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////////////////////////////////////////////////////////////////////// //// //// //// or1200_monitor.v //// //// //// //// OR1200 processor monitor module //// //// //// //// Author(s): //// //// - Damjan Lampret, lampret@opencores.org //// //// - Julius Baxter, julius@opencores.org //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2009, 2010 Authors and OPENCORES.ORG //// //// //// //// This source file may be used and distributed without //// //// restriction provided that this copyright statement is not //// //// removed from the file and that any derivative work contains //// //// the original copyright notice and the associated disclaimer. //// //// //// //// This source file is free software; you can redistribute it //// //// and/or modify it under the terms of the GNU Lesser General //// //// Public License as published by the Free Software Foundation; //// //// either version 2.1 of the License, or (at your option) any //// //// later version. //// //// //// //// This source is distributed in the hope that it will be //// //// useful, but WITHOUT ANY WARRANTY; without even the implied //// //// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR //// //// PURPOSE. See the GNU Lesser General Public License for more //// //// details. //// //// //// //// You should have received a copy of the GNU Lesser General //// //// Public License along with this source; if not, download it //// //// from http://www.opencores.org/lgpl.shtml //// //// //// ////////////////////////////////////////////////////////////////////// `include "timescale.v" `include "or1200_defines.v" `include "orpsoc-testbench-defines.v" `include "test-defines.v" // // Top of TB // `define TB_TOP orpsoc_testbench // // Top of DUT // `define DUT_TOP `TB_TOP.dut // // Top of OR1200 inside test bench // `define OR1200_TOP `DUT_TOP.or1200_top0 // // Define to enable lookup file generation // //`define OR1200_MONITOR_LOOKUP // // Define to enable SPR access log file generation // //`define OR1200_MONITOR_SPRS // // Enable logging of state during execution // //`define OR1200_MONITOR_EXEC_STATE // // Enable disassembly of instructions in execution state log // //`define OR1200_MONITOR_EXEC_LOG_DISASSEMBLY // // Enable verbose report l.nops (to both general log file and stdout) // `define OR1200_MONITOR_VERBOSE_NOPS // // Enable monitoring of control and execution flow (experimental) // //`define OR1200_SYSTEM_CHECKER // Can either individually enable things above, or usually have the scripts // running the simulation pass the PROCESSOR_MONITOR_ENABLE_LOGS define to // enable them all. `ifdef PROCESSOR_MONITOR_ENABLE_LOGS `define OR1200_MONITOR_EXEC_STATE `define OR1200_MONITOR_SPRS `define OR1200_MONITOR_LOOKUP `endif // // Memory coherence checking (double check instruction in fetch stage against // what is in memory.) // //`define MEM_COHERENCE_CHECK // // Top of OR1200 inside test bench // `define CPU or1200 `define CPU_cpu or1200_cpu `define CPU_rf or1200_rf `define CPU_except or1200_except `define CPU_ctrl or1200_ctrl `define CPU_sprs or1200_sprs `define CPU_immu_top or1200_immu_top `define CPU_immu_tlb or1200_immu_tlb `define CPU_CORE_CLK `OR1200_TOP.`CPU_cpu.`CPU_ctrl.clk `define OR1K_OPCODE_POS 31:26 `define OR1K_J_BR_IMM_POS 25:0 `define OR1K_RD_POS 25:21 `define OR1K_RA_POS 20:16 `define OR1K_RB_POS 15:11 `define OR1K_ALU_OP_POS 3:0 `define OR1K_SHROT_OP_POS 7:6 `define OR1K_SHROTI_IMM_POS 5:0 `define OR1K_SF_OP 25:21 `define OR1K_XSYNC_OP_POS 25:21 module or1200_monitor; integer fexe; integer finsn; reg [23:0] ref; `ifdef OR1200_MONITOR_SPRS integer fspr; `endif integer fgeneral; `ifdef OR1200_MONITOR_LOOKUP integer flookup; `endif integer r3; integer insns; // // Initialization // initial begin ref = 0; `ifdef OR1200_MONITOR_EXEC_STATE fexe = $fopen({"../out/",`TEST_NAME_STRING,"-executed.log"}); `endif `ifdef OR1200_MONITOR_EXEC_LOG_DISASSEMBLY finsn = fexe; `endif $timeformat (-9, 2, " ns", 12); `ifdef OR1200_MONITOR_SPRS fspr = $fopen({"../out/",`TEST_NAME_STRING,"-sprs.log"}); `endif fgeneral = $fopen({"../out/",`TEST_NAME_STRING,"-general.log"}); `ifdef OR1200_MONITOR_LOOKUP flookup = $fopen({"../out/",`TEST_NAME_STRING,"-lookup.log"}); `endif insns = 0; end // // Get GPR // task get_gpr; input [4:0] gpr_no; output [31:0] gpr; integer j; begin `ifdef OR1200_RFRAM_GENERIC for(j = 0; j < 32; j = j + 1) begin gpr[j] = `OR1200_TOP.`CPU_cpu.`CPU_rf.rf_a.mem[gpr_no*32+j]; end `else //gpr = `OR1200_TOP.`CPU_cpu.`CPU_rf.rf_a.mem[gpr_no]; gpr = `OR1200_TOP.`CPU_cpu.`CPU_rf.rf_a.get_gpr(gpr_no); `endif end endtask // // Write state of the OR1200 registers into a file // // Limitation: only a small subset of register file RAMs // are supported // task display_arch_state; reg [5:0] i; reg [31:0] r; integer j; begin `ifdef OR1200_MONITOR_EXEC_STATE ref = ref + 1; `ifdef OR1200_MONITOR_LOOKUP $fdisplay(flookup, "Instruction %d: %t", insns, $time); `endif $fwrite(fexe, "\nEXECUTED(%d): %h: %h", insns, `OR1200_TOP.`CPU_cpu.`CPU_except.wb_pc, `OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn); `ifdef OR1200_MONITOR_EXEC_LOG_DISASSEMBLY $fwrite(fexe,"\t"); // Decode the instruction, print it out or1200_print_op(`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn); `endif for(i = 0; i < 32; i = i + 1) begin if (i % 4 == 0) $fdisplay(fexe); get_gpr(i, r); $fwrite(fexe, "GPR%d: %h ", i, r); end $fdisplay(fexe); r = `OR1200_TOP.`CPU_cpu.`CPU_sprs.sr; $fwrite(fexe, "SR : %h ", r); r = `OR1200_TOP.`CPU_cpu.`CPU_sprs.epcr; $fwrite(fexe, "EPCR0: %h ", r); r = `OR1200_TOP.`CPU_cpu.`CPU_sprs.eear; $fwrite(fexe, "EEAR0: %h ", r); r = `OR1200_TOP.`CPU_cpu.`CPU_sprs.esr; $fdisplay(fexe, "ESR0 : %h", r); `endif // `ifdef OR1200_MONITOR_EXEC_STATE `ifdef OR1200_DISPLAY_EXECUTED ref = ref + 1; `ifdef OR1200_MONITOR_LOOKUP $fdisplay(flookup, "Instruction %d: %t", insns, $time); `endif $fwrite(fexe, "\nEXECUTED(%d): %h: %h", insns, `OR1200_TOP.`CPU_cpu.