OpenGL -- GL_LINE_LOOP -- - c

I am using GL_LINE_LOOP to draw a circle in C and openGL! Is it possible for me to fill the circle with colors?
If needed, this is the code I'm using:
const int circle_points=100;
const float cx=50+i, cy=50+x, r=50;
const float pi = 3.14159f;
int i = 50;
glColor3f(1, 1, 1);
glBegin(GL_LINE_LOOP);
for(i=0;i<circle_points;i++)
{
const float theta=(2*pi*i)/circle_points;
glVertex2f(cx+r*cos(theta),cy+r*sin(theta));
}
glEnd();

Lookup polygon triangulation!
I hope something here is somehow useful to someone, even though this question was asked in February. There are many answers, even though a lot of people would give none. I could witter forever, but I'll try to finish before then.
Some would even say, "You never would," or, "That's not appropriate for OpenGL," I'd like to say more than them about why. Converting polygons into the triangles that OpenGL likes so much is outside of OpenGL's job-spec, and is probably better done on the processor side anyway. Calculate that stage in advance, as few times as possible, rather than repeatedly sending such a chunky problem on every draw call.
Perhaps the original questioner drifted away from OpenGL since February, or perhaps they've become an expert. Perhaps I'll re-inspire them to look at it again, to hack away at some original 'imposters'. Or maybe they'll say it's not the tool for them after all, but that would be disappointing. Whatever graphics code you're writing, you know that OpenGL can speed it up!
Triangles for convex polygons are easy
Do you just want a circle? Make a triangle fan with the shared point at the circle's origin. GL_POLYGON was, for better or worse, deprecated then killed off entirely; it will not work with current or future implementations of OpenGL.
Triangles for concave polygons are hard
You'll want more general polygons later? Well, there are some tricks you could play with, for all manner of convex polygons, but concave ones will soon get difficult. It would be easy to start five different solutions without finishing a single one. Then it would be difficult, on finishing one, to make it quick, and nearly impossible to be sure that it's the quickest.
To achieve it in a future-proofed way you really want to stick with triangles -- so "polygon triangulation" is the subject you want to search for. OpenGL will always be great for drawing triangles. Triangle strips are popular because they reuse many vertices, and a whole mesh can be covered with only triangle strips, (perhaps including the odd lone triangle or pair of triangles). Drawing with only one primitive usually means the entire mesh can be rendered with a single draw call, which could improve performance. (Number of draw calls is one performance consideration, but not always the most important.)
Polygon triangulation gets more complex when you allow convex polygons or polygons with holes. (Finding algorithms for triangulating a general polygon, robustly yet quickly, is actually an area of ongoing research. Nonetheless, you can find some pretty good solutions out there that are probably fit for purpose.)
But is this what you want?
Is a filled polygon crucial to your final goals in OpenGL? Or did you simply choose what felt like it would be a simple early lesson?
Frustratingly, although drawing a filled polygon seems like a simple thing to do -- and indeed is one of the simplest things to do in many languages -- the solution in OpenGL is likely to be quite complicated. Of course, it can be done if we're clever enough -- but that could be a lot of effort, without being the best route to take towards your later goals.
Even in languages that implement filled polygons in a way that is simple to program with, you don't always know how much strain it puts on the CPU or GPU. If you send a sequence of vertices, to be linked and filled, once every animation frame, will it be slow? If a polygon doesn't change shape, perhaps you should do the difficult part of the calculation just once? You will be doing just that, if you triangulate a polygon once using the CPU, then repeatedly send those triangles to OpenGL for rendering.
OpenGL is very, very good at doing certain things, very quickly, taking advantage of hardware acceleration. It is worth appreciating what it is and is not optimal for, to decide your best route towards your final goals with OpenGL.
If you're looking for a simple early lesson, rotating brightly coloured tetrahedrons is ideal, and happens early in most tutorials.
If on the other hand, you're planning a project that you currently envision using filled polygons a great deal -- say, a stylized cartoon rendering engine for instance -- I still advise going to the tutorials, and even more so! Find a good one; stick with it to the end; you can then think better about OpenGL functions that are and aren't available to you. What can you take advantage of? What do you need or want to redo in software? And is it worth writing your own code for apparently simple things -- like drawing filled polygons -- that are 'missing from' (or at least inappropriate to) OpenGL?
