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Say I have a square from (0,0) to (z,z). 
Given a triangle within this square which has integer coordinates 
for all its vertices.
Find out the number of  triangles within this square which are 
congruent to this triangle and have integer coordinates. 
My algorithm is as follows--

 1) Find out the minimum bounding rectangle(MBR) for the given triangle.
 2) Find out the number of congruent triangles, y within that MBR,
    obtained after reflection, rotation of the given triangle. 
    y can be either 2,4 or 8.
 3) Now find out how many such MBR's can be drawn within the given 
    big square, say x;
    (This is similar to finding number of squares on a chess board)
 4) x*y is the required answer.

Am I counting some triangles more than once or I am missing something by this algorithm? It is a problem on online judge? It gives me wrong answer. I have thought a lot about it, but I am not able to figure it out.

share|improve this question
Interesting question...as it turns out, too interesting for me to let it go without a real answer. Enjoy! By the way, where did this problem come from...I don't think this one's in Project Euler? – Jim Lewis Jun 13 '10 at 22:56
@Jim: Even I forgot the name of online judge where it came from – avd Jun 16 '10 at 8:07
up vote 7 down vote accepted

The approach you describe is pretty close, but will not count all the congruent triangles in the grid.

The most significant omission is due to the fact that there are rotations that preserve integer coordinates, but are not multiples of 90 degrees.

Consider the triangle with vertices (0,0), (240,0), and (240,180). Rotate it counter-clockwise about the origin by arcsin(3/5), or approximately 37 degrees, to obtain a congruent triangle with vertices (0,0), (192,144), and (84,288).

The bounding box for the new triangle has a different aspect ratio than the original, which also introduces some difficulties.

Here's an algorithm that, given three points on an NxN grid, should enumerate all the congruent triangles in O(N3) time.

Let P=(x,y) denote a point with integer coordinates, and

T(p,q,r) a triangle formed from distinct points p, q, and r.

T(q,r,p), T(r,p,q), T(p,r,q) all denote the same triangle, so we will consider the triangle with

p < q < r

to be its canonical representation.

We can define p < q by the condition:

((p.y < q.y) OR ((p.y = p.y) AND (p.x < q.x)).

Two triangles T1=(A,B,C) and T2=(P,Q,R), with both T1 and T2 in canonical form, are congruent iff:

|AB| = |PQ|,
|BC| = |QR|, and 
|CA| = |RP|.

To avoid floating point comparisons, we can compare the squares of the lengths.

Consider a line segment AB, with A at the origin (0,0), A < B, and |AB|2 = L.

(Note that sqrt(L) is O(N), since each side of the triangle must fit within an NxN grid, with a maximum diagonal of sqrt(2)*N).

We can find the possible choices of B by testing all the points (x,y) within the triangle defined by

(0,ceil(sqrt(L)), and 
(ceil(sqrt(L), ceil(sqrt(L))

This requires calculating |AB|2 for O(N2) points, then applying symmetries to generate up to 4 points for each match found in the search area:

If B = (x,y) has x = 0, there are no additional points, since (0,-y) < (0,y), which violates the condition

A < B.

If x = y with x > 0, A < (-x, y) and so (-x, y) is a valid choice for B.

If y < x with x > 0, the points (y, x), (-x, y), and (-y, x) all satisfy the conditions.

Although we have searched O(N2) points, at most O(N) will have the correct length. (They will all lie on a circle of radius sqrt(L) and circumference 2*pi*sqrt(L) from the origin, and will be separated by at least one unit from each other.)

This procedure finds all the possible orientations of a line segment AB, with A < B, and |AB|2 = L. Keep this list of points B, then use the same procedure to create lists of points for values of L matching the other two sides of the prototype triangle.

Now we want to build a set of triangles (A, B, C), with A fixed at the origin, and B chosen from the list of points from the list we made for length |AB|. C can be determined in O(1) time by finding the intersection points of two circles, one centered at A with radius |AC|, and the other centered at B with radius |BC|. (This step is most easily accomplished by solving the circle intersection in floating point, then taking the nearest lattice points to the floating point solutions. The lattice points can be confirmed using integer math, then tested to see if any of them satisfy the constraint A < B < C. It is assumed that the floating point calculations are done with sufficient precision to guarantee an error of less than 0.5 units for the intersection points.)

Considering that each (A, B, C) differs from the prototype by only a rotation from a set of size O(N), and symmetries from a set of size O(1), we end up with a list of triangles of length O(N).

Depending on whether the prototype triangle is equilateral, isosceles, or scalene, we will need to consider 1, 3, or 6 permutations of the side lengths to find all the triangles (A,B,C) congruent to the prototype, with A < B < C, and A at the origin. Taking the various permutations into account, this list of triangles still has size O(N).

