Below is a script that accomplishes what I've asked, as far as recoding integers that represent integer partitions of N with K parts. A better recoding method is needed for this approach to be practical for K > 4. This is definitely not a best or preferred approach. However, it's conceptually simple and easily argued as fundamentally unbiased. It's also very fast for small K. The script runs fine in Sage notebook and does not call Sage functions. It is NOT a script for random sampling. Random sampling per se is not the problem.

**The method:**

1.) Treat integer partitions as if their summands are concatenated together and padded with zeros according to size of largest summand in first lexical partition, e.g. [17,1,1,1] -> 17010101 & [5,5,5,5] -> 05050505

2.) Treat the resulting integers as if they are subtracted from the largest integer (i.e. the int representing the first lexical partition). e.g. 17010101 - 5050505 = 11959596

3.) Treat each resulting decreased integer as divided by a common denominator, e.g. 11959596/99 = 120804

**So, if we wanted to choose a random partition we would:**

1.) Choose a number between 0 and 120,804 (instead of a number between 5,050,505 and 17,010,101)

2.) Multiply the number by 99 and substract from 17010101

3.) Split the resulting integer according to how we treated each integer as being padded with 0's

**Pro's and Con's:** As stated in the body of the question, this particular recoding method doesn't do enough to greatly improve the chance of randomly selecting an integer representing a member of P. For small numbers of parts, e.g. K < 5 and substantially larger totals, e.g. N > 100, a function that implements this concept can be very fast because the approach avoids timely recursion (snake eating its tail) that slows other random partition functions or makes other functions impractical for dealing with large N.

At small K, the probability of drawing a member of P can be reasonable when considering how fast the rest of the process is. Coupled with quick random draws, decoding, and evaluation, this function can find uniform random partitions for combinations of N&K (e.g. N = 20000, K = 4) that are untennable with other algorithms. **A better way to recode integers is greatly needed to make this a generally powerful approach.**

```
import random
import sys
```

**First, some generally useful and straightforward functions**

```
def first_partition(N,K):
part = [N-K+1]
ones = [1]*(K-1)
part.extend(ones)
return part
def last_partition(N,K):
most_even = [int(floor(float(N)/float(K)))]*K
_remainder = int(N%K)
j = 0
while _remainder > 0:
most_even[j] += 1
_remainder -= 1
j += 1
return most_even
def first_part_nmax(N,K,Nmax):
part = [Nmax]
N -= Nmax
K -= 1
while N > 0:
Nmax = min(Nmax,N-K+1)
part.append(Nmax)
N -= Nmax
K -= 1
return part
#print first_partition(20,4)
#print last_partition(20,4)
#print first_part_nmax(20,4,12)
#sys.exit()
def portion(alist, indices):
return [alist[i:j] for i, j in zip([0]+indices, indices+[None])]
def next_restricted_part(part,N,K): # *find next partition matching N&K w/out recursion
if part == last_partition(N,K):return first_partition(N,K)
for i in enumerate(reversed(part)):
if i[1] - part[-1] > 1:
if i[0] == (K-1):
return first_part_nmax(N,K,(i[1]-1))
else:
parts = portion(part,[K-i[0]-1]) # split p
h1 = parts[0]
h2 = parts[1]
next = first_part_nmax(sum(h2),len(h2),(h2[0]-1))
return h1+next
""" *I don't know a math software that has this function and Nijenhuis and Wilf (1978)
don't give it (i.e. NEXPAR is not restricted by K). Apparently, folks often get the
next restricted part using recursion, which is unnecessary """
def int_to_list(i): # convert an int to a list w/out padding with 0'
return [int(x) for x in str(i)]
def int_to_list_fill(i,fill):# convert an int to a list and pad with 0's
return [x for x in str(i).zfill(fill)]
def list_to_int(l):# convert a list to an integer
return "".join(str(x) for x in l)
def part_to_int(part,fill):# convert an int to a partition of K parts
# and pad with the respective number of 0's
p_list = []
for p in part:
if len(int_to_list(p)) != fill:
l = int_to_list_fill(p,fill)
p = list_to_int(l)
p_list.append(p)
_int = list_to_int(p_list)
return _int
def int_to_part(num,fill,K): # convert an int to a partition of K parts
# and pad with the respective number of 0's
# This function isn't called by the script, but I thought I'd include
# it anyway because it would be used to recover the respective partition
_list = int_to_list(num)
if len(_list) != fill*K:
ct = fill*K - len(_list)
while ct > 0:
_list.insert(0,0)
ct -= 1
new_list1 = []
new_list2 = []
for i in _list:
new_list1.append(i)
if len(new_list1) == fill:
new_list2.append(new_list1)
new_list1 = []
part = []
for i in new_list2:
j = int(list_to_int(i))
part.append(j)
return part
```

**Finally, we get to the total N and number of parts K. The following will print partitions satisfying N&K in lexical order, with associated recoded integers**

```
N = 20
K = 4
print '#, partition, coded, _diff, smaller_diff'
first_part = first_partition(N,K) # first lexical partition for N&K
fill = len(int_to_list(max(first_part)))
# pad with zeros to 1.) ensure a strictly decreasing relationship w/in P,
# 2.) keep track of (encode/decode) partition summand values
first_num = part_to_int(first_part,fill)
last_part = last_partition(N,K)
last_num = part_to_int(last_part,fill)
print '1',first_part,first_num,'',0,' ',0
part = list(first_part)
ct = 1
while ct < 10:
part = next_restricted_part(part,N,K)
_num = part_to_int(part,fill)
_diff = int(first_num) - int(_num)
smaller_diff = (_diff/99)
ct+=1
print ct, part, _num,'',_diff,' ',smaller_diff
```

**OUTPUT:**

ct, partition, coded, _diff, smaller_diff

1 [17, 1, 1, 1] 17010101 0 0

2 [16, 2, 1, 1] 16020101 990000 10000

3 [15, 3, 1, 1] 15030101 1980000 20000

4 [15, 2, 2, 1] 15020201 1989900 20100

5 [14, 4, 1, 1] 14040101 2970000 30000

6 [14, 3, 2, 1] 14030201 2979900 30100

7 [14, 2, 2, 2] 14020202 2989899 30201

8 [13, 5, 1, 1] 13050101 3960000 40000

9 [13, 4, 2, 1] 13040201 3969900 40100

10 [13, 3, 3, 1] 13030301 3979800 40200

In short, integers in the last column could be a lot smaller.

**Why a random sampling strategy based on this idea is fundamentally unbiased:**

Each integer partition of N having K parts corresponds to one and only one recoded integer. That is, we don't pick a number at random, decode it, and then try to rearrange the elements to form a proper partition of N&K. Consequently, each integer (whether corresponding to partitions of N&K or not) has the same chance of being drawn. The goal is to inherently reduce the number of integers not corresponding to partitions of N with K parts, and so, to make the process of random sampling faster.