`CPU_except.wb_pc, `OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn); `endif insns = insns + 1; end endtask // display_arch_state /* Keep a trace buffer of the last lot of instructions and addresses * "executed",as read from the writeback stage, and cause a $finish if we hit * an instruction that is invalid, such as all zeros. * Currently, only breaks on an all zero instruction, but should probably be * made to break for anything with an X in it too. And of course ideally this * shouldn't be needed - but is handy if someone changes something and stops * the test continuing forever. */ integer num_nul_inst; initial num_nul_inst = 0; task monitor_for_crash; `define OR1200_MONITOR_CRASH_TRACE_SIZE 32 //Trace buffer of 32 instructions reg [31:0] insn_trace [0:`OR1200_MONITOR_CRASH_TRACE_SIZE-1]; //Trace buffer of the addresses of those instructions reg [31:0] addr_trace [0:`OR1200_MONITOR_CRASH_TRACE_SIZE-1]; integer i; begin if (`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn == 32'h00000000) num_nul_inst = num_nul_inst + 1; else num_nul_inst = 0; // Reset it if (num_nul_inst == 1000) // Sat a loop a bit too long... begin $fdisplay(fgeneral, "ERROR - no instruction at PC %h", `OR1200_TOP.`CPU_cpu.`CPU_except.wb_pc); $fdisplay(fgeneral, "Crash trace: Last %d instructions: ", `OR1200_MONITOR_CRASH_TRACE_SIZE); $fdisplay(fgeneral, "PC\t\tINSTR"); for(i=`OR1200_MONITOR_CRASH_TRACE_SIZE-1;i>=0;i=i-1) begin $fdisplay(fgeneral, "%h\t%h",addr_trace[i], insn_trace[i]); end #100 $finish; end else begin for(i=`OR1200_MONITOR_CRASH_TRACE_SIZE-1;i>0;i=i-1) begin insn_trace[i] = insn_trace[i-1]; addr_trace[i] = addr_trace[i-1]; end insn_trace[0] = `OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn; addr_trace[0] = `OR1200_TOP.`CPU_cpu.`CPU_except.wb_pc; end end endtask // monitor_for_crash // // Write state of the OR1200 registers into a file; version for exception // task display_arch_state_except; reg [5:0] i; reg [31:0] r; integer j; begin `ifdef OR1200_MONITOR_EXEC_STATE ref = ref + 1; `ifdef OR1200_MONITOR_LOOKUP $fdisplay(flookup, "Instruction %d: %t", insns, $time); `endif $fwrite(fexe, "\nEXECUTED(%d): %h: %h (exception)", insns, `OR1200_TOP.`CPU_cpu.`CPU_except.ex_pc, `OR1200_TOP.`CPU_cpu.`CPU_ctrl.ex_insn); for(i = 0; i < 32; i = i + 1) begin if (i % 4 == 0) $fdisplay(fexe); get_gpr(i, r); $fwrite(fexe, "GPR%d: %h ", i, r); end $fdisplay(fexe); r = `OR1200_TOP.`CPU_cpu.`CPU_sprs.sr; $fwrite(fexe, "SR : %h ", r); r = `OR1200_TOP.`CPU_cpu.`CPU_sprs.epcr; $fwrite(fexe, "EPCR0: %h ", r); r = `OR1200_TOP.`CPU_cpu.`CPU_sprs.eear; $fwrite(fexe, "EEAR0: %h ", r); r = `OR1200_TOP.`CPU_cpu.`CPU_sprs.esr; $fdisplay(fexe, "ESR0 : %h", r); insns = insns + 1; `endif // `ifdef OR1200_MONITOR_EXEC_STATE `ifdef OR1200_DISPLAY_EXECUTED ref = ref + 1; `ifdef OR1200_MONITOR_LOOKUP $fdisplay(flookup, "Instruction %d: %t", insns, $time); `endif $fwrite(fexe, "\nEXECUTED(%d): %h: %h (exception)", insns, `OR1200_TOP.`CPU_cpu.`CPU_except.ex_pc, `OR1200_TOP.`CPU_cpu.`CPU_ctrl.ex_insn); insns = insns + 1; `endif end endtask integer iwb_progress; reg [31:0] iwb_progress_addr; // // WISHBONE bus checker // always @(posedge `OR1200_TOP.iwb_clk_i) if (`OR1200_TOP.iwb_rst_i) begin iwb_progress = 0; iwb_progress_addr = `OR1200_TOP.iwb_adr_o; end else begin if (`OR1200_TOP.iwb_cyc_o && (iwb_progress != 2)) begin iwb_progress = 1; end if (`OR1200_TOP.iwb_stb_o) begin if (iwb_progress >= 1) begin if (iwb_progress == 1) iwb_progress_addr = `OR1200_TOP.iwb_adr_o; iwb_progress = 2; end else begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.iwb_stb_o raised without `OR1200_TOP.iwb_cyc_o, at %t\n", $time); #100 $finish; end end if (`OR1200_TOP.iwb_ack_i & `OR1200_TOP.iwb_err_i) begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.iwb_ack_i and `OR1200_TOP.iwb_err_i raised at the same time, at %t\n", $time); end if ((iwb_progress == 2) && (iwb_progress_addr != `OR1200_TOP.iwb_adr_o)) begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.iwb_adr_o changed while waiting for `OR1200_TOP.iwb_err_i/`OR1200_TOP.iwb_ack_i, at %t\n", $time); #100 $finish; end if (`OR1200_TOP.iwb_ack_i | `OR1200_TOP.iwb_err_i) if (iwb_progress == 2) begin iwb_progress = 0; iwb_progress_addr = `OR1200_TOP.iwb_adr_o; end else begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.iwb_ack_i/`OR1200_TOP.iwb_err_i raised without `OR1200_TOP.iwb_cyc_i/`OR1200_TOP.iwb_stb_i, at %t\n", $time); #100 $finish; end if ((iwb_progress == 2) && !`OR1200_TOP.iwb_stb_o) begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.iwb_stb_o lowered without `OR1200_TOP.iwb_err_i/`OR1200_TOP.iwb_ack_i, at %t\n", $time); #100 $finish; end end integer dwb_progress; reg [31:0] dwb_progress_addr; // // WISHBONE bus checker // always @(posedge `OR1200_TOP.dwb_clk_i) if (`OR1200_TOP.dwb_rst_i) dwb_progress = 0; else begin if (`OR1200_TOP.dwb_cyc_o && (dwb_progress != 2)) dwb_progress = 1; if (`OR1200_TOP.dwb_stb_o) if (dwb_progress >= 1) begin if (dwb_progress == 1) dwb_progress_addr = `OR1200_TOP.dwb_adr_o; dwb_progress = 2; end else begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.dwb_stb_o raised without `OR1200_TOP.dwb_cyc_o, at %t\n", $time); #100 $finish; end if (`OR1200_TOP.dwb_ack_i & `OR1200_TOP.dwb_err_i) begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.dwb_ack_i and `OR1200_TOP.dwb_err_i raised at the same time, at %t\n", $time); end if ((dwb_progress == 2) && (dwb_progress_addr != `OR1200_TOP.dwb_adr_o)) begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.dwb_adr_o changed while waiting for `OR1200_TOP.dwb_err_i/`OR1200_TOP.dwb_ack_i, at %t\n", $time); #100 $finish; end if (`OR1200_TOP.dwb_ack_i | `OR1200_TOP.dwb_err_i) if (dwb_progress == 2) begin dwb_progress = 0; dwb_progress_addr = `OR1200_TOP.dwb_adr_o; end else begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.dwb_ack_i/`OR1200_TOP.dwb_err_i raised without `OR1200_TOP.dwb_cyc_i/`OR1200_TOP.dwb_stb_i, at %t\n", $time); #100 $finish; end if ((dwb_progress == 2) && !