module gpif_rd (input gpif_clk, input gpif_rst, output [15:0] gpif_data, input gpif_rd, input gpif_ep, output reg gpif_empty_d, output reg gpif_empty_c, output reg gpif_flush, input sys_clk, input sys_rst, input [18:0] data_i, input src_rdy_i, output dst_rdy_o, input [18:0] resp_i, input resp_src_rdy_i, output resp_dst_rdy_o, output [31:0] debug ); wire [18:0] data_o; // occ bit indicates flush wire [17:0] resp_o; // no occ bit wire final_rdy_data, final_rdy_resp; // 33/257 Bug Fix reg [8:0] read_count; always @(negedge gpif_clk) if(gpif_rst) read_count <= 0; else if(gpif_rd) read_count <= read_count + 1; else read_count <= 0; // Data Path wire [18:0] data_int; wire src_rdy_int, dst_rdy_int; fifo_2clock_cascade #(.WIDTH(19), .SIZE(4)) rd_fifo_2clk (.wclk(sys_clk), .datain(data_i[18:0]), .src_rdy_i(src_rdy_i), .dst_rdy_o(dst_rdy_o), .space(), .rclk(~gpif_clk), .dataout(data_int), .src_rdy_o(src_rdy_int), .dst_rdy_i(dst_rdy_int), .occupied(), .arst(sys_rst)); reg [7:0] packet_count; wire consume_data_line = gpif_rd & ~gpif_ep & ~read_count[8]; wire produce_eop = src_rdy_int & dst_rdy_int & data_int[17]; wire consume_sop = consume_data_line & final_rdy_data & data_o[16]; wire consume_eop = consume_data_line & final_rdy_data & data_o[17]; fifo_cascade #(.WIDTH(19), .SIZE(10)) rd_fifo (.clk(~gpif_clk), .reset(gpif_rst), .clear(0), .datain(data_int), .src_rdy_i(src_rdy_int), .dst_rdy_o(dst_rdy_int), .space(), .dataout(data_o), .src_rdy_o(final_rdy_data), .dst_rdy_i(consume_data_line), .occupied()); always @(negedge gpif_clk) if(gpif_rst) packet_count <= 0; else if(produce_eop & ~consume_sop) packet_count <= packet_count + 1; else if(consume_sop & ~produce_eop) packet_count <= packet_count - 1; always @(negedge gpif_clk) if(gpif_rst) gpif_empty_d <= 1; else gpif_empty_d <= ~|packet_count; // Use occ bit to signal a gpif flush always @(negedge gpif_clk) if(gpif_rst) gpif_flush <= 0; else if(consume_eop & data_o[18]) gpif_flush <= ~gpif_flush; // Response Path wire [15:0] resp_fifolevel; wire consume_resp_line = gpif_rd & gpif_ep & ~read_count[4]; fifo_2clock_cascade #(.WIDTH(18), .SIZE(4)) resp_fifo_2clk (.wclk(sys_clk), .datain(resp_i[17:0]), .src_rdy_i(resp_src_rdy_i), .dst_rdy_o(resp_dst_rdy_o), .space(), .rclk(~gpif_clk), .dataout(resp_o), .src_rdy_o(final_rdy_resp), .dst_rdy_i(consume_resp_line), .occupied(resp_fifolevel), .arst(sys_rst)); // FIXME -- handle short packets always @(negedge gpif_clk) if(gpif_rst) gpif_empty_c <= 1; else gpif_empty_c <= resp_fifolevel < 16; // Output Mux assign gpif_data = gpif_ep ? resp_o[15:0] : data_o[15:0]; assign debug = { { 16'd0 }, { data_int[17:16], data_o[17:16], packet_count[3:0] }, { consume_sop, consume_eop, final_rdy_data, data_o[18], consume_data_line, consume_resp_line, src_rdy_int, dst_rdy_int} }; endmodule // gpif_rd