Is there a higher level graphics library, free to use -- perhaps relying on OpenGL for rasterisation -- that can already do want you want? If so, how much freedom does it give you, to mess with the nuts and bolts of OpenGL itself?
OpenGL is very good at drawing points, lines, and triangles, and hardware accelerating certain common operations such as clipping, face culling, perspective divides, perspective texture accesses (very useful for lighting) and so on. It offers you a chance to write special programs called shaders, which operate at various stages of the rendering pipeline, maximising your chance to insert your own unique cleverness while still taking advantage of hardware acceleration.
A good tutorial is one that explains the rendering pipeline and puts you in a much better position to assess what the tool of OpenGL is best used for.
Here is one such tutorial that I found recently: Learning Modern 3D Graphics Programming
by Jason L. McKesson. It doesn't appear to be complete, but if you get far enough for that to annoy you, you'll be well placed to search for the rest.
Using imposters to fill polygons
Everything in computer graphics is an imposter, but the term often has a specialised meaning. Imposters display very different geometry from what they actually have -- only more so than usual! Of course, a 3D world is very different from the pixels representing it, but with imposters, the deception goes deeper than usual.
For instance, a rectangle that OpenGL actually constructs out of two triangles can appear to be a sphere if, in its fragment shader, you write a customised depth value to the depth coordinate, calculate your own normals for lighting and so on, and discard those fragments of the square that would fall outside the outline of the sphere. (Calculating the depth on those fragments would involve a square root of a negative number, which can be used to discard the fragment.) Imposters like that are sometimes called flat cards or billboards.
(The tutorial above includes a chapter on imposters, and examples doing just what I've described here. In fact, the rectangle itself is constructed only part way through the pipeline, from a single point. I warn that the scaling of their rectangle, to account for the way that perspective distorts a sphere into an ellipse in a wide FOV, is a non-robust fudge . The correct and robust answer is tricky to work out, using mathematics that would be slightly beyond the scope of the book. I'd say it is beyond the author's algebra skills to work it out but I could be wrong; he'd certainly understand a worked example. However, when you have the correct solution, it is computationally inexpensive; it involves only linear operations plus two square roots, to find the four limits of a horizontally- or vertically-translated sphere. To generalise that technique for other displacements requires one more square root, for a vector normalisation to find the correct rotation, and one application of that rotation matrix when you render the rectangle.)
So just to suggest an original solution that others aren't likely to provide, you could use an inequality (like x * x + y * y <= 1 for a circle or x * x - y * y <= 1 for a hyperbola) or a system of inequalities (like three straight line forms to bound a triangle) to decide how to discard a fragment. Note that if inequalities have more than linear order, they can encode perfect curves, and render them just as smoothly as your pixelated screen will allow -- with no limitation on the 'geometric detail' of the curve. You can also combine straight and curved edges in a single polygon, in this way.
For instance, a fragment shader (which would be written in GLSL) for a semi-circle might have something like this:
if (y < 0) discard;
float rSq = x * x + y * y;
if (1 < rSq) discard;
// We're inside the semi-circle; put further shader computations here
However, the polygons that are easy to draw, in this way, are very different from the ones that you're used to being easy. Converting a sequence of connected nodes into inequalities means yet more code to write, and deciding on the Boolean logic, to deal with combining those inequalities, could then get quite complex -- especially for concave polygons. Performing inequalities in a sensible order, so that some can be culled based on the results of others, is another ill-posed headache of a problem, if it needs to be general, even though it is easy to hard-code an optimal solution for a single case like a square.
I suggest using imposters mainly for its contrast with the triangulation method. Something like either one could be a route to pursue, depending on what you're hoping to achieve in the end, and the nature of your polygons.
Have fun...
P.S. have a related topic... Polygon triangulation into triangle strips for OpenGL ES
As long as the link lasts, it's a more detailed explanation of 'polygon triangulation' than mine. Those are the two words to search for if the link ever dies.

A line loop is just an outline.
To fill the middle as well, you want to use GL_POLYGON.

