Self 0 SetUnitIsEnemy
Self 1 SetUnitReceivesPackets
Self 0 SetUnitHasHealthBar
Self 1 SetUnitHasEnergyBar
Self 0 SetUnitLatheTargets # so enemies don't destroy it once built
endif
#check energy
Self GetUnitEnergy gte (Self GetUnitMaxEnergy) if
<-isEnemy if
"Full energy on enemy side, hue hue." Trace #todo: actaully do something useful here
else
"Full energy on friendly side, yatta!" Trace #todo: actaully do something useful here
endif
Self 0 SetUnitEnergy
endif
:SetImageColor #sets the image color to red/blue depending on isEnemy variable
if (<-isEnemy)
Self "main" 255 0 0 255 SetImageColor # R G B A
else
Self "main" 0 0 255 255 SetImageColor # R G B A
endif
Again, most code is exaplined with comment. This time we don't show the health bar until the unit takes some damage. The "wierd float issue" was that the health would randomly decreace by a tiny amount (say, from `200` to `199.9999764`) so we fix that by forcably heling the unit when it's at full ehalth, just in case.
Aslo, when checking if the ehalth is low enought, `Self GetUnitHealth 10 lt if # health is low enought to flip` it is wise to choose a slightly larger number, like `10`, so that even when multiple lathes are targeting the unit, they will not destroy it before it can flip and fully heal itself.
$StarFill:"Custom0_256"
$StarBorder:"Custom1_256"
once
Self "fill" <-StarFill SetImage
Self "fill" 255 255 0 255 SetImageColor # R=255 G=255 B=0 A=255 - yellow
Self "fill" 2 2 SetImageScale
Self "border" <-StarBorder SetImage
Self "border" 255 128 0 255 SetImageColor # R=255 G=128 B=0 A=255 - orange
Self "border" 2 2 SetImageScale
endonce
Again, search for "image" on the [[prpl:prplreference|PRPL Reference]] for more detail, or go to the [[https://knucklecracker.com/wiki/doku.php?id=crpl:crplreference#image_commands|CRPL Reference]] if the page isn't filled on the PRPL wiki.
How it looks:
{{:prpl:first_star.png|}}
The interesting part here is that the image itself is whire, but the color is set in PRPL. The advantage over having the image itself colored is that we can now compute and change the color with PRPL to our liking, which we will do momentary.
But first, a few notes: ''%%Self "fill" <-StarFill SetImage%%'' The first agument, Self, is the ID of the core on which we want to set the image, so you can manipulate images on different cores, but that is rarely used. The second argument, ''%%"fill"%%'', is the internal name of the image. Since a PRPL core can have multiple images attached to them and you need to differentiate between them, this is the way to it. Finally, ''%%<-StarFill%%'' is the name of the image in the game's image repository (if you can call that). This is the slot name into which you loaded the image earlier. It's a good practice to always set this as Script Argument, since you could easily end up with 2 scripts that want to use the same slot for different images, so you can easily change the image slot without even editing the script's code.
Next, let's take a look at ''%%Self "fill" 255 255 0 255 SetImageColor%%'' The 4 numbers specify the color as a RGBA color - that means the first number is for Red, second for Green, third for Blue and fourth for Alpha (visibility). Each pixel's values in the original image is "multiplied" by this value (or rather, by it's relative value). For example, if the original pixel in the image had color (255,128,0,128) (half-transparent orange), and the color set by PRPL was (32,128,255,64), then the resulting color would be (64,128,0,32), since (32 = 255 * (32/256), 64 = 128 * (128/256), 0 = 0 * (255/256), 32 = 128 / (64/256)). Note that this can only decrese the color value, so while you can turn white into any other color, black will always remain black.
Finally, ''%%Self "fill" 2 2 SetImageScale%%'' is relatively simple, for image scale just remember that ''1 scale = 3 cells'', probably since 3x3 modules are a common image, so they would have scale 1.
==== Making the star change color ====
Now we are getting into some fun. Let's start by chaning the color from red to yellow by keeping the red color channel at 255 and changing the green color channel:
$StarFill:"Custom0_256"
$StarBorder:"Custom1_256"
$Step:2 #the speed of color change
once
Self "fill" <-StarFill SetImage
#Self "fill" 255 255 0 255 SetImageColor # R=255 G=255 B=0 A=255 - yellow
Self "fill" 2 2 SetImageScale
Self "border" <-StarBorder SetImage
Self "border" 255 128 32 255 SetImageColor
Self "border" 2 2 SetImageScale
0 ->green
1 ->growing #the green color is growing
endonce
<-growing if
<-green <-Step add ->green
<-green 255 gt if
# the green color is more than the maximum value of 255
255 ->green #set it back to maximum
0 ->growing #make it so its growing smaller isntead
endif
else
<-green <-Step sub ->green
<-green 0 lt if
# the green color is less than the minimum value of 0
0 ->green #set it back to minimum
1 ->growing #make it so its growing larger again
endif
endif
Self "fill" 255 <-green 0 255 SetImageColor
How it looks:
{{:prpl:second_star.gif|}}
The code should be pretty self-explanatory. If you have never worked with RGb values before and ar ewondering where the 255 number comes from, it's from the fact taht computers store color as 3 8-bit numbers, one for Red, one for Green and one for Blue (RGB). And since 8 bits can hold 256 diffent values, the color values are from the range 0-255. Finally, if you want to see some examples of colors and their RGB values, jsut any [[http://lmgtfy.com/?q=color+picker+online|online color picker]].
