Creating a random vector whose sum is X (e.g. X=1000) is fairly straight forward:

```
import random
def RunFloat():
Scalar = 1000
VectorSize = 30
RandomVector = [random.random() for i in range(VectorSize)]
RandomVectorSum = sum(RandomVector)
RandomVector = [Scalar*i/RandomVectorSum for i in RandomVector]
return RandomVector
RunFloat()
```

The code above create a vector whose values are floats and sum is 1000.

I'm having difficulty creating a simple function for creating a vector whose values are integers and sum is X (e.g. X=1000*30)

```
import random
def RunInt():
LowerBound = 600
UpperBound = 1200
VectorSize = 30
RandomVector = [random.randint(LowerBound,UpperBound) for i in range(VectorSize)]
RandomVectorSum = 1000*30
#Sanity check that our RandomVectorSum is sensible/feasible
if LowerBound*VectorSize <= RandomVectorSum and RandomVectorSum <= UpperBound*VectorSum:
if sum(RandomVector) == RandomVectorSum:
return RandomVector
else:
RunInt()
```

Does anyone have any suggestions to improve on this idea? My code might never finish or run into recursion depth problems.

# Edit (July 9, 2012)

Thanks to Oliver, mgilson, and Dougal for their inputs. My solution is shown below.

- Oliver was very creative with the multinomial distribution idea
- Put simply, (1) is very likely to output certain solutions more so than others. Dougal demonstrated that the multinomial solution space distribution is not uniform or normal by a simple test/counter example of Law of Large Numbers. Dougal also suggested to use numpy's multinomial function which saves me a lot of trouble, pain, and headaches.
- To overcome (2)'s output issue, I use RunFloat() to give what appears (I haven't tested this so its just a superficial appearance) to be a more uniform distribution. How much of a difference does this make compared to (1)? I don't really know off-hand. It's good enough for my use though.
- Thanks again to mgilson for the alternative method that does not use numpy.

Here is the code that I have made for this edit:

## Edit #2 (July 11,2012)

I realized that the normal distribution is not correctly implemented, I have since modified it to the following:

```
import random
def RandFloats(Size):
Scalar = 1.0
VectorSize = Size
RandomVector = [random.random() for i in range(VectorSize)]
RandomVectorSum = sum(RandomVector)
RandomVector = [Scalar*i/RandomVectorSum for i in RandomVector]
return RandomVector
from numpy.random import multinomial
import math
def RandIntVec(ListSize, ListSumValue, Distribution='Normal'):
"""
Inputs:
ListSize = the size of the list to return
ListSumValue = The sum of list values
Distribution = can be 'uniform' for uniform distribution, 'normal' for a normal distribution ~ N(0,1) with +/- 5 sigma (default), or a list of size 'ListSize' or 'ListSize - 1' for an empirical (arbitrary) distribution. Probabilities of each of the p different outcomes. These should sum to 1 (however, the last element is always assumed to account for the remaining probability, as long as sum(pvals[:-1]) <= 1).
Output:
A list of random integers of length 'ListSize' whose sum is 'ListSumValue'.
"""
if type(Distribution) == list:
DistributionSize = len(Distribution)
if ListSize == DistributionSize or (ListSize-1) == DistributionSize:
Values = multinomial(ListSumValue,Distribution,size=1)
OutputValue = Values[0]
elif Distribution.lower() == 'uniform': #I do not recommend this!!!! I see that it is not as random (at least on my computer) as I had hoped
UniformDistro = [1/ListSize for i in range(ListSize)]
Values = multinomial(ListSumValue,UniformDistro,size=1)
OutputValue = Values[0]
elif Distribution.lower() == 'normal':
"""
Normal Distribution Construction....It's very flexible and hideous
Assume a +-3 sigma range. Warning, this may or may not be a suitable range for your implementation!
If one wishes to explore a different range, then changes the LowSigma and HighSigma values
"""
LowSigma = -3#-3 sigma
HighSigma = 3#+3 sigma
StepSize = 1/(float(ListSize) - 1)
ZValues = [(LowSigma * (1-i*StepSize) +(i*StepSize)*HighSigma) for i in range(int(ListSize))]
#Construction parameters for N(Mean,Variance) - Default is N(0,1)
Mean = 0
Var = 1
#NormalDistro= [self.NormalDistributionFunction(Mean, Var, x) for x in ZValues]
NormalDistro= list()
for i in range(len(ZValues)):
if i==0:
ERFCVAL = 0.5 * math.erfc(-ZValues[i]/math.sqrt(2))
NormalDistro.append(ERFCVAL)
elif i == len(ZValues) - 1:
ERFCVAL = NormalDistro[0]
NormalDistro.append(ERFCVAL)
else:
ERFCVAL1 = 0.5 * math.erfc(-ZValues[i]/math.sqrt(2))
ERFCVAL2 = 0.5 * math.erfc(-ZValues[i-1]/math.sqrt(2))
ERFCVAL = ERFCVAL1 - ERFCVAL2
NormalDistro.append(ERFCVAL)
#print "Normal Distribution sum = %f"%sum(NormalDistro)
Values = multinomial(ListSumValue,NormalDistro,size=1)
OutputValue = Values[0]
else:
raise ValueError ('Cannot create desired vector')
return OutputValue
else:
raise ValueError ('Cannot create desired vector')
return OutputValue
#Some Examples
ListSize = 4
ListSumValue = 12
for i in range(100):
print RandIntVec(ListSize, ListSumValue,Distribution=RandFloats(ListSize))
```

The code above can be found on github. It is part of a class I built for school. user1149913, also posted a nice explanation of the problem.