`OR1200_TOP.dwb_stb_o) begin $fdisplay(fgeneral, "WISHBONE protocol violation: `OR1200_TOP.dwb_stb_o lowered without `OR1200_TOP.dwb_err_i/`OR1200_TOP.dwb_ack_i, at %t\n", $time); #100 $finish; end end // // Hooks for: // - displaying registers // - end of simulation // - access to SPRs // always @(posedge `CPU_CORE_CLK) if (!`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_freeze) begin // #2; if (((`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn[31:26] != `OR1200_OR32_NOP) | !`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn[16]) & !(`OR1200_TOP.`CPU_cpu.`CPU_except.except_flushpipe & `OR1200_TOP.`CPU_cpu.`CPU_except.ex_dslot)) begin display_arch_state; monitor_for_crash; end else if (`OR1200_TOP.`CPU_cpu.`CPU_except.except_flushpipe) display_arch_state_except; // small hack to stop simulation (l.nop 1): if (`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn == 32'h1500_0001) begin get_gpr(3, r3); $fdisplay(fgeneral, "%t: l.nop exit (%h)", $time, r3); `ifdef OR1200_MONITOR_VERBOSE_NOPS $display("%t: l.nop exit (%h)", $time, r3); `endif $finish; end // debug if test (l.nop 10) if (`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn == 32'h1500_000a) begin $fdisplay(fgeneral, "%t: l.nop dbg_if_test", $time); end // simulation reports (l.nop 2) if (`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn == 32'h1500_0002) begin get_gpr(3, r3); $fdisplay(fgeneral, "%t: l.nop report (%h)", $time, r3); `ifdef OR1200_MONITOR_VERBOSE_NOPS $display("%t: l.nop report (%h)", $time, r3); `endif end // simulation printfs (l.nop 3) if (`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn == 32'h1500_0003) begin get_gpr(3, r3); $fdisplay(fgeneral, "%t: l.nop printf (%h)", $time, r3); end if (`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn == 32'h1500_0004) begin // simulation putc (l.nop 4) get_gpr(3, r3); $write("%c", r3); $fdisplay(fgeneral, "%t: l.nop putc (%c)", $time, r3); end `ifdef OR1200_MONITOR_SPRS if (`OR1200_TOP.`CPU_cpu.`CPU_sprs.spr_we) $fdisplay(fspr, "%t: Write to SPR : [%h] <- %h", $time, `OR1200_TOP.`CPU_cpu.`CPU_sprs.spr_addr, `OR1200_TOP.`CPU_cpu.`CPU_sprs.spr_dat_o); if ((|`OR1200_TOP.`CPU_cpu.`CPU_sprs.spr_cs) & !`OR1200_TOP.`CPU_cpu.`CPU_sprs.spr_we) $fdisplay(fspr, "%t: Read from SPR: [%h] -> %h", $time, `OR1200_TOP.`CPU_cpu.`CPU_sprs.spr_addr, `OR1200_TOP.`CPU_cpu.`CPU_sprs.to_wbmux); `endif end `ifdef RAM_WB `define RAM_WB_TOP `DUT_TOP.ram_wb0.ram_wb_b3_0 task get_insn_from_wb_ram; input [31:0] addr; output [31:0] insn; begin insn = `RAM_WB_TOP.get_mem(addr); end endtask // get_insn_from_wb_ram `endif `ifdef VERSATILE_SDRAM `define SDRAM_TOP `TB_TOP.sdram0 // Bit selects to define the bank // 32 MB part with 4 banks `define SDRAM_BANK_SEL_BITS 24:23 `define SDRAM_WORD_SEL_TOP_BIT 22 // Gets instruction word from correct bank task get_insn_from_sdram; input [31:0] addr; output [31:0] insn; reg [`SDRAM_WORD_SEL_TOP_BIT-1:0] word_addr; begin word_addr = addr[`SDRAM_WORD_SEL_TOP_BIT:2]; if (addr[`SDRAM_BANK_SEL_BITS] == 2'b00) begin //$display("%t: get_insn_from_sdram bank0, word 0x%h, (%h and %h in SDRAM)", $time, word_addr, `SDRAM_TOP.Bank0[{word_addr,1'b0}], `SDRAM_TOP.Bank0[{word_addr,1'b1}]); insn[15:0] = `SDRAM_TOP.Bank0[{word_addr,1'b1}]; insn[31:16] = `SDRAM_TOP.Bank0[{word_addr,1'b0}]; end end endtask // get_insn_from_sdram `endif // `ifdef VERSATILE_SDRAM `ifdef XILINX_DDR2 `define DDR2_TOP `TB_TOP.gen_cs[0] // Gets instruction word from correct bank task get_insn_from_xilinx_ddr2; input [31:0] addr; output [31:0] insn; reg [16*8-1:0] ddr2_array_line0,ddr2_array_line1,ddr2_array_line2, ddr2_array_line3; integer word_in_line_num; begin // Get our 4 128-bit chunks (8 half-words in each!! Confused yet?), // 16 words total `DDR2_TOP.gen[0].u_mem0.memory_read(addr[28:27],addr[26:13],{addr[12:6],3'd0},ddr2_array_line0); `DDR2_TOP.gen[1].u_mem0.memory_read(addr[28:27],addr[26:13],{addr[12:6],3'd0},ddr2_array_line1); `DDR2_TOP.gen[2].u_mem0.memory_read(addr[28:27],addr[26:13],{addr[12:6],3'd0},ddr2_array_line2); `DDR2_TOP.gen[3].u_mem0.memory_read(addr[28:27],addr[26:13],{addr[12:6],3'd0},ddr2_array_line3); case (addr[5:2]) 4'h0: begin insn[15:0] = ddr2_array_line0[15:0]; insn[31:16] = ddr2_array_line1[15:0]; end 4'h1: begin insn[15:0] = ddr2_array_line2[15:0]; insn[31:16] = ddr2_array_line3[15:0]; end 4'h2: begin insn[15:0] = ddr2_array_line0[31:16]; insn[31:16] = ddr2_array_line1[31:16]; end 4'h3: begin insn[15:0] = ddr2_array_line2[31:16]; insn[31:16] = ddr2_array_line3[31:16]; end 4'h4: begin insn[15:0] = ddr2_array_line0[47:32]; insn[31:16] = ddr2_array_line1[47:32]; end 4'h5: begin insn[15:0] = ddr2_array_line2[47:32]; insn[31:16] = ddr2_array_line3[47:32]; end 4'h6: begin insn[15:0] = ddr2_array_line0[63:48]; insn[31:16] = ddr2_array_line1[63:48]; end 4'h7: begin insn[15:0] = ddr2_array_line2[63:48]; insn[31:16] = ddr2_array_line3[63:48]; end 4'h8: begin insn[15:0] = ddr2_array_line0[79:64]; insn[31:16] = ddr2_array_line1[79:64]; end 4'h9: begin insn[15:0] = ddr2_array_line2[79:64]; insn[31:16] = ddr2_array_line3[79:64]; end 4'ha: begin insn[15:0] = ddr2_array_line0[95:80]; insn[31:16] = ddr2_array_line1[95:80]; end 4'hb: begin insn[15:0] = ddr2_array_line2[95:80]; insn[31:16] = ddr2_array_line3[95:80]; end 4'hc: begin insn[15:0] = ddr2_array_line0[111:96]; insn[31:16] = ddr2_array_line1[111:96]; end 4'hd: begin insn[15:0] = ddr2_array_line2[111:96]; insn[31:16] = ddr2_array_line3[111:96]; end 4'he: begin insn[15:0] = ddr2_array_line0[127:112]; insn[31:16] = ddr2_array_line1[127:112]; end 4'hf: begin insn[15:0] = ddr2_array_line2[127:112]; insn[31:16] = ddr2_array_line3[127:112]; end endcase // case (addr[5:2]) end endtask // get_insn_from_xilinx_ddr2 `endif task get_insn_from_memory; input [31:0] id_pc; output [31:0] insn; begin // do a decode of which server we should look in case (id_pc[31:28]) `ifdef VERSATILE_SDRAM 4'h0: get_insn_from_sdram(id_pc, insn); `endif `ifdef XILINX_DDR2 4'h0: get_insn_from_xilinx_ddr2(id_pc, insn); `endif `ifdef RAM_WB 4'h0: get_insn_from_wb_ram(id_pc, insn); `endif 4'hf: // Flash isn't stored in a memory, it's an FSM so just skip/ignore insn = `OR1200_TOP.