Here's a stab at it.

This is horribly inefficient, as I compute the Cartesian product of the two vectors, then compare each tuple combination. This also won't scale past 2 dimensions.

Also, I'm worried this isn't exactly what you are looking for, because I'm solving each equation independently. If you're looking for all the integer values that satisfy a 3-dimensional space bound by the system of inequalities, well, that's a bit of a brain bender for me, albeit very interesting.

Python anyone?

```
#sample data
A =[12,2,15,104,54,20]
B =[10,20,30,40,50,60]
C =[100,200,300,400,500,600]
import itertools
def eq1():
product = itertools.product(B,A) #construct Cartesian product of 2 lists
#list(product) returns a Cartesian product of tuples
# [(12, 10), (12, 20), (12, 30)... (2, 10), (2, 20)... (20, 60)]
#now, use a list comprehension to compare the values in each tuple,
# generating a list of only those that satisfy the inequality...
# then return the length of that list - which is the count
return len([ Bval for Bval, Aval in list(product) if Bval > Aval])
def eq2():
product = itertools.product(C,B)
return len([ Cval for Cval, Bval in list(product) if Cval>Bval])
def eq3():
product = itertools.product(A,C)
return len([ Aval for Aval, Cval in list(product) if Aval>Cval])
print eq1()
print eq2()
print eq3()
```

This sample data returns:

eq1 : 21

eq2 : 36

eq3 : 1

But doesn't know how to combine these answers into a single integer count of all 3 - there's some kind of union that's going to happen between the lists.

My sanity test is in equation 3, which returns '1' - because only when Aval = 104 does it satisfy Aval > Cval for Cval only at 100.