At this point, some triangles on the list may not actually fit on the grid (perhaps because one side had a length close to sqrt(2)*N and needs to be at an angle to the X axis). For isosceles and equilateral triangles, depending on the details of the search algorithm, some of the triangles may appear more than once, with the redundant triangles' vertices out of order. These can be pruned out of the list, again in O(N) time. The final list of triangles represents the complete set of congruent triangles with A fixed at the origin, meeting all the conditions we have imposed, and is a set of size O(N).

Finally, we allow point A to move away from the origin to some other grid point. There are O(N2) choices for A, and for each choice of A=(x,y), we make a list of O(N) translated triangles by adding the coordinates (x,y) to each of A, B, and C from the "origin" list. We check in O(1) time to make sure each of the translated A, B, C points is still on the NxN grid, and the ones that survive get added to the final output list. The runtime of this step is O(N3), and this dominates the runtime of the entire search algorithm.

Using the above example on a 289x289 grid, our prototype triangle has coordinates A=(0,0), B=(240,0), and C=(240,180). Let Z equal the origin (0,0).

|AB|2 is 57600. |BC|2 is 32400. |CA|2 is 90000.

From the first part of the algorithm, the points B with L = r2= 57600 from Z and Z < B are:

(0, 240), (240, 0), (144, 192), (192, 144), (-144, 192), (-192, 144)

The points C with L = 32400 and Z < C are:

(0, 180), (180, 0), (108, 144), (144, 108), (-108, 144), (-144, 108)

The points A with L = 90000 and Z < A are:

(84, 288), (288, 84), (-84, 288), (-288, 84), (180, 240), (240, 180), (-180, 240), (-240, 180)

The triangles obtained from these sets of coordinates, after taking all 6 permutations of the side lengths and pruning the ones that don't meet the conditions, are:

(0, 0),(-180, 240),(0, 240)   L= 90000 32400 57600
(0, 0),(0, 240),(180, 240)    L= 57600 32400 90000
(0, 0),(240, 0),(240, 180)    L= 57600 32400 90000
(0, 0),(192, 144),(84, 288)   L= 57600 32400 90000
(0, 0),(-192, 144),(-84, 288) L= 57600 32400 90000
(0, 0),(240, 0),(0, 180)      L= 57600 90000 32400
(0, 0),(0, 180),(240, 180)    L= 32400 57600 90000
(0, 0),(180, 0),(180, 240)    L= 32400 57600 90000
(0, 0),(108, 144),(-84, 288)  L= 32400 57600 90000
(0, 0),(-108, 144),(84, 288)  L= 32400 57600 90000
(0, 0),(180, 0),(0, 240)      L= 32400 90000 57600
(0, 0),(144, 108),(-144, 192) L= 32400 90000 57600
(0, 0),(-144, 108),(144, 192) L= 32400 90000 57600
(0, 0),(-240, 180),(0, 180)   L= 90000 57600 32400
(0, 0),(288, 84),(144, 192)   L= 90000 32400 57600
(0, 0),(-288, 84),(-144, 192) L= 90000 32400 57600
(0, 0),(-180, 240),(0, 240)   L= 90000 32400 57600

Translating these to the 289x289 grid and pruning the ones that don't fit, we get a final list of 43,504 triangles.

The first few:

(0, 0),(0, 240),(180, 240)  L= 57600 32400 90000
(0, 0),(240, 0),(240, 180)  L= 57600 32400 90000
(0, 0),(192, 144),(84, 288) L= 57600 32400 90000
(0, 0),(240, 0),(0, 180)    L= 57600 90000 32400
(0, 0),(0, 180),(240, 180)  L= 32400 57600 90000
(0, 0),(180, 0),(180, 240)  L= 32400 57600 90000
(0, 0),(180, 0),(0, 240)    L= 32400 90000 57600
(0, 0),(288, 84),(144, 192) L= 90000 32400 57600
(0, 1),(0, 241),(180, 241)  L= 57600 32400 90000
(0, 1),(240, 1),(240, 181)  L= 57600 32400 90000
(0, 1),(240, 1),(0, 181)    L= 57600 90000 32400

and the final few:

