Make the FPGA optimization code work with the latest version of Verilator. Move JTAG TAP to swerv_wrapper module.

README.md

@@ -1,6 +1,6 @@
-# SweRV RISC-V Core<sup>TM</sup> 1.2 from Western Digital
+# SweRV RISC-V Core<sup>TM</sup> 1.3 from Western Digital
 
-This repository contains the SweRV Core<sup>TM</sup> 1.2 design RTL. The previous version can be found in [branch 1.1.](https://github.com/chipsalliance/Cores-SweRV/tree/branch1.1)
+This repository contains the SweRV Core<sup>TM</sup> 1.3 design RTL. The previous version can be found in [branch 1.2.](https://github.com/chipsalliance/Cores-SweRV/tree/branch1.2)
 The SweRV 1 series provides a 32-bit, machine-mode only, implementation of the RISC-V ISA including options I (base integer), M (multiply/divide) and C (compressed instructions from I and M).
 
 ## License

design/lib/beh_lib.sv

@@ -143,30 +143,23 @@ module rvdffe #( parameter WIDTH=1 )
 
    logic                      l1clk;
 
-`ifdef RV_FPGA_OPTIMIZE
-
-`ifndef PHYSICAL   
-   begin: genblock
-`endif
-     rvdffs #(WIDTH) dff ( .* );
-`ifndef PHYSICAL   
-   end
-`endif
-
-`else
-   
 `ifndef PHYSICAL   
    if (WIDTH >= 8) begin: genblock
 `endif
+
+`ifdef RV_FPGA_OPTIMIZE
+      rvdffs #(WIDTH) dff ( .* );
+`else
       rvclkhdr clkhdr ( .* );
       rvdff #(WIDTH) dff (.*, .clk(l1clk));
+`endif
+
 `ifndef PHYSICAL
    end
    else 
       $error("%m: rvdffe width must be >= 8");
 `endif
    
-`endif
    
 endmodule // rvdffe
 

design/swerv.sv

@@ -28,7 +28,6 @@ module swerv
    input logic [31:1]           rst_vec,
    input logic                  nmi_int,
    input logic [31:1]           nmi_vec,                            
-   input logic [31:1]           jtag_id,
    output logic                 core_rst_l,   // This is "rst_l | dbg_rst_l"  
 
    output logic [63:0] trace_rv_i_insn_ip,
@@ -370,13 +369,13 @@ module swerv
    input   logic                 dbg_bus_clk_en,
    input   logic                 dma_bus_clk_en,
 
-   // JTAG ports               
-   input logic             jtag_tck, // JTAG clk
-   input logic             jtag_tms, // JTAG TMS  
-   input logic             jtag_tdi, // JTAG tdi
-   input logic             jtag_trst_n, // JTAG Reset
-   output logic            jtag_tdo, // JTAG TDO
-   
+   //Debug module
+   input  logic                  dmi_reg_en,
+   input  logic [6:0]            dmi_reg_addr,
+   input  logic                  dmi_reg_wr_en,
+   input  logic [31:0]           dmi_reg_wdata,
+   output logic [31:0]           dmi_reg_rdata,
+   input  logic                  dmi_hard_reset,
 
    input logic [`RV_PIC_TOTAL_INT:1]           extintsrc_req,
    input logic                   timer_int,
@@ -972,40 +971,6 @@ module swerv
       .*
    );
 
-   // inputs from the JTAG - these will become input ports to the echx
-   logic                   dmi_reg_en;                // read or write
-   logic [6:0]             dmi_reg_addr;              // address of DM register
-   logic                   dmi_reg_wr_en;             // write instruction
-   logic [31:0]            dmi_reg_wdata;             // write data
-   // outputs from the dbg back to jtag
-   logic [31:0]            dmi_reg_rdata;
-   logic                   dmi_hard_reset;
-   
-   logic                   jtag_tdoEn;
-         
-  // Instantiat the JTAG/DMI             
-   dmi_wrapper  dmi_wrapper (
-           .scan_mode(scan_mode),           // scan mode
-
-           // JTAG signals
-           .trst_n(jtag_trst_n),           // JTAG reset
-           .tck   (jtag_tck),              // JTAG clock
-           .tms   (jtag_tms),              // Test mode select   
-           .tdi   (jtag_tdi),              // Test Data Input
-           .tdo   (jtag_tdo),              // Test Data Output           
-           .tdoEnable (jtag_tdoEn),       // Test Data Output enable             
-
-           // Processor Signals
-           .core_rst_n  (rst_l),          // Core reset, active low                  
-           .core_clk    (clk),            // Core clock                  
-           .jtag_id     (jtag_id),        // 32 bit JTAG ID 
-           .rd_data     (dmi_reg_rdata),  // 32 bit Read data from  Processor                       
-           .reg_wr_data (dmi_reg_wdata),  // 32 bit Write data to Processor                      
-           .reg_wr_addr (dmi_reg_addr),   // 32 bit Write address to Processor                   
-           .reg_en      (dmi_reg_en),     // 1 bit  Write interface bit to Processor                                   
-           .reg_wr_en   (dmi_reg_wr_en),   // 1 bit  Write enable to Processor               
-           .dmi_hard_reset   (dmi_hard_reset)   //a hard reset of the DTM, causing the DTM to forget about any outstanding DMI transactions
-); 
    