Related

opencascade BRepOffsetAPI_Sewing is slow

i have fairly large files with 3D scan points (200.000 ish) and try to make a TopoDS_Shape with BRepOffsetAPI_Sewing
gp_Pnt p1(0,0,100);
...
TopoDS_Edge e1 = BRepBuilderAPI_MakeEdge( p4, p1);
...
TopoDS_Wire w1 = BRepBuilderAPI_MakeWire(e1, e2, e3, e4);
...
TopoDS_Face f1 = BRepBuilderAPI_MakeFace(w1);
...
BRepOffsetAPI_Sewing sew(0.1);
sew.Add(f1);sew.Perform();TopoDS_Shape sewedShape = sew.SewedShape();
of corse with all the points in loops etc. above code is just a sample how I try to create things.
with 200.000 points it takes 20-30 second to produce the face.
my next approach was to save the produced shape after generated and load it later as a workaround.
BRepTools::Write(sewedShape, sFile);
but even that is slow.
I did similar things in Java3D and it was way faster. So I make something wrong.
only showing the points with
Handle_Graphic3d_ArrayOfPoints points3d = new Graphic3d_ArrayOfPoints(totPoints, true, false);
gp_Pnt pnt(x, y, z);
points3d->AddVertex(pnt, aColor); // adding 200.000 points
Handle(AIS_PointCloud) m_points = new AIS_PointCloud();
m_points->SetPoints(points3d);
m_occView->getContext()->Display(m_points, true);
is almost instant (less then a second)
my goal is to build 2 of those faces and find the intersection with OCBRepAlgoAPI_Section
Thanks for help in advance!
As far as I understand, your current approach is:
Create a TopoDS_Face per quad in Point Cloud.
To avoid unnecessary overhead on sewing operation, you would need reconsidering your workflow and create shared shapes from the scratch. E.g., instead of creating TopoDS_Vertex for the same point in Point Cloud multiple times, you should create a single one and reuse it in construction of connected edges / quads; the same applies to TopoDS_Edge construction. What sewing operation does for you is finding and repairing shared information between geometrically connected faces - which is a plenty of work that could be entirely avoided.
But as you have been already pointed out (by trying to dump produced shape into a file), mapping tessellation to B-Rep is counter-efficient approach in general. Just take a look at all these TopoDS_Vertex, TopoDS_Edge, TopoDS_Wire, TopoDS_Face to figure out how much more data structures are needed in B-Rep for mapping a very single triangle or quad. This structure is heavy not only from memory utilization point of view, but also for algorithms you might want to do with it like Boolean operations.
Possible alternatives:
Create a Poly_Triangulation from your point cloud and a single TopoDS_Face from it. You would be able to efficiently visualize it in 3D Viewer and perform some operations like computing surface area. Unfortunately, such geometry definition is not yet supported by all OCCT algorithms, so that you wouldn't be able performing Boolean operations.
Create an approximated B-Spline surface from your Point Clouds. This could be done with help of GeomPlate or SSP (Surface from Scattered Points) algorithms. Approximated surface would be a better fit to B-Rep geometry definition, but might loose some details of original surface and might be tricky to apply (you might need splitting a complex surface into several pieces).
Use OMF product (Mesh Framework) to perform Boolean operations on meshes. In case if Boolean operation on meshes is all you need, OMF could be helpful.

Advice for Object Detection on Embedded System with no non-standard libraries

I am looking for some advice for a good way to detect either square or circular objects in an image. I currently have a canny edge algorithm running on the original greyscale and I can produce this output:
http://imgur.com/FAwowr1
Now I can see that there is a cubesat in this picture, but what is a good computationally efficient way that the program can see that aswell? I have looked at houghs transform but that seems to be very computation heavy. I have also looked at Harris corner detect, but I feel I would get to many false positives, for I am essentially looking to isolate pictures that contain said cube satellite.
Anyone have any thoughts on some good algorithms to pursue? I am very limited on space so I cannot use any large external libraries like opencv. (This is all in C btw)
Many Thanks!
I would into what is called mathematical morphology
Basically you operate on binary images, so you must find a clever way to threshold them first , the you do operations such as erosion and dilation with some well selected structuring element to extract areas of interest in your image.

best method of turning millions of x,y,z positions of particles into visualisation

