I’m looking for a way to let user edit the vertex of polygon after drawn.
Here’s demo from fabricjs
http://fabricjs.com/custom-controls-polygon
Is there anything similar in Konva?
Related
I am making a game in Unity3d and I need a pathfinding algorithm that can guide enemy's towards the player on a 3d surface. The problem is that the 3d surface can take any shape, so it can be a 3d sphere, cube, torus and many more shapes.
I tried using A* but for that formula I need the distance between the two points, and since the object is curved I cannot get that so easily. I found that you can use the Haversine formula if its a sphere, but that won't work on a torus or a random 3d shape.
I want this kind of result except with every kind of object:
https://www.youtube.com/watch?v=hvunNq7yVcU
Is there a way/algorithm that I can use to get that result. I know there is something called nav mesh but I need to program it myself. Also I cannot find how nav mesh approaches this dilema. I am going to use the triangles of my object as nodes.
So my question boils down to:
Does anyone know a algorithm for pathfinding that works on any 3d surface?
Thanks in advance.
I think your problem is that you are not using a graph, I would suggest that you look into a tutorial on how to create a graph, for the language you are using if you can, (this may also help here they are using edges to connect their node which is needed if you have more then one weight). If you do make a graph you will need a node class. Each node must contain pointers to any nodes that it is connected to and an ID of some kind. In your case that is probably all you need but it is also possible to assign a weight to each move if you also have an edge class (connectors between nodes) which would be used to connect the nodes. If you do have an edge class your nodes will have pointers to edges instead of other nodes and each edge will have a weight and a pointer to 1 or 2 nodes (depending on if it is a directed path or not). You can also make a graph class to contain all of your nodes and edges.
Summary:
make a node class and determine if you need the edge class (if everything has a weight of 1 you can get away with out it). Use the node class to create a graph to represent your map with each tile being a node with pointers to connected tiles. Use A* or dijkstra's algorithm to search your graph to find the shortest path.
note: most examples you will find will be for 2d graphs, yours is no different except that there are no bounds on yours, you just need to connect the nodes to their adjacent tiles.
Ok, here is the thing. Recently i decided i wanted to understand how Random map generation works. I found some papers and some arguments. The most interesting one was "Diamond Square algorithm" and "Midpoint Displacement". I still have to try to apply those to a software, but other than that, i ran into this site: http://www-cs-students.stanford.edu/~amitp/game-programming/polygon-map-generation/
As you can see, the idea is to use polygons. But i have no idea how to apply that a Tile-Based map, not even how to create those polygons using the tools i have (c++ and sdl). I am assuming there is no way to do it ( please correct me if i am wrong.) But if i am not, how does a non-tile map works, and how are these polygons generated?
This answer will not give you directly the answers you're looking for, but hopefully will get you close enough!
The Problem
I think what blocks you is how to represent the data. You're probably used to a 2D grid that simply represent the type of each tile. As you know, this is fine to handle a tile-based map, but doesn't properly allow you to model worlds where tiles are of a different shape.
Graphs
What I suggest to you, is to see the problem a bit differently. A grid is nothing more than a graph (more info) with nodes that have 4 (or 8 if you allow diagonals) implicit neighbor nodes. So first, what I would do if I was you, would be to move from your strict standard 2D grid to a more "loose" graph, where each node has a position, a position, a list of neighbors (in most cases you'll have corners with 2 neighbors, borders with 3 and "middle" tiles with 4) and finally a rendering component which simply draws your tile on screen at the given position. Once this is done, you should be able to have the exact same results on screen that you currently have with your "2D Tile-Based" engine by simply calling the rendering component with each node who's bounding box (didn't touch it in what you should add to your node, but I'll get back to this later) intersects with the camera's frustum (in a 2D world, it would most likely if the position +/- the size intersects the RECT currently being drawn).
Search
The more generic approach will also help you doing stuff like pathfinding with generic algorithms that explore nodes until they find a valid path (see A* or Dijkstra). Even if you decided to stick to a good old 2D Tile Map game, these techniques would still be useful!
