In situations like these, you don't need to invoke the random number generator more than once. All you need is a table of cumulative probabilities:

```
double c[k] = // the probability that X <= k (k = 0,...)
```

Then generate a random number `0 <= r < 1`

, and take the first integer `X`

such that `c[X] > r`

. You can find this `X`

with a binary search.

To generate this table, we need the individual probabilities

```
p[k] = lambda^k / (k! e^lambda) // // the probability that X = k
```

If `lambda`

is large, this becomes wildly inaccurate, as you have found. But we can use a trick here: start at (or near) the largest value, with `k = floor[lambda]`

, and pretend for the moment that `p[k]`

is equal to `1`

. Then calculate `p[i]`

for `i > k`

using the recurrence relation

```
p[i+1] = (p[i]*lambda) / (i+1)
```

and for `i < k`

using

```
p[i-1] = (p[i]*i)/lambda
```

This ensures that the largest probabilities have the greatest possible precision.

Now just calculate `c[i]`

using `c[i+1] = c[i] + p[i+1]`

, up to the point where `c[i+1]`

is the same as `c[i]`

. Then you can normalise the array by dividing by this limiting value `c[i]`

; or you can leave the array as it is, and use a random number `0 <= r < c[i]`

.

See: http://en.wikipedia.org/wiki/Inverse_transform_sampling