I'm interested in different algorithms people use to visualise millions of particles in a box. I know you can use Cloud-In-Cell, adaptive mesh, Kernel smoothing, nearest grid point methods etc to reduce the load in memory but there is very little documentation on how to do these things online.
i.e. I have array with:
x,y,z
1,2,3
4,5,6
6,7,8
xi,yi,zi
for i = 100 million for example. I don't want a package like Mayavi/Paraview to do it, I want to code this myself then load the decomposed matrix into Mayavi (rather than on-the-fly rendering) My poor 8Gb Macbook explodes if I try and use the particle positions. Any tutorials would be appreciated.
Analysing and creating visualisations for complex multi-dimensional data is complex. The best visualisation almost always depends on what the data is, and what relationships exists within the data. Of course, you are probably wanting to create visualisation of the data to show and explore relationships. Ultimately, this comes down to trying different posibilities.
My advice is to think about the data, and try to find sensible ways to slice up the dimensions. 3D plots, like surface plots or voxel renderings may be what you want. Personally, I prefer trying to find 2D representations, because they are easier to understand and to communicate to other people. Contour plots are great because they show 3D information in a 2D form. You can show a sequence of contour plots side by side, or in a timelapse to add a fourth dimension. There are also creative ways to use colour to add dimensions, while keeping the visualisation comprehensible -- which is the most important thing.
I see you want to write the code yourself. I understand that. Doing so will take a non-trivial effort, and afterwards, you might not have an effective visualisation. My advice is this: use a tool to help you prototype visualisations first! I've used gnuplot with some success, although I'm sure there are other options.
Once you have a good handle on the data, and how to communicate what it means, then you will be well positioned to code a good visualisation.
UPDATE
I'll offer a suggestion for the data you have described. It sounds as though you want/need a point density map. These are popular in geographical information systems, but have other uses. I haven't used one before, but the basic idea is to use a function to enstimate the density in a 3D space. The density becomes the fourth dimension. Something relatively simple, like the equation below, may be good enough.
The point density map might be easier to slice, summarise and render than the raw particle data.
The data I have analysed has been of a different nature, so I have not used this particular method before. Hopefully it proves helpful.
PS. I've just seen your comment below, and I'm not sure that this information will help you with that. However, I am posting my update anyway, just in case it is useful information.

Collision Detection in 2D Motion

I have created a very simple numerical simulation that models an object being thrown off a building at some angle, and when the object hits the ground, the simulation stops. Now I want to add in collision detection. How would I go about doing this?
I know I need to find the exact time that the object (a ball) hits the ground, as well as the velocity in the x and y direction, and position of the object when it hits the ground, and I have to add in parameters that say how much the ball will bounce on impact. But I don't know how to go about doing this. I know that there are various ways of detecting collision but since I am new to this, the most comprehensible method would be best.
Make a coordinate system, with the ground at y=0. Track the coordinates of the ball as it flies and then check when it has y=0, and that's where it hits the ground. You can also keep track of the x and y velocity as the ball is moving.
Use Physics skillz. This is a good tutorial. If you have it, I recommend Fundamentals of Physics by Halliday, Resnick and Walker. They have a very good chapter on this.
If you are just looking for the math, that you could write C code for. I found this one helpful. Math Models
Collision detection simply involves determining the distance between 2 objects.
If you are only interested in collisions between objects and the ground, you can use:
if(object.y <= ground.y) {
//collision occurred
}
To do collisions between objects, you can loop through all objects and compare them to each other in the same way.

Pacman: how do the eyes find their way back to the monster hole?