`CPU_cpu.`CPU_ctrl.id_insn; default: begin $fdisplay(fgeneral, "%t: Unknown memory server for address 0x%h", $time,id_pc); insn = 32'hxxxxxxxx; // Unknown server end endcase // case (id_pc[31:28]) end endtask // get_insn_from_memory // // Look in the iMMU TLB MR for this address' page, if MMUs are on and enabled // task check_for_immu_entry; input [31:0] pc; output [31:0] physical_pc; output mmu_tlb_miss; integer w,x; reg [31:`OR1200_IMMU_PS] pc_vpn; reg [`OR1200_ITLBTRW-1:0] itlb_tr; reg [`OR1200_ITLBMRW-1:0] itlb_mr; integer tlb_index; reg mmu_en; begin mmu_tlb_miss = 0; `ifdef OR1200_NO_IMMU physical_pc = pc; `else mmu_en = `OR1200_TOP.`CPU_immu_top.immu_en; // If MMU is enabled if (mmu_en) begin // Look in the iTLB for mapping - get virtual page number pc_vpn = pc[31:`OR1200_IMMU_PS]; tlb_index = pc[`OR1200_ITLB_INDX]; // Look at the ITLB match register itlb_mr = `OR1200_TOP.`CPU_immu_top.`CPU_immu_tlb.itlb_mr_ram.mem[tlb_index]; // Get the translate register here too, in case there's an error, we print it itlb_tr = `OR1200_TOP.`CPU_immu_top.`CPU_immu_tlb.itlb_tr_ram.mem[tlb_index]; if ((itlb_mr[`OR1200_ITLBMR_V_BITS] === 1'b1) & (itlb_mr[`OR1200_ITLBMRW-1:1] === pc[`OR1200_ITLB_TAG])) begin // Page number in match register matches page number of virtual PC, so get the physical // address from the translate memory // Now pull the physical page number out of the tranlsate register (it's after bottom 3 bits) physical_pc = {itlb_tr[`OR1200_ITLBTRW-1:`OR1200_ITLBTRW-(32-`OR1200_IMMU_PS)],pc[`OR1200_IMMU_PS-1:0]}; //$display("check_for_immu_entry: found match for virtual PC 0x%h in entry %d of iMMU, mr = 0x%x tr = 0x%x, phys. PC = 0x%h", pc, pc[`OR1200_ITLB_INDX], itlb_mr, itlb_tr, physical_pc); end // if ((itlb_mr[`OR1200_ITLBMR_V_BITS]) & (itlb_mr[`OR1200_ITLBMRW-1:1] == pc[`OR1200_ITLB_TAG])) else begin // Wait a couple of clocks, see if we're doing a miss @(posedge `CPU_CORE_CLK); @(posedge `CPU_CORE_CLK); if (!(`OR1200_TOP.`CPU_immu_top.miss)) // MMU should indicate miss begin $display("%t: check_for_immu_entry - ERROR - no match found for virtual PC 0x%h in entry %d of iMMU, mr = 0x%x tr = 0x%x, and no miss generated", $time, pc, pc[`OR1200_ITLB_INDX], itlb_mr, itlb_tr); #100; $finish; end else begin mmu_tlb_miss = 1; // Started a miss, so ignore this instruction end end // else: !if((itlb_mr[`OR1200_ITLBMR_V_BITS]) & (itlb_mr[`OR1200_ITLBMRW-1:1] == pc[`OR1200_ITLB_TAG])) end // if (`OR1200_TOP.`CPU_immu_top.immu_en === 1'b1) else physical_pc = pc; `endif // !`ifdef OR1200_NO_IMMU end endtask // check_for_immu_entry /* Instruction memory coherence checking. For new instruction executed in the pipeline - ensure it matches what is in the main program memory. Perform MMU translations if it is enabled. */ reg [31:0] mem_word; reg [31:0] last_addr = 0; reg [31:0] last_mem_word; reg [31:0] physical_pc; reg tlb_miss; `ifdef MEM_COHERENCE_CHECK `define MEM_COHERENCE_TRIGGER (`OR1200_TOP.`CPU_cpu.`CPU_ctrl.id_void === 1'b0) `define INSN_TO_CHECK `OR1200_TOP.`CPU_cpu.`CPU_ctrl.id_insn `define PC_TO_CHECK `OR1200_TOP.`CPU_cpu.`CPU_except.id_pc // Check instruction in decode stage is what is in the RAM always @(posedge `CPU_CORE_CLK) begin if (`MEM_COHERENCE_TRIGGER) begin check_for_immu_entry(`PC_TO_CHECK, physical_pc, tlb_miss); // Check if it's a new PC - will also get triggered if the // instruction has changed since we last checked it if (((physical_pc !== last_addr) || (last_mem_word != `INSN_TO_CHECK)) & !tlb_miss) begin // Decode stage not void, check instruction // get PC get_insn_from_memory(physical_pc, mem_word); if (mem_word !== `INSN_TO_CHECK) begin $fdisplay(fgeneral, "%t: Instruction mismatch for PC 0x%h (phys. 0x%h) - memory had 0x%h, CPU had 0x%h", $time, `PC_TO_CHECK, physical_pc, mem_word, `INSN_TO_CHECK); $display("%t: Instruction mismatch for PC 0x%h (phys. 0x%h) - memory had 0x%h, CPU had 0x%h", $time, `PC_TO_CHECK, physical_pc, mem_word, `INSN_TO_CHECK); #200 $finish; end last_addr = physical_pc; last_mem_word = mem_word; end // if (((physical_pc !== last_addr) || (last_mem_word != `INSN_TO_CHECK))... end // if (`MEM_COHERENCE_TRIGGER) end // always @ (posedge `CPU_CORE_CLK) `endif // `ifdef MEM_COHERENCE_CHECK // Trigger on each instruction that gets into writeback stage properly reg exception_coming1, exception_coming2, exception_here; reg will_jump, jumping, jump_dslot, jumped; reg rfe, except_during_rfe; reg dslot_expt; // Maintain a copy of GPRS for previous instruction reg [31:0] current_gprs [0:31]; reg [31:0] current_epcr, current_eear, current_esr, current_sr; reg [31:0] previous_gprs [0:31]; reg [31:0] previous_epcr; reg [31:0] previous_eear; reg [31:0] previous_esr; reg [31:0] previous_sr; task update_current_gprs; integer j; begin for(j=0;j<32;j=j+1) begin get_gpr(j,current_gprs[j]); end current_sr = `OR1200_TOP.`CPU_cpu.or1200_sprs.sr ; current_esr = `OR1200_TOP.`CPU_cpu.or1200_sprs.epcr ; current_epcr = `OR1200_TOP.`CPU_cpu.or1200_sprs.epcr ; current_eear = `OR1200_TOP.