(288, 94),(0, 178),(144, 286)  L= 90000 32400 57600
(288, 95),(48, 275),(288, 275) L= 90000 57600 32400
(288, 95),(0, 179),(144, 287)  L= 90000 32400 57600
(288, 96),(48, 276),(288, 276) L= 90000 57600 32400
(288, 96),(0, 180),(144, 288)  L= 90000 32400 57600
(288, 97),(48, 277),(288, 277) L= 90000 57600 32400
(288, 98),(48, 278),(288, 278) L= 90000 57600 32400
(288, 99),(48, 279),(288, 279) L= 90000 57600 32400
(288, 100),(48, 280),(288, 280) L= 90000 57600 32400
(288, 101),(48, 281),(288, 281) L= 90000 57600 32400
(288, 102),(48, 282),(288, 282) L= 90000 57600 32400
(288, 103),(48, 283),(288, 283) L= 90000 57600 32400
(288, 104),(48, 284),(288, 284) L= 90000 57600 32400
(288, 105),(48, 285),(288, 285) L= 90000 57600 32400
(288, 106),(48, 286),(288, 286) L= 90000 57600 32400
(288, 107),(48, 287),(288, 287) L= 90000 57600 32400
(288, 108),(48, 288),(288, 288) L= 90000 57600 32400

The runtime was well under one second to generate this list for the 289x289 grid.

share|improve this answer
But these are not congruent triangles – avd Oct 5 '09 at 7:49
@Aditya: You're right, I typo-ed the second vertex....sorry about that! It's fixed now...both triangles have sides with length 240,180, and 300 and are therefore congruent. – Jim Lewis Oct 5 '09 at 8:28
@Jim Lewis How did you find out the vertices (0,0), (192,144), (84,288)? brute force? or some other method? – Lazer Oct 5 '09 at 8:53
@eSKay: A Pythagorean right triangle, having integer lengths for all the sides, has nice rational values for the sines and cosines of all its angles. I picked one with sides (3,4,5) and scaled it up so the rotated vertices would all lie on integer coordinates. – Jim Lewis Oct 5 '09 at 9:07
@Jim Lewis: Thank u very much for ur point – avd Oct 5 '09 at 12:21

It seems to me that you might be missing a lot of congruent triangles this way. For smaller triangles, there won't be many different angles that you can place a congruent triangle such that all of its vertices are lattice points. But, as the size of the triangle increases, there are more opportunities to snap to the grid, so you could end up with far more than 8 different orientations of the triangle.

Instead, designate one of the points of the example triangle as the origin. Try all the lattice points of a circle of the radius of the first side as locations for the second vertex. Once you've picked the candidate point, calculate the location of the third vertex, and if it is a lattice point too, then calculate how many times the resulting triangle fits into the square without rotation. The only symmetry you have to worry about is if the original triangle is isosceles or equilateral, which would cause you to over count triangles by a factor of 2 and 3 respectively.

share|improve this answer
Please give me an example of the case where I may miss in case of large triangles. Since it is in MBR, I think it cannot be more than 8 – avd Oct 5 '09 at 5:52
MBR means all its 3 vertices are on the one or the other sides of the minimum bounding rectangle. And also since we want lattice points only, we need not check for every combination – avd Oct 5 '09 at 5:56
I have a very strict time limit. The algorithm ur suggesting may take a lot of time – avd Oct 5 '09 at 6:04
But this would be quite fast. Even naively implemented, it's O(N) in the length of the shortest side of the triangle. – Jason Orendorff Nov 24 '09 at 14:01

Do you want to know exact number of triangles of just estimation?

For "exact" one I don't have a answer but I'm sure that usage of MBR for this is not a good idea - because:

  1. there may be triangles that intersect bounds of MBR
  2. there may be triangles with integer coords with zoom not equal to integer number (i.e. via rotation. It's a theory (because I don't have a example in hands) but we have to proove that it's wrong before going forward)

If you want to know an estimation than MBR is good enough

share|improve this answer
I want exact number – avd Oct 5 '09 at 6:00
I think that a good idea is to find out all possible triangles like this or smaller (if we search for max of triangles to fit) by trying all of 3-points within circumscribed circle. Then we need to fill out the square with this triangles (greedy algorithm may be good start for this) – Meta Oct 5 '09 at 6:05
Can u elborate more in ur post on this algorithm? I did not get the idea – avd Oct 5 '09 at 6:08
I mean than we should take all congruent triangles within the circumscribed circle. Than we use this set to fill the square. The complexity to get all triangles is: 1. get first point (~N^2 where N is proportional to lenght of triangle side) 2. get second point (~N^2) 3. try to get third point assuming that we have one of the side of square (1) so result complexity is N^2 to get full set of triangles. Brute force filling of square may be good for small squares / small sets of triangles - it's N(P) complexity task and you have to read Knut or some other guru to fill really big squares. – Meta Oct 5 '09 at 6:16
> "one of the side of square" - I meat "triangle" here – Meta Oct 5 '09 at 6:17

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