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), .b(b), .c(c), .s(s), .cout() .g(g), .p() );
fulladder add1(.a(a), .b(b), .c(carry), .s(s), .cout() .g(g), .p() );
fulladder add2(.a(a), .b(b), .c(carry), .s(s), .cout() .g(g), .p() );
fulladder add3(.a(a), .b(b), .c(carry), .s(s), .cout() .g(g), .p() );
.p (p ), //input [3:0]
.g (g ), //input [3:0]
.c (carry), //output [3:1]
.cout (cout ) //output
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, carry, carry and cout.
To create a 16 bit adder you can use 4 of these 4 bit sections.