Load_Store.tlv

\m4_TLV_version 1d: tl-x.org
\SV
   // This code can be found in: https://github.com/stevehoover/RISC-V_MYTH_Workshop
   
   m4_include_lib(['https://raw.githubusercontent.com/stevehoover/RISC-V_MYTH_Workshop/c1719d5b338896577b79ee76c2f443ca2a76e14f/tlv_lib/risc-v_shell_lib.tlv'])

\SV
   m4_makerchip_module   // (Expanded in Nav-TLV pane.)
\TLV

   // /====================\
   // | Sum 1 to 9 Program |
   // \====================/
   //
   // Program for MYTH Workshop to test RV32I
   // Add 1,2,3,...,9 (in that order).
   //
   // Regs:
   //  r10 (a0): In: 0, Out: final sum
   //  r12 (a2): 10
   //  r13 (a3): 1..10
   //  r14 (a4): Sum
   // 
   // External to function:
   m4_asm(ADD, r10, r0, r0)             // Initialize r10 (a0) to 0.
   // Function:
   m4_asm(ADD, r14, r10, r0)            // Initialize sum register a4 with 0x0
   m4_asm(ADDI, r12, r10, 1010)         // Store count of 10 in register a2.
   m4_asm(ADD, r13, r10, r0)            // Initialize intermediate sum register a3 with 0
   // Loop:
   m4_asm(ADD, r14, r13, r14)           // Incremental addition
   m4_asm(ADDI, r13, r13, 1)            // Increment intermediate register by 1
   m4_asm(BLT, r13, r12, 1111111111000) // If a3 is less than a2, branch to label named <loop>
   m4_asm(ADD, r10, r14, r0)            // Store final result to register a0 so that it can be read by main program
   m4_asm(SW, r0, r10, 10000)           // Store the value of r10 into address 17.
   m4_asm(LW, r17, r0, 10000)           // Load the value from 
   
   // Optional:
   // m4_asm(JAL, r7, 00000000000000000000) // Done. Jump to itself (infinite loop). (Up to 20-bit signed immediate plus implicit 0 bit (unlike JALR) provides byte address; last immediate bit should also be 0)
   m4_define_hier(['M4_IMEM'], M4_NUM_INSTRS)

   |cpu
      @0
         $reset = *reset;
      
      //Fetch
         // Next PC
         $pc[31:0] = (>>1$reset) ? '0 : 
                     (>>3$taken_br) ? >>3$br_tgt_pc : 
                     (>>3$is_load) ? >>3$inc_pc : >>1$inc_pc;
         
         $imem_rd_en = !$reset;
         $imem_rd_addr[31:0] = $pc[M4_IMEM_INDEX_CNT+1:2];
         
      @1         
         $instr[31:0] = $imem_rd_data[31:0];
         $inc_pc[31:0] = $pc + 32'd4;  
      // Decode   
         $is_i_instr = $instr[6:2] ==? 5'b0000x ||
                       $instr[6:2] ==? 5'b001x0 ||
                       $instr[6:2] == 5'b11001;
         $is_r_instr = $instr[6:2] ==? 5'b01011 ||
                       $instr[6:2] ==? 5'b10100 ||
                       $instr[6:2] ==? 5'b0110x;                       
         $is_b_instr = $instr[6:2] == 5'b11000;
         $is_u_instr = $instr[6:2] == 5'b0x101;
         $is_s_instr = $instr[6:2] == 5'b0100x;
         $is_j_instr = $instr[6:2] == 5'b11011;
         
         $imm[31:0] = $is_i_instr ? { {21{$instr[31]}} , $instr[30:20] } :
                      $is_s_instr ? { {21{$instr[31]}} , $instr[30:25] , $instr[11:8] , $instr[7] } :
                      $is_b_instr ? { {20{$instr[31]}} , $instr[7] , $instr[30:25] , $instr[11:8] , 1'b0} :
                      $is_u_instr ? { $instr[31:12] , 12'b0} : 
                      $is_j_instr ? { {12{$instr[31]}} , $instr[19:12] , $instr[20] , $instr[30:21] , 1'b0} : 32'b0;
         