==== Setting position and rotation ====
Next we are going to make the start rotate around the core by chaning it's position, as well as rotate as an image to make it spin. Code:
$StarFill:"Custom0_256"
$StarBorder:"Custom1_256"
$Step:2 #the speed of color change
$Distance:40 #the radius of the star's orbit around the core, in pixels
$OrbitingSpeed:0.01 #the speed at which the star orbits around the code, in radians/frame
$SpinningSpeed:-0.03 #the speed at which the star spins around it's own center, in radians/frame
once
Self "fill" <-StarFill SetImage
#Self "fill" 255 255 0 255 SetImageColor # R=255 G=255 B=0 A=255 - yellow
Self "fill" 2 2 SetImageScale
Self "border" <-StarBorder SetImage
Self "border" 255 128 32 255 SetImageColor
Self "border" 2 2 SetImageScale
0 ->green
1 ->growing #the green color is growing
0 ->orbitAngle
0 ->spinAngle
endonce
# set the color
<-growing if
<-green <-Step add ->green
<-green 255 gt if
# the green color is more than the maximum value of 255
255 ->green #set it back to maximum
0 ->growing #make it so its growing smaller isntead
endif
else
<-green <-Step sub ->green
<-green 0 lt if
# the green color is less than the minimum value of 0
0 ->green #set it back to minimum
1 ->growing #make it so its growing larger again
endif
endif
Self "fill" 255 <-green 0 255 SetImageColor
#set the position
<-orbitAngle <-OrbitingSpeed add ->orbitAngle
Self "fill" <-orbitAngle cos <-Distance mul SetImagePositionX
Self "fill" <-orbitAngle sin <-Distance mul SetImagePositionY
Self "border" <-orbitAngle cos <-Distance mul SetImagePositionX
Self "border" <-orbitAngle sin <-Distance mul SetImagePositionY
#set the rotation
<-spinAngle <-SpinningSpeed add ->spinAngle
Self "fill" <-spinAngle SetImageRotation
Self "border" <-spinAngle SetImageRotation
Result:
{{:prpl:third_star.gif|}}
The key to making it look good is balancing the rotations speeds properly. I definetely like it more when the start is spinning in the oposite derection than the orbit (positiv/negative rotation speed), but you can change it however you like.
==== The homework ====
We could go on and on, making the star bigger/smaller, or moving it closer/further away, or even adding more interesting color changes, etc. But for the homework, make it so that 6 stars orbit the core, evenly spread out. You will need 12 image slots in total (6 for the "fills", and 6 for the "borders") and I recommend you name them "fill0", "fill1" etc so you can easily manipulate them by using ''%%"fill" I concat%%'' inside a do-loop. Use ''TWOPI 6 div'' to get the radian equivalent of 60 degrees.
Preview:
{{:prpl:fourth_star.gif|}}
Solution:
$StarFill:"Custom0_256"
$StarBorder:"Custom1_256"
$Step:2 #the speed of color change
$Distance:40 #the radius of the star's orbit around the core, in pixels
$OrbitingSpeed:0.01 #the speed at which the star orbits around the code, in radians/frame
$SpinningSpeed:-0.03 #the speed at which the star spins around it's own center, in radians/frame
$Stars:6 #the amount of stars
once
Self RemoveImages
<-Stars 0 do
Self "fill" I concat <-StarFill SetImage
Self "fill" I concat 2 2 SetImageScale
Self "border" I concat <-StarBorder SetImage
Self "border" I concat 255 128 32 255 SetImageColor
Self "border" I concat 2 2 SetImageScale
loop
0 ->green
1 ->growing #the green color is growing
0 ->orbitAngle
0 ->spinAngle
endonce
# set the color
<-growing if
<-green <-Step add ->green
<-green 255 gt if
# the green color is more than the maximum value of 255
255 ->green #set it back to maximum
0 ->growing #make it so its growing smaller isntead
endif
else
<-green <-Step sub ->green
<-green 0 lt if
# the green color is less than the minimum value of 0
0 ->green #set it back to minimum
1 ->growing #make it so its growing larger again
endif
endif
<-orbitAngle <-OrbitingSpeed add ->orbitAngle
<-spinAngle <-SpinningSpeed add ->spinAngle
<-Stars 0 do
Self "fill" I concat 255 <-green 0 255 SetImageColor
#set the position
TWOPI <-Stars div I mul ->offset
Self "fill" I concat <-orbitAngle <-offset add cos <-Distance mul SetImagePositionX
Self "fill" I concat <-orbitAngle <-offset add sin <-Distance mul SetImagePositionY
Self "border" I concat <-orbitAngle <-offset add cos <-Distance mul SetImagePositionX
Self "border" I concat <-orbitAngle <-offset add sin <-Distance mul SetImagePositionY
#set the rotation
Self "fill" I concat <-spinAngle SetImageRotation
Self "border" I concat <-spinAngle SetImageRotation
loop