65. Ripple Carry Adder
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Solving Approach
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Code
// 1-bit Full Adder (to be used by the 4-bit RCA)
module full_adder_1bit (
input a, b, cin,
output sum, cout
); assign sum= a^b^cin;
assign cout=(a&b)|(b&cin)|(a&cin);
// TODO: implement 1-bit full adder (structural or dataflow)
endmodule
// 4-bit Ripple Carry Adder – chain 4 full adders
module rca4_chain (
input [3:0] a,
input [3:0] b,
input cin,
output [3:0] sum,
output cout
);
wire c0,c1,c2,c3,c4;
assign c0=cin;
full_adder_1bit fa0 (.a(a[0]), .b(b[0]), .cin(c0), .sum(sum[0]), .cout(c1));
full_adder_1bit fa1 (.a(a[1]), .b(b[1]), .cin(c1), .sum(sum[1]), .cout(c2));
full_adder_1bit fa2 (.a(a[2]), .b(b[2]), .cin(c2), .sum(sum[2]), .cout(c3));
full_adder_1bit fa3 (.a(a[3]), .b(b[3]), .cin(c3), .sum(sum[3]), .cout(c4));
// TODO: Declare internal ripple carries
// TODO: instantiate 4 full adders and chain carries
// TODO: drive cout
assign cout=c4;
endmodule
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