module histogram32 ( input wire clock, frame, reset, input wire hst_good, input wire [6:0] hst_data, input wire bus_ssel, bus_wren, input wire [6:0] bus_addr, input wire [15:0] bus_mosi, output wire [15:0] bus_miso, output wire bus_busy ); // signal declaration reg [3:0] int_case_reg, int_case_next; reg int_wren_reg, int_wren_next; reg [6:0] int_addr_reg, int_addr_next; reg [31:0] int_data_reg, int_data_next; reg [7:0] bus_addr_reg, bus_addr_next; reg [15:0] bus_miso_reg, bus_miso_next; reg bus_wren_reg, bus_wren_next; reg [15:0] bus_mosi_reg, bus_mosi_next; wire [31:0] q_a_wire; wire [15:0] q_b_wire; altsyncram #( .address_reg_b("CLOCK0"), .clock_enable_input_a("BYPASS"), .clock_enable_input_b("BYPASS"), .clock_enable_output_a("BYPASS"), .clock_enable_output_b("BYPASS"), .indata_reg_b("CLOCK0"), .intended_device_family("Cyclone III"), .lpm_type("altsyncram"), .numwords_a(80), .numwords_b(160), .operation_mode("BIDIR_DUAL_PORT"), .outdata_aclr_a("NONE"), .outdata_aclr_b("NONE"), .outdata_reg_a("CLOCK0"), .outdata_reg_b("CLOCK0"), .power_up_uninitialized("FALSE"), .read_during_write_mode_mixed_ports("OLD_DATA"), .read_during_write_mode_port_a("NEW_DATA_NO_NBE_READ"), .read_during_write_mode_port_b("NEW_DATA_NO_NBE_READ"), .widthad_a(7), .widthad_b(8), .width_a(32), .width_b(16), .width_byteena_a(1), .width_byteena_b(1), .wrcontrol_wraddress_reg_b("CLOCK0")) hst_ram_unit( .wren_a(int_wren_reg), .clock0(clock), .wren_b(bus_wren_reg), .address_a(int_addr_reg), .address_b(bus_addr_reg), .data_a(int_data_reg), .data_b(bus_mosi_reg), .q_a(q_a_wire), .q_b(q_b_wire), .aclr0(1'b0), .aclr1(1'b0), .addressstall_a(1'b0), .addressstall_b(1'b0), .byteena_a(1'b1), .byteena_b(1'b1), .clock1(1'b1), .clocken0(1'b1), .clocken1(1'b1), .clocken2(1'b1), .clocken3(1'b1), .eccstatus(), .rden_a(1'b1), .rden_b(1'b1)); // body always @(posedge clock) begin if (reset) begin int_wren_reg <= 1'b1; int_addr_reg <= 7'd0; int_data_reg <= 32'd0; int_case_reg <= 4'b0; bus_addr_reg <= 8'd0; bus_miso_reg <= 16'd0; bus_wren_reg <= 1'b0; bus_mosi_reg <= 16'd0; end else begin int_wren_reg <= int_wren_next; int_addr_reg <= int_addr_next; int_data_reg <= int_data_next; int_case_reg <= int_case_next; bus_addr_reg <= bus_addr_next; bus_miso_reg <= bus_miso_next; bus_wren_reg <= bus_wren_next; bus_mosi_reg <= bus_mosi_next; end end always @* begin bus_addr_next = bus_addr_reg; bus_miso_next = bus_miso_reg; bus_wren_next = 1'b0; bus_mosi_next = bus_mosi_reg; if (bus_ssel) begin bus_miso_next = q_b_wire; bus_addr_next = bus_addr; bus_wren_next = bus_wren; if (bus_wren) begin bus_mosi_next = bus_mosi; end end end always @* begin int_wren_next = int_wren_reg; int_addr_next = int_addr_reg; int_data_next = int_data_reg; int_case_next = int_case_reg; case (int_case_reg) 0: begin // write zeros int_addr_next = int_addr_reg + 7'd1; if (&int_addr_reg) begin int_wren_next = 1'b0; int_case_next = 4'd1; end end 1: begin int_wren_next = 1'b0; /* if (&int_data_reg) begin int_case_next = 4'd0; end else if (frame & hst_good) */ if (frame & hst_good) begin int_addr_next = hst_data; int_case_next = 4'd2; end end 2: begin int_case_next = 4'd3; end 3: begin int_case_next = 4'd4; end 4: begin int_case_next = 4'd1; if (~&q_a_wire) begin int_wren_next = 1'b1; int_data_next = q_a_wire + 32'd1; end end default: begin int_wren_next = 1'b0; int_addr_next = 7'd0; int_data_next = 32'd0; int_case_next = 4'd0; end endcase end // output logic assign bus_miso = bus_miso_reg; assign bus_busy = 1'b0; endmodule