`CPU_cpu.or1200_sprs.eear ; end endtask task update_previous_gprs; integer j; begin for(j=0;j<32;j=j+1) begin previous_gprs[j] = current_gprs[j]; end previous_sr = current_sr; previous_esr = current_esr; previous_epcr = current_epcr; previous_eear = current_eear; end endtask // update_previous_gprs // Maintain a list of addresses we expect the processor to execute // Whenever we hit a branch or jump or rfe we add to this list - when we // execute it then we remove it from the list. reg [31:0] expected_addresses [0:31]; reg expected_addresses_waiting [0:31]; // List indicating if address is waiting reg duplicate_expected_addresses_waiting [0:31]; // List indicating if a waiting address will be cleared by the single return integer expected_address_num; // Initialise things on reset always @(`OR1200_TOP.iwb_rst_i) begin for (expected_address_num=0;expected_address_num<32;expected_address_num=expected_address_num+1) begin expected_addresses_waiting[expected_address_num] = 0; duplicate_expected_addresses_waiting[expected_address_num] = 0; end expected_address_num = 0; end task add_expected_address; input [31:0] expected_pc; begin if (expected_address_num == 31) begin $display("%t: Too many branches not reached",$time); #100; $finish; end if (expected_addresses_waiting[expected_address_num]) begin $display("%t: expected_addresses tracker bugged out. expected_address_num = %0d",$time,expected_address_num); #100; $finish; end else begin `ifdef OR1200_MONITOR_JUMPTRACK_DEBUG_OUTPUT // Debugging output... $display("%t: Adding address 0x%h to expected list index %0d",$time, expected_pc,expected_address_num); `endif // Put the expected PC in the list, increase the index expected_addresses[expected_address_num] = expected_pc; expected_addresses_waiting[expected_address_num] = 1; expected_address_num = expected_address_num + 1; end // else: !if(expected_addresses_waiting[expected_address_num]) end endtask // add_address_to_expect // Use this in the case that there's an execption after a jump, in which // case we'll have two entries when we finally jump back (the one the // original jump put in, and the one put in by the l.rfe or l.jr/ when // returning outside of exception handler), so mark this one as OK for // removing the duplicate of task mark_duplicate_expected_address; begin // This will always be done on the first instruction of an exception // that has occured after a delay slot instruction, so // expected_address_num will be one past the entry for the one we will // get a duplicate return call for duplicate_expected_addresses_waiting[expected_address_num-1] = 1; end endtask // mark_duplicate_expected_address task check_expected_address; input [31:0] pc; input expecting_hit; integer i,j; reg hit; reg duplicates; begin hit = 0; //$display("%t: check_expected_addr 0x%h, index %0d", // $time,pc, expected_address_num); if (expected_address_num > 0) begin // First check the last jump we did if (expected_addresses[expected_address_num-1] == pc) begin // Jump address hit // Debugging printout: `ifdef OR1200_MONITOR_JUMPTRACK_DEBUG_OUTPUT $display("%t: PC address 0x%h was in expected list, index %0d",$time, pc,expected_address_num-1); `endif expected_address_num = expected_address_num-1; expected_addresses_waiting[expected_address_num] = 0; hit = 1; end else begin // Check through the list for(i=0;i<expected_address_num;i=i+1) begin if (expected_addresses[i] == pc) begin // Jump address hit // Debugging printout: `ifdef OR1200_MONITOR_JUMPTRACK_DEBUG_OUTPUT $display("%t: PC address 0x%h was in expected list, index %0d",$time, pc,i); `endif for(j=i;j<expected_address_num;j=j+1) begin // Pull all of the ones above us down one expected_addresses_waiting[j] = expected_addresses_waiting[j+1]; expected_addresses[j] = expected_addresses[j+1]; duplicate_expected_addresses_waiting[j] = duplicate_expected_addresses_waiting[j+1]; end expected_address_num = expected_address_num-1; hit = 1; // quit out. only allow 1 hit i = expected_address_num; end end end // else: !if(expected_addresses[expected_ad... end // if (expected_address_num > 0) // Check for duplicates this way because of the way we've declared // the array... duplicates=0; for(i=0;i<32;i=i+1) duplicates = duplicates | duplicate_expected_addresses_waiting[i]; if (hit & duplicates) begin // If we got a hit, check for duplicates we're also meant to clear `ifdef OR1200_MONITOR_JUMPTRACK_DEBUG_OUTPUT $display; `endif for(i=0;i<expected_address_num;i=i+1) begin if(duplicate_expected_addresses_waiting[i] & expected_addresses_waiting[i] & expected_addresses[i] == pc) begin // Found a duplicate call address, clear it duplicate_expected_addresses_waiting[i] = 0; expected_addresses_waiting[i] = 0; // Now reorder the list - pull all the ones above us // down by one for(j=i;j<expected_address_num;j=j+1) begin expected_addresses_waiting[j] = expected_addresses_waiting[j+1]; expected_addresses[j] = expected_addresses[j+1]; duplicate_expected_addresses_waiting[j] = duplicate_expected_addresses_waiting[j+1]; end expected_address_num = expected_address_num - 1; end end // for (i=0;i<expected_address_num;i=i+1) end // if (hit & duplicates) if (expecting_hit & !hit) begin // Expected this address to be one we're supposed to jump to, but it wasn't! $display("%t: Failed to find current PC, 0x%h, in expected PCs for branches/jumps",$time,pc); #100; $finish; end end endtask // check_expected_address // Task to assert value of GPR task assert_gpr_val; input [5:0] regnum; input [31:0] assert_value; input [31:0] pc; reg [31:0] reg_val; begin get_gpr(regnum, reg_val); if (reg_val !== assert_value) begin $display("%t: Assert r%0d value (0x%h) = 0x%h failed. pc=0x%h", $time, regnum, reg_val, assert_value,pc); #100; $finish; end end endtask // assert_gpr_val // Task to assert something is true task assert_this; input assert_result; input [31:0] pc; begin if (!assert_result) begin $display("%t: Assert failed for instruction at pc=0x%h", $time , pc); #100; $finish; end end endtask // assert_gpr_val // The jumping variable doesn't get updated until we do the proper check of // the current instruction reaching the writeback stage. We need to know // earlier, eg. in the exception checking part, if this instruction will // jump. We do that with this task. task check_for_jump; input [31:0] insn; reg [5:0] opcode; reg flag; begin opcode = insn[`OR1K_OPCODE_POS]; // Use the flag from the previous instruction, as the decision // is made in the execute stage not in te writeback stage, // which is where we're getting our instructions. flag = previous_sr[`OR1200_SR_F]; case (opcode) `OR1200_OR32_J, `OR1200_OR32_JR, `OR1200_OR32_JAL, `OR1200_OR32_JALR: will_jump = 1; `OR1200_OR32_BNF: will_jump = !flag; `OR1200_OR32_BF: will_jump = flag; default: will_jump = 0; endcase // case (opcode) end endtask // check_for_jump // Detect exceptions from the processor here reg [13:0] except_trig_r; reg exception_coming; always @(posedge `CPU_CORE_CLK) if (`OR1200_TOP.iwb_rst_i) begin except_trig_r = 0; exception_coming = 0; except_during_rfe = 0; end else if ((|`OR1200_TOP.