Here's a method that uses a constant amount of memory, if you assume tail-call optimization prevents the call stack from growing unnecessarily. (code is in Python, but does not use any constructs that aren't easily ported)

```
#returns the value at the given position in the triangle of a particular size.
def valueAt(x,y,size):
#is position out of bounds?
if x >= size or y >= size or x > y:
return None
#is position on the left edge of the triangle?
if x == 0:
return y+1
#is position on the bottom edge of the triangle?
if y == size - 1:
return x + size
#is position on the right edge of the triangle?
if x == y:
return 3*size - 2 - x
#position must lie somewhere within the triangle.
return 3*size - 3 + valueAt(x-1, y-2, size-3)
```

This is a recursive function whose first four conditionals form the base case. If the coordinates lie out of bounds or on the edge of the triangle, we can easily find the value lying there. If the coordinates lie within the triangle's interior, we strip the big triangle like an onion, revealing a triangle three sizes smaller, and retrieve the value from that.

You can then take these values and print them by iterating through the necessary coordinates.

```
#adds spaces to the start of the string.
def pad(v, amt):
while len(v) < amt:
v = " " + v
return v
def showTriangle(size):
#figure out how many characters long each value should be,
#based on the length of the largest number
maxValue = size * (size+1) / 2
maxLength = len(str(maxValue))
for y in range(size):
print "\n",
for x in range(y+1):
val = valueAt(x,y,size)
if val:
print pad(str(val), maxLength),
for i in range(3, 12+1, 3):
showTriangle(i)
print "\n"
```

Result:

```
1
2 6
3 4 5
1
2 15
3 16 14
4 17 21 13
5 18 19 20 12
6 7 8 9 10 11
1
2 24
3 25 23
4 26 39 22
5 27 40 38 21
6 28 41 45 37 20
7 29 42 43 44 36 19
8 30 31 32 33 34 35 18
9 10 11 12 13 14 15 16 17
1
2 33
3 34 32
4 35 57 31
5 36 58 56 30
6 37 59 72 55 29
7 38 60 73 71 54 28
8 39 61 74 78 70 53 27
9 40 62 75 76 77 69 52 26
10 41 63 64 65 66 67 68 51 25
11 42 43 44 45 46 47 48 49 50 24
12 13 14 15 16 17 18 19 20 21 22 23
```

Edit: if your particular system doesn't implement tail-call optimization, you can implement the iterative form yourself:

```
def valueAt(x,y,size):
acc = 0
while True:
#is position out of bounds?
if x >= size or y >= size or x > y:
return None
#is position on the left edge of the triangle?
if x == 0:
return acc + y+1
#is position on the bottom edge of the triangle?
if y == size - 1:
return acc + x + size
#is position on the right edge of the triangle?
if x == y:
return acc + 3*size - 2 - x
#position must lie somewhere within the triangle.
acc += 3*size - 3
x-= 1
y -= 2
size -= 3
```

`m`

(which has size`log m`

when encoded binary) and you need to print`O(m^2)`

elements. So the running time is at least`O(2^(2t))`

with`t`

the size of the input. – Vincent van der Weele Oct 9 '13 at 12:03`n`

and print`n+1`

using`O(1)`

space given that simply storing the number requires`O(log(n))`

space? – 6502 Oct 10 '13 at 5:28