# Given an integer z<=10^100, find the smallest row of Pascal's triangle that contains z [closed]

How can I find an algorithm to solve this problem using C++: given an integer z<=10^100, find the smallest row of Pascal's triangle that contains the number z.

``````    1
1 1
1 2 1
1 3 3 1
1 4 6 4 1
``````

For example if z=6 => result is on the 4th row.

Another way to describe the problem: given integer z<=10^100, find the smallest integer n: exist integer k so that C(k,n) = z.

C(k,n) is combination of n things taken k at a time without repetition

-

## closed as off-topic by DarkWanderer, Sneftel, Seymour, Blazemonger, SebApr 14 '14 at 16:01

• This question does not appear to be about programming within the scope defined in the help center.
If this question can be reworded to fit the rules in the help center, please edit the question.

What have you tried so far? –  Absurd-Mind Apr 14 '14 at 10:25
@user3531460 please paste your code –  tinky_winky Apr 14 '14 at 10:31
I think that's rather a math problem than a programming one - by your example, any algorithm would have to perform in order of 5864079763474581 operations best-case. Which is quite long time. Better off asking on math.stackexchange.com –  DarkWanderer Apr 14 '14 at 10:58
@DarkWanderer I believe it is a computer programming problem and that the user is seeking an algorithm to solve it. Also your conclusion is not right. There may be an algorithm that is faster than linear to solve this problem. For instance to find the smallest number x such that phi(x) = K where k is a constant one performs way less then K operations. –  Ivaylo Strandjev Apr 14 '14 at 11:13
@privatedatapublicchannel2 any number N will appear in the PT at the row N+1, so there's no "invalid" entries. –  DarkWanderer Apr 14 '14 at 11:47

EDIT This solution needs Logarithmic time, it's `O(Log z)`. Or maybe `O( (Log z)^2 )`.

Say you are looking for `n,k` where `Binomial(n,k)==z` for a given z.

1. Each row has its largest value in the middle, so starting from `n=0` you increase the row number, `n`, as long as the middle value is smaller than the given number. Actually, 10^100 isn't that big, so before row 340 you find a position `n0,k0=n0/2` where the value from the triangle is larger than or equal to `z`: `Binomial(n0,k0)>=z`

2. You walk to the left, i.e. you decrease the column number `k`, until eventually you find a value smaller than `z`. If there was a matching value in that row you would have hit it by now. `k` is not very large, less than 170, so this step won't be executed more often than that and does not present a performance problem.

3. From here you walk down, increasing `n`. Here you will find a steadily increasing value of `Binomial[n,k]`. Continue with 3 until the value gets bigger than or equal to `z`, then goto 2.

EDIT: This step 3 can loop for a very long time when the row number `n` is large, so instead of checking each `n` linearly you can do a binary search for `n` with `Binomial(n,k) >= z > Binomial(n-1,k)`, then it only needs `Log(n)` time.

A Python implementation looks like this, C++ is similar but somewhat more cumbersome because you need to use an additional library for arbitrary precision integers:

``````# Calculate (n-k+1)* ... *n
def getnk( n, k ):
a = n
for u in range( n-k+1, n ):
a = a * u
return a

# Find n such that Binomial(n,k) >= z and Binomial(n-1,k) < z
def find_n( z, k, n0 ):
kfactorial = k
for u in range(2, k):
kfactorial *= u

xk = z * kfactorial

nk0 = getnk( n0, k )
n1=n0*2
nk1 = getnk( n1, k )

# duplicate n while the value is too small
while nk1 < xk:
nk0=nk1
n0=n1
n1*=2
nk1 = getnk( n1, k )
# do a binary search
while n1 > n0 + 1:
n2 = (n0+n1) // 2
nk2 = getnk( n2, k )
if nk2 < xk:
n0 = n2
nk0 = nk2
else:
n1 = n2
nk1 = nk2

return n1, nk1 // kfactorial

def find_pos( z ):
n=0
k=0
nk=1

# start by finding a row where the middle value is bigger than z
while nk < z:
# increase n
n = n + 1
nk = nk * n // (n-k)
if nk >= z:
break
# increase both n and k
n = n + 1
k = k + 1
nk = nk * n // k

# check all subsequent rows for a matching value
while nk != z:
if nk > z:
# decrease k
k = k - 1
nk = nk * (k+1) // (n-k)
else:
# increase n
# either linearly
#  n = n + 1
#  nk = nk * n // (n-k)
# or using binary search:
n, nk = find_n( z, k, n )
return n, k

z = 56476362530291763837811509925185051642180136064700011445902684545741089307844616509330834616
print( find_pos(z) )
``````

