Our friend Wikipedia has a bit about Carry Look-Ahead. These are typically put together in 4 bit stages. 4 fulladders with additional logic to calculate the carries.

Assuming a fulladder as specified in the question, with the addition of a generate `g`

and propagate `p`

output, a 4 bit block might look some thing like:

```
module four_bit_carry_lookahead (
input [3:0] a,
input [3:0] b,
input c, //Carry in
output [3:0] s, //Sum
output cout //Carry
);
wire [3:1] carry; // 3:1 to align numbers with wikipedia article
wire [3:0] p;
wire [3:0] g;
fulladder add0(.a(a[0]), .b(b[0]), .c(c), .s(s[0]), .cout() .g(g[0]), .p([0]) );
fulladder add1(.a(a[1]), .b(b[1]), .c(carry[1]), .s(s[1]), .cout() .g(g[1]), .p([1]) );
fulladder add2(.a(a[2]), .b(b[2]), .c(carry[2]), .s(s[2]), .cout() .g(g[2]), .p([2]) );
fulladder add3(.a(a[3]), .b(b[3]), .c(carry[3]), .s(s[3]), .cout() .g(g[3]), .p([3]) );
carry_lookahead(
.p (p ), //input [3:0]
.g (g ), //input [3:0]
.c (carry), //output [3:1]
.cout (cout ) //output
);
endmodule
```

The addition outputs required are `g = a & b;`

`p = a | b;`

.

The logic to implement the carry_lookahead is still required, the wikipedia article should tell you what is required. They are C1, C2, C3 and C4 in this code that would be carry[1], carry[2], carry[3] and cout.

To create a 16 bit adder you can use 4 of these 4 bit sections.