    // -----------------   DEBUG END -----------------------------
 
@@ -1348,4 +1313,3 @@ module swerv
 
    
 endmodule // swerv
-

design/swerv_wrapper.sv

@@ -393,6 +393,13 @@ module swerv_wrapper
    logic        icm_clk_override;
    logic        dec_tlu_core_ecc_disable;
   
+   logic        dmi_reg_en;
+   logic [6:0]  dmi_reg_addr;
+   logic        dmi_reg_wr_en;
+   logic [31:0] dmi_reg_wdata;
+   logic [31:0] dmi_reg_rdata;
+   logic        dmi_hard_reset;
+
    // Instantiate the swerv core
    swerv swerv (
           .*
@@ -404,6 +411,29 @@ module swerv_wrapper
         .*
         );
 
+  // Instantiate the JTAG/DMI
+   dmi_wrapper  dmi_wrapper (
+           .scan_mode(scan_mode),           // scan mode
+
+           // JTAG signals
+           .trst_n(jtag_trst_n),           // JTAG reset
+           .tck   (jtag_tck),              // JTAG clock
+           .tms   (jtag_tms),              // Test mode select
+           .tdi   (jtag_tdi),              // Test Data Input
+           .tdo   (jtag_tdo),              // Test Data Output
+           .tdoEnable (),                  // Test Data Output enable
+
+           // Processor Signals
+           .core_rst_n  (core_rst_l),     // Core reset, active low
+           .core_clk    (clk),            // Core clock
+           .jtag_id     (jtag_id),        // 32 bit JTAG ID
+           .rd_data     (dmi_reg_rdata),  // 32 bit Read data from  Processor
+           .reg_wr_data (dmi_reg_wdata),  // 32 bit Write data to Processor
+           .reg_wr_addr (dmi_reg_addr),   // 32 bit Write address to Processor
+           .reg_en      (dmi_reg_en),     // 1 bit  Write interface bit to Processor
+           .reg_wr_en   (dmi_reg_wr_en),   // 1 bit  Write enable to Processor
+           .dmi_hard_reset   (dmi_hard_reset)   //a hard reset of the DTM, causing the DTM to forget about any outstanding DMI transactions
+);
 
 endmodule
    

release-notes.md

@@ -1,3 +1,8 @@
+# SweRV RISC-V Core<sup>TM</sup> 1.3 from Western Digital
+## Release Notes
+1. Make the FPGA optimization code work with the latest version of Verilator.
+1. Move JTAG TAP to swerv_wrapper module.
+
 # SweRV RISC-V Core<sup>TM</sup> 1.2 from Western Digital
 ## Release Notes
 1. SWERV core RISCV compatibility improvements

testbench/asm/hello_world2.s

@@ -66,6 +66,6 @@ _finish:
 .data
 hw_data:
 .ascii "------------------------------------\n"
-.ascii "Hello World from SweRV EH1.2 @WDC !!\n"
+.ascii "Hello World from SweRV EH1.3 @WDC !!\n"
 .ascii "------------------------------------"
 .byte 0

testbench/tb_top.sv

@@ -100,7 +100,9 @@ module tb_top ( input logic core_clk, input logic reset_l, output finished);
 
    logic        [31:0]                  cycleCnt       ;
    logic                                mailbox_data_val;
+`ifndef VERILATOR
    logic                                finished;
+`endif
 
    wire                                 dma_hready_out;