//======================================================= // This code is generated by Terasic System Builder //======================================================= module DE10_NANO_SoC_GHRD( //////////// CLOCK ////////// input FPGA_CLK1_50, input FPGA_CLK2_50, input FPGA_CLK3_50, //////////// HPS ////////// output [14: 0] HPS_DDR3_ADDR, output [ 2: 0] HPS_DDR3_BA, output HPS_DDR3_CAS_N, output HPS_DDR3_CK_N, output HPS_DDR3_CK_P, output HPS_DDR3_CKE, output HPS_DDR3_CS_N, output [ 3: 0] HPS_DDR3_DM, inout [31: 0] HPS_DDR3_DQ, inout [ 3: 0] HPS_DDR3_DQS_N, inout [ 3: 0] HPS_DDR3_DQS_P, output HPS_DDR3_ODT, output HPS_DDR3_RAS_N, output HPS_DDR3_RESET_N, input HPS_DDR3_RZQ, output HPS_DDR3_WE_N, //////////// LED ////////// output [ 7: 0] LED ); //======================================================= // REG/WIRE declarations //======================================================= wire hps_fpga_reset_n; wire fpga_clk_50; wire [6:0] fpga_led_internal; wire [63:0] adder_a_export; wire [63:0] adder_b_export; wire [63:0] adder_sum_export; // connection of internal logics assign LED[7: 1] = fpga_led_internal; assign fpga_clk_50 = FPGA_CLK1_50; simple_adder my_adder( .a(adder_a_export), .b(adder_b_export), .sum(adder_sum_export) ); //======================================================= // Structural coding //======================================================= soc_system u0( // Adder .adder_a_export(adder_a_export), .adder_b_export(adder_b_export), .adder_sum_export(adder_sum_export), //Clock&Reset .clk_clk(FPGA_CLK1_50), // clk.clk .reset_reset_n(hps_fpga_reset_n), // reset.reset_n //HPS ddr3 .memory_mem_a(HPS_DDR3_ADDR), // memory.mem_a .memory_mem_ba(HPS_DDR3_BA), // .mem_ba .memory_mem_ck(HPS_DDR3_CK_P), // .mem_ck .memory_mem_ck_n(HPS_DDR3_CK_N), // .mem_ck_n .memory_mem_cke(HPS_DDR3_CKE), // .mem_cke .memory_mem_cs_n(HPS_DDR3_CS_N), // .mem_cs_n .memory_mem_ras_n(HPS_DDR3_RAS_N), // .mem_ras_n .memory_mem_cas_n(HPS_DDR3_CAS_N), // .mem_cas_n .memory_mem_we_n(HPS_DDR3_WE_N), // .mem_we_n .memory_mem_reset_n(HPS_DDR3_RESET_N), // .mem_reset_n .memory_mem_dq(HPS_DDR3_DQ), // .mem_dq .memory_mem_dqs(HPS_DDR3_DQS_P), // .mem_dqs .memory_mem_dqs_n(HPS_DDR3_DQS_N), // .mem_dqs_n .memory_mem_odt(HPS_DDR3_ODT), // .mem_odt .memory_mem_dm(HPS_DDR3_DM), // .mem_dm .memory_oct_rzqin(HPS_DDR3_RZQ), // .oct_rzqin .hps_0_h2f_reset_reset_n(hps_fpga_reset_n), ); reg [25: 0] counter; reg led_level; always @(posedge fpga_clk_50 or negedge hps_fpga_reset_n) begin if (~hps_fpga_reset_n) begin counter <= 0; led_level <= 0; end else if (counter == 24999999) begin counter <= 0; led_level <= ~led_level; end else counter <= counter + 1'b1; end assign LED[0] = led_level; endmodule