I would like to generate a set of rather big (~10,000-50,000) complete graphs `G=(V,E)`

with weighted edges in which the **sharp** triangle inequality holds -- so for every `v,u,w from V`

: *weight*(vu) + *weight(uw)* > *weight*(vw); weights are positive integers.

**EDIT**
The vertices are points in N-dim euclidean space and each weight of an edge *uv* has to be greater or equally than euclidean distance between *u* and *v* (so if the distance is e.g. 2.753 then the minimal, allowed weight is 3, but it may 4, 5, ...).

Up to now I came up with two naive approaches. Both of these methods are based on random generating points in N-dimensional Euclidean space.

Some notation:

- vu or vertex1-vertex2 denotes an edge
*E(v,u)*-- euclidean distance between v and u- for a double / real number
*r*,*ceil(r)*is an integer n such that n - 1 < r <= n (e.g. ceil(10.5) = 11, ceil(0.000000000001) = 1, ceil(172) = 172. *(vu,c)*-- edge vu has weight c

## Method 1 -- *local*

```
vertices = {v,u} -- v, u generated randomly
edges = {vu}
weights = {(vu,ceil(E(v,u))}
i = 0
while(i < total_number_of_vertices)
candidate = generate_new_point()
ok = true
foreach (vertex in vertices):
integer_distance = ceil(E(candidate,vertex))
if adding (candidate-vertex, integer_distance) to weights
violates the triangle inequality:
ok = false \\ this candidate is wrong
break \\ breaking for-each; start with new candidate
end_if
end_for_each
if(ok)
i++
add candidate to vertices,
for_each vertex in vertices:
add vertex-candidate to edges
add (vertex-candidate, ceil(E(candidate,vertex))) to weights
end_for_each
end_if
end_while
```

## Method 2 -- *global*

```
vertices = generate_points(total_number_of_vertices)
edges = complete Graph induced by vertices
weights = {}
for_each edge uv:
add (uv, ceil(E(u,v))) to weights
end_for_each
all_good = false
while (!all_good):
all_good = true
for_each edge in edges:
\\ this one has to be check in all triangles that edge belongs to
if edge violates triangle inequality:
\\ by appropriate I mean directly involved
update appropriate weights to satisfy triangle inequality
all_good = false \\ 'updating one edge may disturb other'
end_if
end_for_each
end_while
```

I am highly skeptical, if these methods will be efficient enough, so any help -- in improving them or suggesting completely different approaches -- would be appreciated.

If anything above is not clear enough I will provide more information.

If it will turn out, that keeping weights as positive `integers`

is too difficult I could consider having them as positive `doubles`

, but in such a case the floating-point precision would be potentially a problem to deal with [as I really need to have *sharp* triangle inequality]

notexhibit the required property? I'm not sure such a triangle exists, except for the degenerate case where weight(vu) + weight(uw) == weight(vw) (i.e. one vertex is on the line defined by the other two). – twalberg Nov 15 '13 at 20:18in generalthe distance is`real / double`

and I would like to have the weight`integer`

. – artur grzesiak Nov 15 '13 at 21:44