`CPU_cpu.`CPU_except.except_trig) && !exception_coming) begin exception_coming = 1; except_trig_r = `OR1200_TOP.`CPU_cpu.`CPU_except.except_trig; except_during_rfe = rfe; end task check_incoming_exceptions; begin // Exception timing - depends on the trigger. // Appears to be: // tick timer - dslot - 1 instruction delay, else 2 // tlb lookasides - 1 instruction for both casex (except_trig_r) 13'b1_xxxx_xxxx_xxxx: begin //except_type <= #1 `OR1200_EXCEPT_TICK; exception_here = exception_coming2; exception_coming2 = jump_dslot ? exception_coming: exception_coming1 ; exception_coming1 = jump_dslot ? 0 : exception_coming; end 13'b0_1xxx_xxxx_xxxx: begin //except_type <= #1 `OR1200_EXCEPT_INT; #1; end 13'b0_01xx_xxxx_xxxx: begin //except_type <= #1 `OR1200_EXCEPT_ITLBMISS; exception_here = exception_coming2; exception_coming2 = jump_dslot ? exception_coming : exception_coming1 ; exception_coming1 = jump_dslot ? 0 : exception_coming; end 13'b0_001x_xxxx_xxxx: begin //except_type <= #1 `OR1200_EXCEPT_IPF; exception_here = exception_coming2; exception_coming2 = jump_dslot ? exception_coming : exception_coming1 ; exception_coming1 = jump_dslot ? 0 : exception_coming; end 13'b0_0001_xxxx_xxxx: begin //except_type <= #1 `OR1200_EXCEPT_BUSERR; exception_here = exception_coming; exception_coming2 = 0; exception_coming1 = 0; end 13'b0_0000_1xxx_xxxx: begin //except_type <= #1 `OR1200_EXCEPT_ILLEGAL; if (will_jump) begin // Writeback stage instruction will jump, and we have an // illegal instruction in the decode/execute stage, which is // the delay slot, so indicate the exception is coming... exception_here = exception_coming2; exception_coming2 = exception_coming; exception_coming1 = 0; end else begin exception_here = jump_dslot ? exception_coming2 : exception_coming; exception_coming2 = jump_dslot ? exception_coming : 0; exception_coming1 = 0; end end 13'b0_0000_01xx_xxxx: begin //except_type <= #1 `OR1200_EXCEPT_ALIGN; if(will_jump) begin exception_here = exception_coming2; exception_coming2 = exception_coming; exception_coming1 = 0; end else begin exception_here = (rfe) ? exception_coming : exception_coming2; exception_coming2 = (rfe) ? 0 : exception_coming; exception_coming1 = 0; end end 13'b0_0000_001x_xxxx: begin //except_type <= #1 `OR1200_EXCEPT_DTLBMISS; // Looks like except_trig goes high here after we check the // instruction before the itlb miss after a delay slot, so we // miss the dslot variable (it gets propegated before we call // this task) so we use the jumped variable here to see if we // are an exception after a delay slot //exception_here = (jumped | rfe) ? exception_coming : exception_coming2 ; //exception_coming2 = (jumped | rfe) ? 0 : exception_coming; exception_here = (jumped | rfe) ? exception_coming : exception_coming2 ; exception_coming2 = (jumped | rfe) ? 0 : exception_coming; exception_coming1 = 0; end 13'b0_0000_0001_xxxx: begin //except_type <= #1 `OR1200_EXCEPT_DPF; if (jumped) begin // Jumped onto illegal instruction exception_here = exception_coming ; exception_coming2 = 0; exception_coming1 = 0; end else begin exception_here = exception_coming2; exception_coming2 = exception_coming; exception_coming1 = 0; end end 13'b0_0000_0000_1xxx: begin // Data Bus Error //except_type <= #1 `OR1200_EXCEPT_BUSERR; exception_here = exception_coming2 ; exception_coming2 = exception_coming; exception_coming1 = 0; end 13'b0_0000_0000_01xx: begin //except_type <= #1 `OR1200_EXCEPT_RANGE; #1; end 13'b0_0000_0000_001x: begin // trap #1; end 13'b0_0000_0000_0001: begin //except_type <= #1 `OR1200_EXCEPT_SYSCALL; exception_here = exception_coming2; exception_coming2 = jumped ? exception_coming: exception_coming1 ; exception_coming1 = jumped ? 0 : exception_coming; end endcase // casex (except_trig_r) exception_coming = 0; except_during_rfe = 0; end endtask // check_incoming_exceptions ///////////////////////////////////////////////////////////////////////// // Execution tracking task ///////////////////////////////////////////////////////////////////////// `ifdef OR1200_SYSTEM_CHECKER always @(posedge `CPU_CORE_CLK) begin if (`OR1200_TOP.iwb_rst_i) begin exception_coming1 = 0;exception_coming2 = 0;exception_here= 0; jumping = 0; jump_dslot = 0; jumped = 0; rfe = 0; end if (!`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_freeze) begin //#2 ; // If instruction isn't a l.nop with bit 16 set (implementation's // filler instruction in pipeline), and do not have an exception // signaled with a dslot instruction in the execute stage if (((`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn[`OR1K_OPCODE_POS] != `OR1200_OR32_NOP) || !`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn[16]) && !(`OR1200_TOP.`CPU_cpu.`CPU_except.except_flushpipe && `OR1200_TOP.`CPU_cpu.`CPU_except.ex_dslot)) // and not except start begin // Propegate jump-tracking variables // If was exception in delay slot, we didn't actually jump // so don't set jumped in this case. jumped = exception_here ? 0 : jump_dslot; jump_dslot = jumping; jumping = 0; rfe = 0; // Now, check if current instruction will jump/branch, this is // needed by the exception checking code, sets will_jump=1 check_for_jump(`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn); // Now check if it's an exception this instruction check_incoming_exceptions; // Case where we just went to an exception after a jump, so we // mark the address we were meant to jump to as a place which will // have duplicate return entries in the expected address list if (exception_here & (jumped | jump_dslot)) begin $display("%t: marked as jump address with exception (dup)" ,$time); mark_duplicate_expected_address; end or1200_check_execution(`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn, `OR1200_TOP.`CPU_cpu.