`ifdef VCS `ifndef GL `include "caravel_mgmt_soc_litex/verilog/includes/rtl_caravel_vcs.v" `else `include "caravel_mgmt_soc_litex/verilog/includes/gl_caravel_vcs.v" `endif //`include "verilog/includes/user_project_vcs.v" `endif module caravel_top ; // parameter FILENAME = {"hex_files/",`TESTNAME,".hex"}; parameter FILENAME={"hex_files/",`TESTNAME,".hex"}; initial begin `ifdef VCS `ifdef ENABLE_SDF $vcdplusfile({`MAIN_PATH,"/sim/",`TAG,"/",`FTESTNAME,"/",`TESTNAME , `SDF_POSTFIX, ".vpd"}); `else $vcdplusfile({`MAIN_PATH,"/sim/",`TAG,"/",`FTESTNAME,"/",`TESTNAME ,".vpd"}); `endif $vcdpluson(); `else $dumpfile ({"sim/",`TAG,"/",`SIM,"-",`TESTNAME,"/",`SIM,"-",`TESTNAME,".vcd"}); $dumpvars (0, caravel_top); `endif end wire vddio_tb; // Common 3.3V padframe/ESD power wire vddio_2_tb; // Common 3.3V padframe/ESD power wire vssio_tb; // Common padframe/ESD ground wire vssio_2_tb; // Common padframe/ESD ground wire vdda_tb; // Management 3.3V power wire vssa_tb; // Common analog ground wire vccd_tb; // Management/Common 1.8V power wire vssd_tb; // Common digital ground wire vdda1_tb; // User area 1 3.3V power wire vdda1_2_tb; // User area 1 3.3V power wire vdda2_tb; // User area 2 3.3V power wire vssa1_tb; // User area 1 analog ground wire vssa1_2_tb; // User area 1 analog ground wire vssa2_tb; // User area 2 analog ground wire vccd1_tb; // User area 1 1.8V power wire vccd2_tb; // User area 2 1.8V power wire vssd1_tb; // User area 1 digital ground wire vssd2_tb; // User area 2 digital ground wire gpio_tb; // Used for external LDO control wire [38-1:0] mprj_io_tb; reg clock_tb; // CMOS core clock input; not a crystal wire resetb_tb; // Reset input (sense inverted) // Note that only two flash data pins are dedicated to the // management SoC wrapper. The management SoC exports the // quad SPI mode status to make use of the top two mprj_io // pins for io2 and io3. wire flash_csb_tb; wire flash_clk_tb; wire flash_io0_tb; wire flash_io1_tb; caravel uut ( .vddio (vddio_tb), .vddio_2 (vddio_2_tb), .vssio (vssio_tb), .vssio_2 (vssio_2_tb), .vdda (vdda_tb), .vssa (vssa_tb), .vccd (vccd_tb), .vssd (vssd_tb), .vdda1 (vdda1_tb), .vdda1_2 (vdda1_2_tb), .vdda2 (vdda2_tb), .vssa1 (vssa1_tb), .vssa1_2 (vssa1_2_tb), .vssa2 (vssa2_tb), .vccd1 (vccd1_tb), .vccd2 (vccd2_tb), .vssd1 (vssd1_tb), .vssd2 (vssd2_tb), .clock (clock_tb), .gpio (gpio_tb), .mprj_io (mprj_io_tb), .flash_csb(flash_csb_tb), .flash_clk(flash_clk_tb), .flash_io0(flash_io0_tb), .flash_io1(flash_io1_tb), .resetb (resetb_tb) ); spiflash #( FILENAME ) spiflash ( .csb(flash_csb_tb), .clk(flash_clk_tb), .io0(flash_io0_tb), .io1(flash_io1_tb), .io2(), // not used .io3() // not used ); mac macros(); // make speical variables for the mprj input to assign the input without writing to the output gpios // cocotb limitation #2587 wire bin0; wire bin0_en; wire bin1; wire bin1_en; wire bin2; wire bin2_en; wire bin3; wire bin3_en; wire bin4; wire bin4_en; wire bin5; wire bin5_en; wire bin6; wire bin6_en; wire bin7; wire bin7_en; wire bin8; wire bin8_en; wire bin9; wire bin9_en; wire bin10; wire bin10_en; wire bin11; wire bin11_en; wire bin12; wire bin12_en; wire bin13; wire bin13_en; wire bin14; wire bin14_en; wire bin15; wire bin15_en; wire bin16; wire bin16_en; wire bin17; wire bin17_en; wire bin18; wire bin18_en; wire bin19; wire bin19_en; wire bin20; wire bin20_en; wire bin21; wire bin21_en; wire bin22; wire bin22_en; wire bin23; wire bin23_en; wire bin24; wire bin24_en; wire bin25; wire bin25_en; wire bin26; wire bin26_en; wire bin27; wire bin27_en; wire bin28; wire bin28_en; wire bin29; wire bin29_en; wire bin30; wire bin30_en; wire bin31; wire bin31_en; wire bin32; wire bin32_en; wire bin33; wire bin33_en; wire bin34; wire bin34_en; wire bin35; wire bin35_en; wire bin36; wire bin36_en; wire bin37; wire bin37_en; assign mprj_io_tb[0] = (bin0_en) ? bin0 : 1'bz; assign mprj_io_tb[1] = (bin1_en) ? bin1 : 1'bz; assign mprj_io_tb[2] = (bin2_en) ? bin2 : 1'bz; assign mprj_io_tb[3] = (bin3_en) ? bin3 : 1'bz; assign mprj_io_tb[4] = (bin4_en) ? bin4 : 1'bz; assign mprj_io_tb[5] = (bin5_en) ? bin5 : 1'bz; assign mprj_io_tb[6] = (bin6_en) ? bin6 : 1'bz; assign mprj_io_tb[7] = (bin7_en) ? bin7 : 1'bz; assign mprj_io_tb[8] = (bin8_en) ? bin8 : 1'bz; assign mprj_io_tb[9] = (bin9_en) ? bin9 : 1'bz; assign mprj_io_tb[10] = (bin10_en) ? bin10 : 1'bz; assign mprj_io_tb[11] = (bin11_en) ? bin11 : 1'bz; assign mprj_io_tb[12] = (bin12_en) ? bin12 : 1'bz; assign mprj_io_tb[13] = (bin13_en) ? bin13 : 1'bz; assign mprj_io_tb[14] = (bin14_en) ? bin14 : 1'bz; assign mprj_io_tb[15] = (bin15_en) ? bin15 : 1'bz; assign mprj_io_tb[16] = (bin16_en) ? bin16 : 1'bz; assign mprj_io_tb[17] = (bin17_en) ? bin17 : 1'bz; assign mprj_io_tb[18] = (bin18_en) ? bin18 : 1'bz; assign mprj_io_tb[19] = (bin19_en) ? bin19 : 1'bz; assign mprj_io_tb[20] = (bin20_en) ? bin20 : 1'bz; assign mprj_io_tb[21] = (bin21_en) ? bin21 : 1'bz; assign mprj_io_tb[22] = (bin22_en) ? bin22 : 1'bz; assign mprj_io_tb[23] = (bin23_en) ? bin23 : 1'bz; assign mprj_io_tb[24] = (bin24_en) ? bin24 : 1'bz; assign mprj_io_tb[25] = (bin25_en) ? bin25 : 1'bz; assign mprj_io_tb[26] = (bin26_en) ? bin26 : 1'bz; assign mprj_io_tb[27] = (bin27_en) ? bin27 : 1'bz; assign mprj_io_tb[28] = (bin28_en) ? bin28 : 1'bz; assign mprj_io_tb[29] = (bin29_en) ? bin29 : 1'bz; assign mprj_io_tb[30] = (bin30_en) ? bin30 : 1'bz; assign mprj_io_tb[31] = (bin31_en) ? bin31 : 1'bz; assign mprj_io_tb[32] = (bin32_en) ? bin32 : 1'bz; assign mprj_io_tb[33] = (bin33_en) ? bin33 : 1'bz; assign mprj_io_tb[34] = (bin34_en) ? bin34 : 1'bz; assign mprj_io_tb[35] = (bin35_en) ? bin35 : 1'bz; assign mprj_io_tb[36] = (bin36_en) ? bin36 : 1'bz; assign mprj_io_tb[37] = (bin37_en) ? bin37 : 1'bz; endmodule // module that has all needed macros by cocotb module mac; reg [7:0] MPRJ_IO_PADS_1 = `ifdef MPRJ_IO_PADS_1 `MPRJ_IO_PADS_1 `else 0 `endif; /* number of user GPIO pads on user1 side */ reg [7:0] MPRJ_IO_PADS_2 = `ifdef MPRJ_IO_PADS_2 `MPRJ_IO_PADS_2 `else 0 `endif; /* number of user GPIO pads on user2 side */ reg [7:0] MPRJ_IO_PADS = `ifdef MPRJ_IO_PADS `MPRJ_IO_PADS `else 0 `endif; reg [7:0] MPRJ_PWR_PADS_1 =`ifdef MPRJ_PWR_PADS_1 `MPRJ_PWR_PADS_1 `else 0 `endif; /* vdda1, vccd1 enable/disable control */ reg [7:0] MPRJ_PWR_PADS_2 = `ifdef MPRJ_PWR_PADS_2 `MPRJ_PWR_PADS_2 `else 0 `endif; /* vdda2, vccd2 enable/disable control */ reg [7:0] MPRJ_PWR_PADS =`ifdef MPRJ_PWR_PADS `MPRJ_PWR_PADS `else 0 `endif; // Analog pads are only used by the "caravan" module and associated // modules such as user_analog_project_wrapper and chip_io_alt. reg [7:0] ANALOG_PADS_1 = `ifdef ANALOG_PADS_1 `ANALOG_PADS_1 `else 0 `endif; reg [7:0] ANALOG_PADS_2 = `ifdef ANALOG_PADS_2 `ANALOG_PADS_2 `else 0 `endif; reg [7:0] ANALOG_PADS = `ifdef ANALOG_PADS `ANALOG_PADS `else 0 `endif; // Type and size of soc_mem reg USE_CUSTOM_DFFRAM = `ifdef USE_CUSTOM_DFFRAM 1 `else 0 `endif; // don't change the following without double checking addr widths reg [7:0] MEM_WORDS = `ifdef MEM_WORDS `MEM_WORDS `else 0 `endif; // Number of columns in the custom memory; takes one of three values: // 1 column : 1 KB, 2 column: 2 KB, 4 column: 4KB reg [7:0] DFFRAM_WSIZE = `ifdef DFFRAM_WSIZE `DFFRAM_WSIZE `else 0 `endif; reg [7:0] DFFRAM_USE_LATCH = `ifdef DFFRAM_USE_LATCH `DFFRAM_USE_LATCH `else 0 `endif; // not really parameterized but just to easily keep track of the number // of ram_block across different modules reg [7:0] RAM_BLOCKS = `ifdef RAM_BLOCKS `RAM_BLOCKS `else 0 `endif; // Clock divisor default value reg [7:0] CLK_DIV = `ifdef CLK_DIV `CLK_DIV `else 0 `endif; // GPIO control default mode and enable for most I/Os // Most I/Os set to be user bidirectional pins on power-up. reg [7:0] MGMT_INIT = `ifdef MGMT_INIT `MGMT_INIT `else 0 `endif; reg [7:0] OENB_INIT = `ifdef OENB_INIT `OENB_INIT `else 0 `endif; reg [7:0] DM_INIT = `ifdef DM_INIT `DM_INIT `else 0 `endif; // GL reg GL = `ifdef GL 1 `else 0 `endif; endmodule