I found a lot of references to the AI of the ghosts in Pacman, but none of them mentioned how the eyes find their way back to the central ghost hole after a ghost is eaten by Pacman.
In my implementation I implemented a simple but awful solution. I just hard coded on every corner which direction should be taken.
Are there any better/or the best solution? Maybe a generic one that works with different level designs?
Actually, I'd say your approach is a pretty awesome solution, with almost zero-run time cost compared to any sort of pathfinding.
If you need it to generalise to arbitrary maps, you could use any pathfinding algorithm - breadth-first search is simple to implement, for example - and use that to calculate which directions to encode at each of the corners, before the game is run.
EDIT (11th August 2010): I was just referred to a very detailed page on the Pacman system: The Pac-Man Dossier, and since I have the accepted answer here, I felt I should update it. The article doesn't seem to cover the act of returning to the monster house explicitly but it states that the direct pathfinding in Pac-Man is a case of the following:
continue moving towards the next intersection (although this is essentially a special case of 'when given a choice, choose the direction that doesn't involve reversing your direction, as seen in the next step);
at the intersection, look at the adjacent exit squares, except the one you just came from;
picking one which is nearest the goal. If more than one is equally near the goal, pick the first valid direction in this order: up, left, down, right.
I've solved this problem for generic levels that way: Before the level starts, I do some kind of "flood fill" from the monster hole; every tile of the maze that isn't a wall gets a number that says how far it is away from the hole. So when the eyes are on a tile with a distance of 68, they look which of the neighbouring tiles has a distance of 67; that's the way to go then.
For an alternative to more traditional pathfinding algorithms, you could take a look at the (appropriately-named!) Pac-Man Scent Antiobject pattern.
You could diffuse monster-hole-scent around the maze at startup and have the eyes follow it home.
Once the smell is set up, runtime cost is very low.
Edit: sadly the wikipedia article has been deleted, so WayBack Machine to the rescue...
You should take a look a pathfindings algorithm, like Dijsktra's Algorithm or A* algorithm. This is what your problem is : a graph/path problem.
Any simple solution that works is maintainable, reliable and performs well enough is a good solution. It sounds to me like you have already found a good solution ...
An path-finding solution is likely to be more complicated than your current solution, and hence more likely to require debugging. It will probably also be slower.
IMO, if it ain't broken, don't fix it.
EDIT
IMO, if the maze is fixed then your current solution is good / elegant code. Don't make the mistake of equating "good" or "elegant" with "clever". Simple code can also be "good" and "elegant".
If you have configurable maze levels, then maybe you should just do the pathfinding when you initially configure the mazes. Simplest would be to get the maze designer to do it by hand. I'd only bother automating this if you have a bazillion mazes ... or users can design them.
(Aside: if the routes are configured by hand, the maze designer could make a level more interesting by using suboptimal routes ... )
In the original Pacman the Ghost found the yellow pill eater by his "smell" he would leave a trace on the map, the ghost would wander around randomly until they found the smell, then they would simply follow the smell path which lead them directly to the player. Each time Pacman moved, the "smell values" would get decreased by 1.
Now, a simple way to reverse the whole process would be to have a "pyramid of ghost smell", which has its highest point at the center of the map, then the ghost just move in the direction of this smell.
Assuming you already have the logic required for chasing pacman why not reuse that? Just change the target. Seems like it would be a lot less work than trying to create a whole new routine using the exact same logic.
It's a pathfinding problem. For a popular algorithm, see http://wiki.gamedev.net/index.php/A*.
How about each square having a value of distance to the center? This way for each given square you can get values of immediate neighbor squares in all possible directions. You pick the square with the lowest value and move to that square.
Values would be pre-calculated using any available algorithm.
This was the best source that I could find on how it actually worked.
http://gameai.com/wiki/index.php?title=Pac-Man#Respawn
When the ghosts are killed, their disembodied eyes return to their starting location. This is simply accomplished by setting the ghost's target tile to that location. The navigation uses the same rules.
It actually makes sense. Maybe not the most efficient in the world but a pretty nice way to not have to worry about another state or anything along those lines you are just changing the target.
Side note: I did not realize how awesome those pac-man programmers were they basically made an entire message system in a very small space with very limited memory ... that is amazing.
I think your solution is right for the problem, simpler than that, is to make a new version more "realistic" where ghost eyes can go through walls =)
Here's an analog and pseudocode to ammoQ's flood fill idea.
queue q
enqueue q, ghost_origin
set visited
while q has squares
p <= dequeue q
for each square s adjacent to p
if ( s not in visited ) then
add s to visited
s.returndirection <= direction from s to p
enqueue q, s
end if
next
next
The idea is that it's a breadth-first search, so each time you encounter a new adjacent square s, the best path is through p. It's O(N) I do believe.
I don't know much on how you implemented your game but, you could do the following:
Determine the eyes location relative position to the gate. i.e. Is it left above? Right below?
Then move the eyes opposite one of the two directions (such as make it move left if it is right of the gate, and below the gate) and check if there are and walls preventing you from doing so.