Yeah but I want Polygons
I hear you! So, if you want polygons, basically all you need to do, is add to your nodes a list of vertices and the appropriate data that you might need to render your polygons (either vertex color, textures and U/V maps, etc...) and update your rendering component to do the appropriate OpenGL (this for example should help) calls to draw your nodes. Once again, the first step to iteratively upgrade your 2D Tile Engine to a polygon map engine would be to, for each tile in your map, give each of your nodes two triangles, a texture resource (the tile), and U/V mappings (0,0 - 0,1 - 1,0 and 1,1). Once again, when this step is done, you should have a "generic" polygon based tile map engine. The creation of most of this data can be created procedurally by calculating coordinates based on tile position, tile size, etc...
Convex Polygons
If you decide that you ever might need NPCs to navigate on your map or want to allow your player to navigate by clicking the map, I would suggest that you always use convex polygons (the triangle being the simplest for of a convex polygon). This allows your code that assume that two different positions on the same polygon can be navigated to in straight line.
Complex Maps
Based on the link you provided, you want to have rather complex maps. In this case, the author used Voronoi Diagrams to generate the polygons of the map. There are already solutions to do triangulation like that, but you might also want to use other techniques that are easier to work with if you're just switching to 3D like this one for example. Once you have interesting results, you should consider implementing serialization to save/open your map data from the game. If you want to create an editor, be aware that it might be a lot of work but can be worth it if you want people to help you creating maps or to add elements to the maps (like geometry that's not part of the terrain).
I went all over the place with this answer, but hopefully it helps!
Just iterate over all the tiles, and do a hit-test from the centre of the tile to the polys. Turn the type of the tile into the type of the polygon. Did you need more than that?
EDIT: Sorry, I realize that probably isn't helpful. Playing with procedural algorithms can be fun and profitable. Start with a loop that iterates over all tiles and chooses randomly whether or not the tile is occupied. Then, iterate over them again and choose whether it is occupied or its neighbour is.
Also, check out the source code for this: http://dustinfreeman.org/toys/wall7-dustin.html
How to place marker inside polygon (this polygon already on map)?
My thoughts are: find a way to inscribe for example circle to the polygon and find a center of this circle (it is not problem), but can't find way to inscribe circle.
Method getCenter() on LatLngBounds works not as expected, because math center of polygon can be out of this polygon visually.
As said Dr.Molle this is really duplicate of this question. So, for get center of polygon need to use programm realization of anything math algorithm for find center of polygon, there is no more easy way unfortunately.
I have some points on the edge(left image), and I want to construct a mesh(right), Is there any good algorithm to achieve it? many thanks!
image can see here http://ww3.sinaimg.cn/large/6a2c8e2bjw1dk8jr3t7eaj.jpg
To begin with, see Delauney triangulation. Look at this project: http://people.sc.fsu.edu/~jburkardt/c_src/triangulate/triangulate.html.
Edited because my original had too few details on edge-flipping, and when I tried to provided those details I found the TRIANGULATE project.
If the region is flat or quasi-flat look for Ear Clipping approach (http://www.geometrictools.com/Documentation/TriangulationByEarClipping.pdf). In the case of curved surface you need point inside the region and therefore you may need Constrained Delaunay Triangulation (otherwise some edges may not be included in the triangulation).
There is delaunayn function in geometry package for R language (see doc)
It takes an array of boundary points (as in your case) to create a Delaunay mesh on it.
You could also save your geometry into some well-known format, and use one of mesh generators.
today I have a (simple) rendering problem for you. My current project gets datas from a file to generate a SVG file. Drawing things as polygon is pretty easy thanks to the SVG format, but I have a single problem: some of my polygons are in AND out of the page (meaning that some parts of them are displayed while the rest is not shown due to the fact they are out of the display limit). In order to optimize the final SVG file I need to reduce my polygon to a simpler form.
Consider the grey rectangle as my page.
Consider the green polygon as the thing I actually draw.
First picture shows you the thing that I actually have while the second picture shows you the final result I want to have.
First I thought to reduce my polygon in simple triangles in order to only draw points in the display limits. But I think a simpler solution exists... if you have it do not hesitate to share it with me :)
EDIT:
I have this tricky case to handle as well :
Thank you.
Clipping a polygon with a rectangle. We reduce this problem to
clipping a polygon with a line. We reduce this to an even simpler problem:
clipping one edge of a polygon with a line. Which is really just
Finding the intersection of a line segment with a line (if it exists).
The last problem is pretty easy, considering that your lines are vertical or horizontal. Is that enough?