         $rs2_valid = $is_r_instr || $is_s_instr || $is_b_instr;
         $rs1_valid = $is_r_instr || $is_s_instr || $is_b_instr || $is_i_instr;
         $rd_valid = $is_r_instr || $is_i_instr || $is_u_instr || $is_j_instr;
         $funct3_valid = $is_r_instr || $is_s_instr || $is_b_instr || $is_i_instr;
         $funct7_valid = $is_r_instr;
         
         ?$rs2_valid
            $rs2[4:0] = $instr[24:20];
         ?$rs1_valid
            $rs1[4:0] = $instr[19:15];
         ?$rd_valid
            $rd[4:0] = $instr[11:7];
         ?$funct3_valid
            $funct3[2:0] = $instr[14:12];
         ?$funct7_valid
            $funct7[6:0] = $instr[31:25];
            
         $opcode[6:0] = $instr[6:0];
         
         $dec_bits[10:0] = {$funct7[5],$funct3,$opcode};
         
         // Branch Instruction
         $is_beq = $dec_bits ==? 11'bx_000_1100011;
         $is_bne = $dec_bits ==? 11'bx_001_1100011;
         $is_blt = $dec_bits ==? 11'bx_100_1100011;
         $is_bge = $dec_bits ==? 11'bx_101_1100011;
         $is_bltu = $dec_bits ==? 11'bx_110_1100011;
         $is_bgeu = $dec_bits ==? 11'bx_111_1100011;
         
         // Arithmetic Instruction
         $is_add = $dec_bits ==? 11'b0_000_0110011;
         $is_addi = $dec_bits ==? 11'bx_000_0010011;
         $is_or = $dec_bits ==? 11'b0_110_0110011;
         $is_ori = $dec_bits ==? 11'bx_110_0010011;
         $is_xor = $dec_bits ==? 11'b0_100_0110011;
         $is_xori = $dec_bits ==? 11'bx_100_0010011;
         $is_and = $dec_bits ==? 11'b0_111_0110011;
         $is_andi = $dec_bits ==? 11'bx_111_0010011;
         $is_sub = $dec_bits ==? 11'b1_000_0110011;
         $is_slti = $dec_bits ==? 11'bx_010_0010011;
         $is_sltiu = $dec_bits ==? 11'bx_011_0010011;
         $is_slli = $dec_bits ==? 11'b0_001_0010011;
         $is_srli = $dec_bits ==? 11'b0_101_0010011;
         $is_srai = $dec_bits ==? 11'b1_101_0010011;
         $is_sll = $dec_bits ==? 11'b0_001_0110011;
         $is_slt = $dec_bits ==? 11'b0_010_0110011;
         $is_sltu = $dec_bits ==? 11'b0_011_0110011;
         $is_srl = $dec_bits ==? 11'b0_101_0110011;
         $is_sra = $dec_bits ==? 11'b1_101_0110011;
         
         // Load Instruction
         $is_load = $dec_bits ==? 11'bx_xxx_0000011;
         
         // Store Instruction
         $is_sb = $dec_bits ==? 11'bx_000_0100011;
         $is_sh = $dec_bits ==? 11'bx_001_0100011;
         $is_sw = $dec_bits ==? 11'bx_010_0100011;
         
         // Jump Instruction
         $lui = $dec_bits ==? 11'bx_xxx_0110111;
         $auipc = $dec_bits ==? 11'bx_xxx_0010111;
         $jal = $dec_bits ==? 11'bx_xxx_1101111;
         $jalr = $dec_bits ==? 11'bx_000_1100111;
         
      @2   
      // Register File Read
         $rf_rd_en1 = $rs1_valid;
         ?$rf_rd_en1
            $rf_rd_index1[4:0] = $rs1[4:0];
         
         $rf_rd_en2 = $rs2_valid;
         ?$rf_rd_en2
            $rf_rd_index2[4:0] = $rs2[4:0];
            
      // Branch Target PC       
         $br_tgt_pc[31:0] = $pc + $imm;
      
      // Input signals to ALU
         $src1_value[31:0] = ((>>1$rd == $rs1) && >>1$rf_wr_en) ? >>1$result : $rf_rd_data1[31:0];
         $src2_value[31:0] = ((>>1$rd == $rs2) && >>1$rf_wr_en) ? >>1$result : $rf_rd_data2[31:0];
         
      @3   
         
      // ALU
         $sltu_result = $src1_value < $src2_value ;
         $sltiu_result = $src1_value < $imm ;
         
