Perlin noise is obtained as the sum of waveforms. The waveforms are obtained by interpolating random values, and the higher octave waveforms have smaller scaling factors whereas the interpolated random values are nearer to each other. To make this wrap around, you just need to properly interpolate around the y- and x-axes in the usual toroidal fashion, i.e. if your X-axis spans from x_min to x_max, and the leftmost random point (which is being interpolated) is at x0 and the rightmost at x1 (x_min < x0 < x1 < x_max), the value for the interpolated pixels right to x1 and left from x0 are obtained by interpolating from x1 to x0 (wrapping around the edges).

Here pseudocode for one of the octaves using linear interpolation. This assumes a 256 x 256 matrix where the Perlin noise grid size is a power of two pixels... just to make it readable. Imagine e.g. size==16:

```
wrappable_perlin_octave(grid, size):
for (x=0;x<256;x+=size):
for (y=0;y<256;y+=size):
grid[x][y] = random()
for (x=0;x<256;x+=size):
for (y=0;y<256;y+=size):
if (x % size != 0 || y % size != 0): # interpolate
ax = x - x % size
bx = (ax + size) % 256 # wrap-around
ay = y - y % size
by = (ay + size) % 256 # wrap-around
h = (x % size) / size # horizontal balance, floating-point calculation
v = (y % size) / size # vertical balance, floating-point calculation
grid[x][y] = grid[ax][ay] * (1-h) * (1-v) +
grid[bx][ay] * h * (1-v) +
grid[ax][by] * (1-h) * v +
grid[bx][by] * h * v
```