module fifo36_to_ll8 (input clk, input reset, input clear, input [35:0] f36_data, input f36_src_rdy_i, output f36_dst_rdy_o, output reg [7:0] ll_data, output ll_sof_n, output ll_eof_n, output ll_src_rdy_n, input ll_dst_rdy_n, output [31:0] debug); wire ll_sof, ll_eof, ll_src_rdy; assign ll_sof_n = ~ll_sof; assign ll_eof_n = ~ll_eof; assign ll_src_rdy_n = ~ll_src_rdy; wire ll_dst_rdy = ~ll_dst_rdy_n; wire f36_sof = f36_data[32]; wire f36_eof = f36_data[33]; wire f36_occ = f36_data[35:34]; wire advance, end_early; reg [1:0] state; assign debug = {29'b0,state}; always @(posedge clk) if(reset) state <= 0; else if(advance) if(ll_eof) state <= 0; else state <= state + 1; always @* case(state) 0 : ll_data = f36_data[31:24]; 1 : ll_data = f36_data[23:16]; 2 : ll_data = f36_data[15:8]; 3 : ll_data = f36_data[7:0]; default : ll_data = f36_data[31:24]; endcase // case (state) assign ll_sof = (state==0) & f36_sof; assign ll_eof = f36_eof & (((state==0)&(f36_occ==1)) | ((state==1)&(f36_occ==2)) | ((state==2)&(f36_occ==3)) | (state==3)); assign ll_src_rdy = f36_src_rdy_i; assign advance = ll_src_rdy & ll_dst_rdy; assign f36_dst_rdy_o = advance & ((state==3)|ll_eof); endmodule // ll8_to_fifo36