`CPU_except.wb_pc, exception_here); //$write("%t: pc:0x%h\t",$time, // `OR1200_TOP.`CPU_cpu.`CPU_except.wb_pc); // Decode the instruction, print it out //or1200_print_op(`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_insn); //$write("\t exc:%0h dsl:%0h\n",exception_here,jump_dslot); end end // if (!`OR1200_TOP.`CPU_cpu.`CPU_ctrl.wb_freeze) end // always @ (posedge `CPU_CORE_CLK) `endif task or1200_check_execution; input [31:0] insn; input [31:0] pc; input exception; reg [5:0] opcode; reg [25:0] j_imm; reg [25:0] br_imm; reg [4:0] rD_num, rA_num, rB_num; reg [31:0] rD_val, rA_val, rB_val; reg [15:0] imm_16bit; reg [15:0] mtspr_imm; reg [3:0] alu_op; reg [1:0] shrot_op; reg [5:0] shroti_imm; reg [5:0] sf_op; reg [5:0] xsync_op; reg flag; reg [31:0] br_j_ea; // Branch/jump effective address begin // Instruction opcode opcode = insn[`OR1K_OPCODE_POS]; // Immediates for jump or branch instructions j_imm = insn[`OR1K_J_BR_IMM_POS]; br_imm = insn[`OR1K_J_BR_IMM_POS]; // Register numbers (D, A and B) rD_num = insn[`OR1K_RD_POS]; rA_num = insn[`OR1K_RA_POS]; rB_num = insn[`OR1K_RB_POS]; // Bottom 16 bits when used as immediates in various instructions imm_16bit = insn[15:0]; // 16-bit immediate for mtspr instructions mtspr_imm = {insn[25:21],insn[10:0]}; // ALU op for ALU instructions alu_op = insn[`OR1K_ALU_OP_POS]; // Shift-rotate op for SHROT ALU instructions shrot_op = insn[`OR1K_SHROT_OP_POS]; shroti_imm = insn[`OR1K_SHROTI_IMM_POS]; // Set flag op sf_op = insn[`OR1K_SF_OP]; // Xsync/syscall/trap opcode xsync_op = insn[`OR1K_XSYNC_OP_POS]; // Use the flag from the previous instruction, as the decision // is made in the execute stage not in te writeback stage, // which is where we're getting our instructions. flag = previous_sr[`OR1200_SR_F]; update_current_gprs; // Check MSbit of the immediate, sign extend if set br_j_ea = j_imm[25] ? pc + {4'hf,j_imm,2'b00} : pc + {4'h0,j_imm,2'b00}; if (exception) begin $display("%t: exception - at 0x%x",$time, pc); // get epcr, put it in the addresses we expect to jump // back to // Maybe DON'T do this. Because maybe in linux things we // interrupt out of, we don't want to execute them again? //add_expected_address(current_epcr); end check_expected_address(pc, (jumped & !exception)); rfe = 0; case (opcode) `OR1200_OR32_J: begin // // PC < - exts(Immediate < < 2) + JumpInsnAddr // //The immediate value is shifted left two bits, sign-extended // to program counter width, and then added to the address of // the jump instruction. The result is the effective address // of the jump. The program unconditionally jumps to EA with // a delay of one instruction. add_expected_address(br_j_ea); jumping = 1; end `OR1200_OR32_JAL: begin // //PC < - exts(Immediate < < 2) + JumpInsnAddr //LR < - DelayInsnAddr + 4 // // Link reg is r9, check it is PC+8 // add_expected_address(br_j_ea); assert_gpr_val(9, pc+8, pc); jumping = 1; // end `OR1200_OR32_BNF: begin //EA < - exts(Immediate < < 2) + BranchInsnAddr //PC < - EA if SR[F] cleared if (!flag) begin add_expected_address(br_j_ea); jumping = 1; end end `OR1200_OR32_BF: begin //EA < - exts(Immediate < < 2) + BranchInsnAddr //PC < - EA if SR[F] set if (flag) begin add_expected_address(br_j_ea); jumping = 1; end end `OR1200_OR32_RFE: begin add_expected_address(current_epcr); // jumping variable keeps track of jumps/branches with delay // slot - there is none for l.rfe rfe = 1; end `OR1200_OR32_JR: begin //PC < - rB get_gpr(rB_num, rB_val); add_expected_address(rB_val); jumping = 1; end `OR1200_OR32_JALR: begin //PC < - rB //LR < - DelayInsnAddr + 4 get_gpr(rB_num, rB_val); add_expected_address(rB_val); assert_gpr_val(9, pc+8, pc); jumping = 1; end /* `OR1200_OR32_LWZ, `OR1200_OR32_LBZ, `OR1200_OR32_LBS, `OR1200_OR32_LHZ, `OR1200_OR32_LHS, `OR1200_OR32_SW, `OR1200_OR32_SB, `OR1200_OR32_SH: begin // Should result in databus access if data cache disabled $display("%t: lsu instruction",$time); end `OR1200_OR32_MFSPR, `OR1200_OR32_MTSPR: begin // Confirm RF values end up in the correct SPR $display("%t: mxspr",$time); end `OR1200_OR32_MOVHI, `OR1200_OR32_ADDI, `OR1200_OR32_ADDIC, `OR1200_OR32_ANDI, `OR1200_OR32_ORI, `OR1200_OR32_XORI, `OR1200_OR32_MULI, `OR1200_OR32_ALU: begin // Double check operations done on RF and immediate values $display("%t: ALU op",$time); end `OR1200_OR32_SH_ROTI: begin // Rotate according to immediate - maybe should be in ALU ops $display("%t: rotate op",$time); end `OR1200_OR32_SFXXI, `OR1200_OR32_SFXX: begin // Set flag - do the check oursevles, check flag $display("%t: set flag op",$time); end `OR1200_OR32_MACI, `OR1200_OR32_MACMSB: begin // Either, multiply signed and accumulate, l.mac // or multiply signed and subtract, l.msb $display("%t: MAC op",$time); end */ /*default: begin $display("%t: Unknown opcode 0x%h at pc 0x%x\n", $time,opcode, pc); end */ endcase // case (opcode) update_previous_gprs; end endtask // or1200_check_execution ///////////////////////////////////////////////////////////////////////// // Instruction decode task ///////////////////////////////////////////////////////////////////////// task or1200_print_op; input [31:0] insn; reg [5:0] opcode; reg [25:0] j_imm; reg [25:0] br_imm; reg [4:0] rD_num, rA_num, rB_num; reg [31:0] rA_val, rB_val; reg [15:0] imm_16bit; reg [10:0] imm_split16bit; reg [3:0] alu_op; reg [1:0] shrot_op; reg [5:0] shroti_imm; reg [5:0] sf_op; reg [5:0] xsync_op; begin // Instruction opcode opcode = insn[`OR1K_OPCODE_POS]; // Immediates for jump or branch instructions j_imm = insn[`OR1K_J_BR_IMM_POS]; br_imm = insn[`OR1K_J_BR_IMM_POS]; // Register numbers (D, A and B) rD_num = insn[`OR1K_RD_POS]; rA_num = insn[`OR1K_RA_POS]; rB_num = insn[`OR1K_RB_POS]; // Bottom 16 bits when used as immediates in various instructions imm_16bit = insn[15:0]; // Bottom 11 bits used as immediates for l.sX instructions // Split 16-bit immediate for l.mtspr/l.sX instructions imm_split16bit = {insn[25:21],insn[10:0]}; // ALU op for ALU instructions alu_op = insn[`OR1K_ALU_OP_POS]; // Shift-rotate op for SHROT ALU instructions shrot_op = insn[`OR1K_SHROT_OP_POS]; shroti_imm = insn[`OR1K_SHROTI_IMM_POS]; // Set flag op sf_op = insn[`OR1K_SF_OP]; // Xsync/syscall/trap opcode xsync_op = insn[`OR1K_XSYNC_OP_POS]; case (opcode) `OR1200_OR32_J: begin $fwrite(finsn,"l.j 0x%h", {j_imm,2'b00}); end `OR1200_OR32_JAL: begin $fwrite(finsn,"l.jal 0x%h", {j_imm,2'b00}); end `OR1200_OR32_BNF: begin $fwrite(finsn,"l.bnf 0x%h", {br_imm,2'b00}); end `OR1200_OR32_BF: begin $fwrite(finsn,"l.bf 0x%h", {br_imm,2'b00}); end `OR1200_OR32_RFE: begin $fwrite(finsn,"l.rfe"); end `OR1200_OR32_JR: begin $fwrite(finsn,"l.jr r%0d",rB_num); end `OR1200_OR32_JALR: begin $fwrite(finsn,"l.jalr r%0d",rB_num); end `OR1200_OR32_LWZ: begin $fwrite(finsn,"l.lwz r%0d,0x%0h(r%0d)",rD_num,imm_16bit,rA_num); end `OR1200_OR32_LBZ: begin $fwrite(finsn,"l.lbz r%0d,0x%0h(r%0d)",rD_num,imm_16bit,rA_num); end `OR1200_OR32_LBS: begin $fwrite(finsn,"l.lbs r%0d,0x%0h(r%0d)",rD_num,imm_16bit,rA_num); end `OR1200_OR32_LHZ: begin $fwrite(finsn,"l.lhz r%0d,0x%0h(r%0d)",rD_num,imm_16bit,rA_num); end `OR1200_OR32_LHS: begin $fwrite(finsn,"l.lhs r%0d,0x%0h(r%0d)",rD_num,imm_16bit,rA_num); end `OR1200_OR32_SW: begin $fwrite(finsn,"l.sw 0x%0h(r%0d),r%0d",imm_split16bit,rA_num,rB_num); end `OR1200_OR32_SB: begin $fwrite(finsn,"l.sb 0x%0h(r%0d),r%0d",imm_split16bit,rA_num,rB_num); end `OR1200_OR32_SH: begin $fwrite(finsn,"l.sh 0x%0h(r%0d),r%0d",imm_split16bit,rA_num,rB_num); end `OR1200_OR32_MFSPR: begin $fwrite(finsn,"l.mfspr r%0d,r%0d,0x%h",rD_num,rA_num,imm_16bit,); end `OR1200_OR32_MTSPR: begin $fwrite(finsn,"l.mtspr r%0d,r%0d,0x%h",rA_num,rB_num,imm_split16bit); end `OR1200_OR32_MOVHI: begin if (!insn[16]) $fwrite(finsn,"l.movhi r%0d,0x%h",rD_num,imm_16bit); else $fwrite(finsn,"l.macrc r%0d",rD_num); end `OR1200_OR32_ADDI: begin $fwrite(finsn,"l.addi r%0d,r%0d,0x%h",rD_num,rA_num,imm_16bit); end `OR1200_OR32_ADDIC: begin $fwrite(finsn,"l.addic r%0d,r%0d,0x%h",rD_num,rA_num,imm_16bit); end `OR1200_OR32_ANDI: begin $fwrite(finsn,"l.andi r%0d,r%0d,0x%h",rD_num,rA_num,imm_16bit); end `OR1200_OR32_ORI: begin $fwrite(finsn,"l.ori r%0d,r%0d,0x%h",rD_num,rA_num,imm_16bit); end `OR1200_OR32_XORI: begin $fwrite(finsn,"l.xori r%0d,r%0d,0x%h",rD_num,rA_num,imm_16bit); end `OR1200_OR32_MULI: begin $fwrite(finsn,"l.muli r%0d,r%0d,0x%h",rD_num,rA_num,imm_16bit); end `OR1200_OR32_ALU: begin case(alu_op) `OR1200_ALUOP_ADD: $fwrite(finsn,"l.add "); `OR1200_ALUOP_ADDC: $fwrite(finsn,"l.addc "); `OR1200_ALUOP_SUB: $fwrite(finsn,"l.sub "); `OR1200_ALUOP_AND: $fwrite(finsn,"l.and "); `OR1200_ALUOP_OR: $fwrite(finsn,"l.or "); `OR1200_ALUOP_XOR: $fwrite(finsn,"l.xor "); `OR1200_ALUOP_MUL: $fwrite(finsn,"l.mul "); `OR1200_ALUOP_SHROT: begin case(shrot_op) `OR1200_SHROTOP_SLL: $fwrite(finsn,"l.sll "); `OR1200_SHROTOP_SRL: $fwrite(finsn,"l.srl "); `OR1200_SHROTOP_SRA: $fwrite(finsn,"l.sra "); `OR1200_SHROTOP_ROR: $fwrite(finsn,"l.ror "); endcase // case (shrot_op) end `OR1200_ALUOP_DIV: $fwrite(finsn,"l.div "); `OR1200_ALUOP_DIVU: $fwrite(finsn,"l.divu "); `OR1200_ALUOP_CMOV: $fwrite(finsn,"l.cmov "); endcase // case (alu_op) $fwrite(finsn,"r%0d,r%0d,r%0d",rD_num,rA_num,rB_num); end `OR1200_OR32_SH_ROTI: begin case(shrot_op) `OR1200_SHROTOP_SLL: $fwrite(finsn,"l.slli "); `OR1200_SHROTOP_SRL: $fwrite(finsn,"l.srli "); `OR1200_SHROTOP_SRA: $fwrite(finsn,"l.srai "); `OR1200_SHROTOP_ROR: $fwrite(finsn,"l.rori "); endcase // case (shrot_op) $fwrite(finsn,"r%0d,r%0d,0x%h",rD_num,rA_num,shroti_imm); end `OR1200_OR32_SFXXI: begin case(sf_op[2:0]) `OR1200_COP_SFEQ: $fwrite(finsn,"l.sfeqi "); `OR1200_COP_SFNE: $fwrite(finsn,"l.sfnei "); `OR1200_COP_SFGT: begin if (sf_op[`OR1200_SIGNED_COMPARE]) $fwrite(finsn,"l.sfgtsi "); else $fwrite(finsn,"l.sfgtui "); end `OR1200_COP_SFGE: begin if (sf_op[`OR1200_SIGNED_COMPARE]) $fwrite(finsn,"l.sfgesi "); else $fwrite(finsn,"l.sfgeui "); end `OR1200_COP_SFLT: begin if (sf_op[`OR1200_SIGNED_COMPARE]) $fwrite(finsn,"l.sfltsi "); else $fwrite(finsn,"l.sfltui "); end `OR1200_COP_SFLE: begin if (sf_op[`OR1200_SIGNED_COMPARE]) $fwrite(finsn,"l.sflesi "); else $fwrite(finsn,"l.sfleui "); end endcase // case (sf_op[2:0]) $fwrite(finsn,"r%0d,0x%h",rA_num, imm_16bit); end // case: `OR1200_OR32_SFXXI `OR1200_OR32_SFXX: begin case(sf_op[2:0]) `OR1200_COP_SFEQ: $fwrite(finsn,"l.sfeq "); `OR1200_COP_SFNE: $fwrite(finsn,"l.sfne "); `OR1200_COP_SFGT: begin if (sf_op[`OR1200_SIGNED_COMPARE]) $fwrite(finsn,"l.sfgts "); else $fwrite(finsn,"l.sfgtu "); end `OR1200_COP_SFGE: begin if (sf_op[`OR1200_SIGNED_COMPARE]) $fwrite(finsn,"l.sfges "); else $fwrite(finsn,"l.sfgeu "); end `OR1200_COP_SFLT: begin if (sf_op[`OR1200_SIGNED_COMPARE]) $fwrite(finsn,"l.sflts "); else $fwrite(finsn,"l.sfltu "); end `OR1200_COP_SFLE: begin if (sf_op[`OR1200_SIGNED_COMPARE]) $fwrite(finsn,"l.sfles "); else $fwrite(finsn,"l.sfleu "); end endcase // case (sf_op[2:0]) $fwrite(finsn,"r%0d,r%0d",rA_num, rB_num); end `OR1200_OR32_MACI: begin $fwrite(finsn,"l.maci r%0d,0x%h",rA_num,imm_16bit); end `OR1200_OR32_MACMSB: begin if(insn[3:0] == 4'h1) $fwrite(finsn,"l.mac "); else if(insn[3:0] == 4'h2) $fwrite(finsn,"l.msb "); $fwrite(finsn,"r%0d,r%0d",rA_num,rB_num); end `OR1200_OR32_NOP: begin $fwrite(finsn,"l.nop 0x%0h",imm_16bit); end `OR1200_OR32_XSYNC: begin case (xsync_op) 5'd0: $fwrite(finsn,"l.sys 0x%h",imm_16bit); 5'd8: $fwrite(finsn,"l.trap 0x%h",imm_16bit); 5'd16: $fwrite(finsn,"l.msync"); 5'd20: $fwrite(finsn,"l.psync"); 5'd24: $fwrite(finsn,"l.csync"); default: begin $display("%t: Instruction with opcode 0x%h has bad specific type information: 0x%h",$time,opcode,insn); $fwrite(finsn,"%t: Instruction with opcode 0x%h has has bad specific type information: 0x%h",$time,opcode,insn); end endcase // case (xsync_op) end default: begin $display("%t: Unknown opcode 0x%h",$time,opcode); $fwrite(finsn,"%t: Unknown opcode 0x%h",$time,opcode); end endcase // case (opcode) end endtask // or1200_print_op endmodule
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