If there are walls preventing you from doing so then make it move opposite the other direction (for example, if the coordinates of the eyes relative to the pin is right north and it was currently moving left but there is a wall in the way make it move south.
Remember to keep checking each time to move to keep checking where the eyes are in relative to the gate and check to see when there is no latitudinal coordinate. i.e. it is only above the gate.
In the case it is only above the gate move down if there is a wall, move either left or right and keep doing this number 1 - 4 until the eyes are in the den.
I've never seen a dead end in Pacman this code will not account for dead ends.
Also, I have included a solution to when the eyes would "wobble" between a wall that spans across the origin in my pseudocode.
Some pseudocode:
x = getRelativeOppositeLatitudinalCoord()
y
origX = x
while(eyesNotInPen())
x = getRelativeOppositeLatitudinalCoordofGate()
y = getRelativeOppositeLongitudinalCoordofGate()
if (getRelativeOppositeLatitudinalCoordofGate() == 0 && move(y) == false/*assume zero is neither left or right of the the gate and false means wall is in the way */)
while (move(y) == false)
move(origX)
x = getRelativeOppositeLatitudinalCoordofGate()
else if (move(x) == false) {
move(y)
endWhile
dtb23's suggestion of just picking a random direction at each corner, and eventually you'll find the monster-hole sounds horribly ineficient.
However you could make use of its inefficient return-to-home algorithm to make the game more fun by introducing more variation in the game difficulty. You'd do this by applying one of the above approaches such as your waypoints or the flood fill, but doing so non-deterministically. So at every corner, you could generate a random number to decide whether to take the optimal way, or a random direction.
As the player progresses levels, you reduce the likelihood that a random direction is taken. This would add another lever on the overall difficulty level in addition to the level speed, ghost speed, pill-eating pause (etc). You've got more time to relax while the ghosts are just harmless eyes, but that time becomes shorter and shorter as you progress.
Short answer, not very well. :) If you alter the Pac-man maze the eyes won't necessarily come back. Some of the hacks floating around have that problem. So it's dependent on having a cooperative maze.
I would propose that the ghost stores the path he has taken from the hole to the Pacman. So as soon as the ghost dies, he can follow this stored path in the reverse direction.
Knowing that pacman paths are non-random (ie, each specific level 0-255, inky, blinky, pinky, and clyde will work the exact same path for that level).
I would take this and then guess there are a few master paths that wraps around the entire
maze as a "return path" that an eyeball object takes pending where it is when pac man ate the ghost.
The ghosts in pacman follow more or less predictable patterns in terms of trying to match on X or Y first until the goal was met. I always assumed that this was exactly the same for eyes finding their way back.
Before the game begins save the nodes (intersections) in the map
When the monster dies take the point (coordinates) and find the
nearest node in your node list
Calculate all the paths beginning from that node to the hole
Take the shortest path by length
Add the length of the space between the point and the nearest node
Draw and move on the path
Enjoy!
My approach is a little memory intensive (from the perspective of Pacman era), but you only need to compute once and it works for any level design (including jumps).
Label Nodes Once
When you first load a level, label all the monster lair nodes 0 (representing the distance from the lair). Proceed outward labelling connected nodes 1, nodes connected to them 2, and so on, until all nodes are labelled. (note: this even works if the lair has multiple entrances)
I'm assuming you already have objects representing each node and connections to their neighbours. Pseudo code might look something like this:
public void fillMap(List<Node> nodes) { // call passing lairNodes
int i = 0;
while(nodes.count > 0) {
// Label with distance from lair
nodes.labelAll(i++);
// Find connected unlabelled nodes
nodes = nodes
.flatMap(n -> n.neighbours)
.filter(!n.isDistanceAssigned());
}
}
Eyes Move to Neighbour with Lowest Distance Label
Once all the nodes are labelled, routing the eyes is trivial... just pick the neighbouring node with the lowest distance label (note: if multiple nodes have equal distance, it doesn't matter which is picked). Pseudo code:
public Node moveEyes(final Node current) {
return current.neighbours.min((n1, n2) -> n1.distance - n2.distance);
}
Fully Labelled Example
For my PacMan game I made a somewhat "shortest multiple path home" algorithm which works for what ever labyrinth I provide it with (within my set of rules). It also works across them tunnels.
When the level is loaded, all the path home data in every crossroad is empty (default) and once the ghosts start to explore the labyrinth, them crossroad path home information keeps getting updated every time they run into a "new" crossroad or from a different path stumble again upon their known crossroad.
The original pac-man didn't use path-finding or fancy AI. It just made gamers believe there is more depth to it than it actually was, but in fact it was random. As stated in Artificial Intelligence for Games/Ian Millington, John Funge.
Not sure if it's true or not, but it makes a lot of sense to me. Honestly, I don't see these behaviors that people are talking about. Red/Blinky for ex is not following the player at all times, as they say. Nobody seems to be consistently following the player, on purpose. The chance that they will follow you looks random to me. And it's just very tempting to see behavior in randomness, especially when the chances of getting chased are very high, with 4 enemies and very limited turning options, in a small space. At least in its initial implementation, the game was extremely simple. Check out the book, it's in one of the first chapters.

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