# C++ Pascal's triangle

I'm looking for an explanation for how the recursive version of pascal's triangle works

The following is the recursive return line for pascal's triangle.

``````int get_pascal(const int row_no,const int col_no)
{
if (row_no == 0)
{
return 1;
}
else if (row_no == 1)
{
return 1;
}
else if (col_no == 0)
{
return 1;
}
else if (col_no == row_no)
{
return 1;
}
else
{
return(get_pascal(row_no-1,col_no-1)+get_pascal(row_no-1,col_no));
}
}
``````

I get how the algorithm works What I wonder is how the recursion does the work.

• Could you write the sample code as a complete function? It'll be easier for you to understand and anyone else to answer. – Roger Pate Nov 19 '09 at 15:11
• Can you post entire pascalRecursive code? – BostonLogan Nov 19 '09 at 15:16
• yes, sorry I have edited my entry now – starcorn Nov 19 '09 at 15:16
• Removed Pascal tag. Not Pascal language related. – Marco van de Voort Nov 26 '09 at 14:38
• Check out my answer on stackoverflow.com/questions/16709748 for a few implementation notes. – cristicbz May 23 '13 at 21:50

## 8 Answers

Your algorithm contains a couple of unnecessary predicates for the base cases. It can be stated more simply as follows:

``````int pascal(int row, int col) {
if (col == 0 || col == row) {
return 1;
} else {
return pascal(row - 1, col - 1) + pascal(row - 1, col);
}
}
``````

This of course assumes that you're guaranteeing that the arguments passed to the function are non-negative integers; you can always include an assertion if you can't impose such a guarantee from outside the function.

• is it efficient it seems to be calculating whole pyramid for every number – Muhammad Umer Aug 10 '16 at 0:33

Pascal's triangle is essentially the sum of the two values immediately above it....

``````           1
1   1
1   2   1
1   3   3   1
``````

etc

• In this, the 1's are obtained by adding the 1 above it with the blank space (0)
• For code, all the 1's are occupied in either the first column (0), or when the (col == row)

For these two border conditions, we code in special cases (for initialization). The main chunk of the code (the recursive part) is the actual logic.

(The condition 'row == 1' is not necessary)

Refer to the page for the source code:

``````#include <stdio.h>
int main()
{
int n, x, y, c, q;
printf("Pascal Triangle Program\n");
printf("Enter the number of rows: ");
scanf("%d",&n);

for (y = 0; y < n; y++)
{
c = 1;
for(q = 0; q < n - y; q++)
{
printf("%3s", " ");
}
for (x = 0; x <= y; x++)
{
printf("   %3d ",c);
c = c * (y - x) / (x + 1);
}
printf("\n");
}
printf("\n");
return 0;
}
``````

The output would be,

Pascal Triangle Program

Enter the number of rows: 11

``````                                  1

1      1

1      2      1

1      3      3      1

1      4      6      4      1

1      5     10     10      5      1

1      6     15     20     15      6      1

1      7     21     35     35     21      7      1

1      8     28     56     70     56     28      8      1

1      9     36     84    126    126     84     36      9      1

1     10     45    120    210    252    210    120     45     10      1
``````
• OP was looking for a recursive version. Still a nice iterative one. – Sumit Gera Jul 23 '13 at 7:19
• `c = c * (y - x) / (x + 1);` maybe explain this – Muhammad Umer Aug 10 '16 at 0:16

The most optimized way is this one:

``````int pascal(int row, int col) {
if (col == 0 || col == row) return 1;
else if(col == 1 || (col + 1) == row) return row;
else return pascal(row - 1, col - 1) + pascal(row - 1, col);
}
``````

Unlike Fox's algorithm it prevents recursive calls for values which can be easily computed right from the input values.

Pascal's triangle can be got from adding the two entries above the current one.

```  | 0          1          2          3            column
--+----------------------------------------------
0 | 1 (case 1)
1 | 1 (case 2) 1 (case 2)
2 | 1 (case 3) 2 (sum)    1 (case 4)
3 | 1 (case 3) 3 (sum)    3 (sum)    1 (case 4)

row
```

etc., for example column 2, row 3 = column 2, row 2 + column 1, row 2, where the cases are as follows:

``````if (row_no == 0) // case 1
{
return 1;
}
else if (row_no == 1) // case 2
{
return 1;
}
else if (col_no == 0) // case 3
{
return 1;
}
else if (col_no == row_no) // case 4
{
return 1;
}
else // return the sum
return pascalRecursive(height-1,width)+pascalRecursive(height-1,width-1);
``````

Here is the code of @kathir-softwareandfinance with more readable and more meaning variable names

``````#include <stdio.h>

int main()
{
int nOfRows, cols, rows, value, nOfSpace;
printf("Pascal Triangle Program\n");
printf("Enter the number of rows: ");
scanf("%d",&nOfRows);

for (rows = 0; rows < nOfRows; rows++)
{
value = 1;
for(nOfSpace = 0; nOfSpace < nOfRows - rows; nOfSpace++)
{
printf("%3s", " ");
}

for (cols = 0; cols <= rows; cols++)
{
printf("  %3d ",value);
value = value * (rows - cols) / (cols + 1);
}
printf("\n");
}
printf("\n");

return 0;
}
``````

Here is how the recursion works

``````We call v(i, j), it calls v(i - 1, j), which calls v(i - 2, j) and so on,
until we reach the values that are already calculated (if you do caching),
or the i and j that are on the border of our triangle.

Then it goes back up eventually to v(i - 1, j), which now calls v(i - 2, j - 1),
which goes all the way to the bottom again, and so on.

....................................................................
_ _ _ _ call v(i, j) _ _ _ _ _
/                              \
/                                \
/                                  \
call v(i - 1, j)                     v(i - 1, j - 1)
/                 \                   /               \
/                   \                 /                 \
call v(i - 2, j)  v(i - 2, j - 1)    v(i - 2, j - 1)    v(i - 2, j - 2)
....................................................................
``````

If you need to get the value often, and if you have enough memory:

``````class PascalTriangle
# unlimited size cache

public

def initialize
@triangle = Array.new
end

def value(i, j)
triangle_at(i, j)
end

private

def triangle_at(i, j)
if i < j
return nil
end

if @triangle[i].nil?
@triangle[i] = Array.new(i + 1)
else
return @triangle[i][j]
end

if (i == 0 || j == 0 || i == j)
@triangle[i][j] = 1
return @triangle[i][j]
end

@triangle[i][j] = triangle_at(i - 1, j) + triangle_at(i - 1, j - 1)
end
end
``````

Using ternary approach for optimization; only 1 return command needed.

``````int f(int i, int j) {
return (
(i <= 1 || !j || j == i) ? 1 :
(f(i - 1, j - 1) + f(i - 1, j))
);
}
``````

see explanation