I found an optimal strategy in this paper: http://www.rand.org/pubs/research_memoranda/2006/RM408.pdf

Let's call this Blotto's strategy.

Look at the diagram above. Any move you make can be represented by a point on the triangle. The strategy in the paper says to pick a point at random in the hexagon. Choose points closer to the edge of the hexagon with higher probability (0 probability for the center of the hexagon, and linearly scale up to the maximum probability at the hexagon outline. Every point on the hexagon outline has equal probability.)

This solution is for "continuous" Blotto, but I assume you are interested in the discrete case (dividing N troops into 3 groups). Applying Blotto's strategy to the discrete case works perfectly well, when N is a multiple of 3. For other values of N, I was able to make a small adjustment on the hexagon border that works very well, but not perfectly.

If there is a strategy that can defeat this one, there must be some static move which wins against Blotto's strategy. There is none, except for when N is not a multiple of 3, then it seems that a move on the line where the big triangle and hexagon meet (e.g. the move <0,.5,.5>) will win against Blotto's strategy *slightly* more than lose. For N=100, the difference seems to be less than 1%, and continues to shrink for larger N.

Code to implement Blotto's strategy:

```
// generate a random number in the range [0,x) -- compensate for rand()%x being slightly un-uniform
int rnd( int x ) { int r; while ( 1 ) { r = rand(); if ( r < RAND_MAX/x*x ) return r % x; } }
// distance from center of triangle/hexagon to (x,y,z), multiplied by 3 (trilinear coordinates)
int hexagonalDist3( int x, int y, int z, int N ) { return max(max(abs(N-x*3),abs(N-y*3)),abs(N-z*3)); }
void generateRandomSimpleBlottoMove( int& x, int& y, int& z, int totalTroops )
{
int N = totalTroops;
while ( true )
{
x = rnd(N+1);
y = rnd(N+1);
z = N-x-y;
// keep only moves in hexagon, with moves closer to the border having higher probability
double relativeProbabilityOfKeepingThisMove = hexagonalDist3(x,y,z,N) > N ? 0 : hexagonalDist3(x,y,z,N);
// minor adjustment for hexagon border when N is not a multiple of 3 -- not perfect, but "very close"
if ( N % 3 != 0 && hexagonalDist3(x,y,z,N) == N )
relativeProbabilityOfKeepingThisMove = N*(N%3)/3;
// possibly keep our move
if ( rnd(N) < relativeProbabilityOfKeepingThisMove )
break;
}
}
```

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– belisarius Mar 1 '11 at 1:27