It should print

``````(5864079763474581, 6)
``````
-
what is an answer here? which row is it, is this 3113? I think this is not correct –  tinky_winky Apr 14 '14 at 13:26
Yes, it would be 3113, because x==Binomial(3113, 47). There is no smaller row containing that number. –  pentadecagon Apr 14 '14 at 13:56
Score one. I have a bad feeling, though - this algorithm would take really long time for the testing data in question (n = 5864079763474581). Also, it's linear @user189 ;) –  DarkWanderer Apr 14 '14 at 14:08
@user3531460 Fixed by doing binary search. Now it should be quick for any input. –  pentadecagon Apr 14 '14 at 14:59

Stirling estimation for n! can be used to find first row in triangle with binomial coefficient bigger or equal to a given x. Using this estimation we can derive lower and upper bound for

and then by observation that this is the maximum coefficient in row that expands 2n:

P( 2n, 0), P( 2n, 1), P( 2n, 2), ..., P( 2n, 2n -1), P( 2n, 2n)

we can find first row with maximum binomial coefficient bigger or equal to a given x. This is the first row in which x can be looking for, this is not possible that x can be found in the row smaller than this. Note: this may be right hint and give an answer immediately in some cases. At the moment I cannot see other way than to start a brute force search from this row.

``````template <class T>
T binomial_coefficient(unsigned long n, unsigned long k) {
unsigned long i;
T b;
if (0 == k || n == k) {
return 1;
}
if (k > n) {
return 0;
}
if (k > (n - k)) {
k = n - k;
}
if (1 == k) {
return n;
}
b = 1;
for (i = 1; i <= k; ++i) {
b *= (n - (k - i));
if (b < 0) return -1; /* Overflow */
b /= i;
}
return b;
}
``````

Stirling:

``````double stirling_lower_bound( int n) {
double n_ = n / 2.0;
double res = pow( 2.0, 2 * n_);
res /= sqrt( n_ * M_PI);
return res * exp( ( -1.0) / ( 6 * n_));
}

double stirling_upper_bound( int n) {
double n_ = n / 2.0;
double res = pow( 2.0, 2 * n_) ;
res /= sqrt( n_ * M_PI);
return res * exp( 1.0 / ( 24 * n_));
}

int stirling_estimate( double x) {
int n = 1;
while ( stirling_lower_bound( n) <= x) {
if ( stirling_upper_bound( n) > x) return n;
++n;
}
return n;
}
``````

usage:

``````long int search_coefficient( unsigned long int &n, unsigned long int x) {
unsigned long int k = n / 2;
long long middle_coefficient = binomial_coefficient<long long>( n, k);
if( middle_coefficient == x) return k;

unsigned long int right = binomial_coefficient<unsigned long>( n, ++k);
while ( x != right) {

while( x < right ||  x < ( right * ( n + 1) / ( k + 1))) {
right = right * ( n + 1) / ( ++k) - right;
}
if ( right == x) return k;
right = right * ( ++n) / ( ++k);
if( right > x) return -1;
}
return k;
}

/*
*
*/
int main(int argc, char** argv) {

long long x2 = 1365;
unsigned long int n = stirling_estimate( x2);
long int k = search_coefficient( n, x2);
std::cout << "row:" << n <<", column: " << k;
return 0;
}
``````

output:

row:15, column: 11

-
Again, incorrect results for number 8: the estimation is 5, but the value is actually at row 9. Doesn't help us at all. –  DarkWanderer Apr 14 '14 at 14:02
@DarkWanderer this returns correctly 5 but this is not what you think it should return –  tinky_winky Apr 14 '14 at 14:08
If you know what it should return, share; don't play "secret knowledge" game. It's not constructive. –  DarkWanderer Apr 14 '14 at 14:10
@DarkWanderer please read this answer again, "first row with maximum binomial coefficient bigger or equal to a given x." –  tinky_winky Apr 14 '14 at 14:12
@user3531460 updated, posted complete solution –  tinky_winky Apr 14 '14 at 17:58