You can find the number with the inclusion-exclusion principle. Let `distributions(itemCount,bucketCount)`

be the number of unrestricted distributions of `itemCount`

items to `bucketCount`

buckets. I disregard the lower limit because that's dealt with simply by subtracting `bucketCount*lowerLimit`

items.

The number of ways to distribute `itemCount`

items to `bucketCount`

buckets with each bucket containing at most `upperLimit`

items is the number of unrestricted distributions minus the number of unrestricted distributions where at least one bucket contains more than `upperLimit`

items. The latter can be calculated with the inclusion exclusion principle as follows:

There are `bucketCount`

choices of a bucket to contain at least `upperLimit+1`

items, there remain `itemCount - (upperLimit+1)`

items to distribute to `bucketCount`

buckets:

```
bucketCount * distributions(itemCount - (upperLimit+1), bucketCount)
```

must be subtracted from the number of unrestricted distributions.

But we have subtracted the distributions where two buckets contain more than `upperLimit`

items twice, we must correct that and add

```
nCr(bucketCount,2) * distributions(itemCount - 2*(upperLimit+1), bucketCount)
```

again, because there are `nCr(bucketCount,2)`

choices of the two buckets.

But we have subtracted the distributions where three buckets contain more than `upperLimit`

items thrice, and added it again thrice (`nCr(3,2)`

), so we have to subtract

```
nCr(bucketCount,3) * distributions(itemCount - 3*(upperLimit+1), bucketCount)
```

to rectify that. etc.

All in all, the number is

```
m
∑ (-1)^k * nCr(bucketCount,k) * distributions(itemCount - k*(upperLimit+1), bucketCount)
k=0
```

where

```
m = min { bucketCount, floor(itemCount/(upperLimit+1)) }
```

(since there is no way to distribute a negative number of items).

Corrected code from your gist with an implementation of the function to count the ways of distributing the items respecting lower and upper limits:

```
import math
def nCr(n,r):
f = math.factorial
return f(n) / f(r) / f(n-r)
def itemCount_cal(target, items, minValue):
return target- items*minValue
def distributions(itemCount, bucketCount):
# There's one way to distribute 0 items to any number of buckets: all get 0 items
if itemCount == 0:
return 1
# we can't distribute fewer than 0 items, and we need at least one bucket
if itemCount < 0 or bucketCount < 1:
return 0
# If there's only one bucket, there's only one way
if bucketCount == 1:
return 1
#get all possible solutions
# The number of ways to distribute n items to b buckets is
# nCr(n+b-1,n)
f = math.factorial
return f(itemCount + bucketCount-1)/(f(itemCount) * f(bucketCount-1))
def ways(items,buckets,lower,upper):
if upper < lower: # upper limit smaller than lower: impossible
return 0
if buckets*upper < items: # too many items: impossible
return 0
necessary = buckets*lower
if items == necessary: # just enough items to meet the minimum requirement
return 1
if items < necessary: # too few items: impossible
return 0
# put the minimum required number in each bucket, leaving
# items - necessary
# to distribute
left = items - necessary
# We have put 'lower' items in each bucket, so each bucket can now take
# at most (upper - lower) more
# any more, and the bucket is overfull
over = upper + 1 - lower
# maximal number of buckets we can put more than upper in at all
# after we fulfilled the minimum requirement
m = left // over
# We start with the number of ways to distribute the items disregarding
# the upper limit
ws = distributions(left,buckets)
# Sign for inclusion-exclusion, (-1)**k
sign = -1
# Number of overfull buckets
k = 1
while k <= m:
# Add or subtract the number of ways to distribute
# 'left' items to 'buckets' buckets with
# k buckets overfull
#
# nCr(buckets,k) choices of the buckets we overfill at the start
#
# That leaves (left - k*over) items to distribute.
ws += sign * nCr(buckets,k) * distributions(left - k*over,buckets)
# flip sign and increment number of overfull buckets
sign = -sign
k += 1
return ws
```

Note that for large numbers of items and buckets, calculating `nCr`

with the factorial is not the best way, it leads to large intermediate results and uses more operations than necessary.