         $result[31:0] = $is_addi ? $src1_value + $imm :
                         $is_add ? $src1_value + $src2_value : 
                         $is_or ? $src1_value | $src2_value : 
                         $is_ori ? $src1_value | $imm :
                         $is_xor ? $src1_value ^ $src2_value :
                         $is_xori ? $src1_value ^ $imm :
                         $is_and ? $src1_value & $src2_value :
                         $is_andi ? $src1_value & $imm :
                         $is_sub ? $src1_value - $src2_value :
                         $is_slti ? (($src1_value[31] == $imm[31]) ? $sltiu_result : {31'b0,$src1_value[31]}) :
                         $is_sltiu ? $sltiu_result :
                         $is_slli ? $src1_value << $imm[5:0] :
                         $is_srli ? $src1_value >> $imm[5:0] :
                         $is_srai ? ({{32{$src1_value[31]}}, $src1_value} >> $imm[4:0]) :
                         $is_sll ? $src1_value << $src2_value[4:0] :
                         $is_slt ? (($src1_value[31] == $src2_value[31]) ? $sltu_result : {31'b0,$src1_value[31]}) :
                         $is_sltu ? $sltu_result :
                         $is_srl ? $src1_value >> $src2_value[5:0] :
                         $is_sra ? ({{32{$src1_value[31]}}, $src1_value} >> $src2_value[4:0]) :
                         $lui ? ({$imm[31:12], 12'b0}) :
                         $auipc ? $pc + $imm :
                         $jal ? $pc + 4 :
                         $jalr ? $pc + 4 : 
                         ($is_load || $is_s_instr) ? $src1_value + $imm : 32'bx;
                         
      // Register File Write
         $rf_wr_en = ($rd_valid && $valid && $rd != 5'b0) || >>2$valid_load;
         ?$rf_wr_en
            $rf_wr_index[4:0] = !$valid ? >>2$rd[4:0] : $rd[4:0];
      
         $rf_wr_data[31:0] = !$valid ? >>2$ld_data[31:0] : $result[31:0];
      
      // Branch
         $taken_br = $is_beq ? ($src1_value == $src2_value) :
                     $is_bne ? ($src1_value != $src2_value) :
                     $is_blt ? (($src1_value < $src2_value) ^ ($src1_value[31] != $src2_value[31])) :
                     $is_bge ? (($src1_value >= $src2_value) ^ ($src1_value[31] != $src2_value[31])) :
                     $is_bltu ? ($src1_value < $src2_value) :
                     $is_bgeu ? ($src1_value >= $src2_value) : 1'b0;
                     
         $valid_taken_br = $valid && $taken_br;
         
      // Load
         $valid_load = $valid && $is_load;
         $valid = !(>>1$valid_taken_br || >>2$valid_taken_br || >>1$valid_load || >>2$valid_load);
         
         
      @4
         $dmem_rd_en = $valid_load;
         $dmem_wr_en = $valid && $is_s_instr;
         $dmem_addr[3:0] = $result[5:2];
         $dmem_wr_data[31:0] = $src2_value[31:0];
         
      @5   
         $ld_data[31:0] = $dmem_rd_data[31:0];
         
      // Note: Because of the magic we are using for visualisation, if visualisation is enabled below,
      //       be sure to avoid having unassigned signals (which you might be using for random inputs)
      //       other than those specifically expected in the labs. You'll get strange errors for these.

         `BOGUS_USE($is_beq $is_bne $is_blt $is_bge $is_bltu $is_bgeu)
   // Assert these to end simulation (before Makerchip cycle limit).
   *passed = |cpu/xreg[17]>>5$value == (1+2+3+4+5+6+7+8+9);
   *failed = 1'b0;
   
   // Macro instantiations for:
   //  o instruction memory
   //  o register file
   //  o data memory
   //  o CPU visualization
   |cpu
      m4+imem(@1)    // Args: (read stage)
      m4+rf(@2, @3)  // Args: (read stage, write stage) - if equal, no register bypass is required
      m4+dmem(@4)    // Args: (read/write stage)
   
   m4+cpu_viz(@4)    // For visualisation, argument should be at least equal to the last stage of CPU logic
                       // @4 would work for all labs
\SV
   endmodule