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////////////////////////////////////////////////////////////////////// //// //// //// OR1200's definitions //// //// //// //// This file is part of the OpenRISC 1200 project //// //// http://opencores.org/project,or1k //// //// //// //// Description //// //// Defines for the OR1200 core //// //// //// //// To Do: //// //// - add parameters that are missing //// //// //// //// Author(s): //// //// - Damjan Lampret, lampret@opencores.org //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2000 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 //// //// //// ////////////////////////////////////////////////////////////////////// // // $Log: or1200_defines.v,v $ // Revision 2.0 2010/06/30 11:00:00 ORSoC // Minor update: // Defines added, bugs fixed. // // Dump VCD // //`define OR1200_VCD_DUMP // // Generate debug messages during simulation // //`define OR1200_VERBOSE // `define OR1200_ASIC //////////////////////////////////////////////////////// // // Typical configuration for an ASIC // `ifdef OR1200_ASIC // // Target ASIC memories // //`define OR1200_ARTISAN_SSP //`define OR1200_ARTISAN_SDP //`define OR1200_ARTISAN_STP `define OR1200_VIRTUALSILICON_SSP //`define OR1200_VIRTUALSILICON_STP_T1 //`define OR1200_VIRTUALSILICON_STP_T2 // // Do not implement Data cache // //`define OR1200_NO_DC // // Do not implement Insn cache // //`define OR1200_NO_IC // // Do not implement Data MMU // //`define OR1200_NO_DMMU // // Do not implement Insn MMU // //`define OR1200_NO_IMMU // // Select between ASIC optimized and generic multiplier // //`define OR1200_ASIC_MULTP2_32X32 `define OR1200_GENERIC_MULTP2_32X32 // // Size/type of insn/data cache if implemented // // `define OR1200_IC_1W_512B // `define OR1200_IC_1W_4KB `define OR1200_IC_1W_8KB // `define OR1200_DC_1W_4KB `define OR1200_DC_1W_8KB `else ///////////////////////////////////////////////////////// // // Typical configuration for an FPGA // // // Target FPGA memories // //`define OR1200_ALTERA_LPM //`define OR1200_XILINX_RAMB16 //`define OR1200_XILINX_RAMB4 //`define OR1200_XILINX_RAM32X1D //`define OR1200_USE_RAM16X1D_FOR_RAM32X1D // Generic models should infer RAM blocks at synthesis time (not only effects // single port ram.) `define OR1200_GENERIC // // Do not implement Data cache // //`define OR1200_NO_DC // // Do not implement Insn cache // //`define OR1200_NO_IC // // Do not implement Data MMU // //`define OR1200_NO_DMMU // // Do not implement Insn MMU // //`define OR1200_NO_IMMU // // Select between ASIC and generic multiplier // // (Generic seems to trigger a bug in the Cadence Ncsim simulator) // //`define OR1200_ASIC_MULTP2_32X32 `define OR1200_GENERIC_MULTP2_32X32 // // Size/type of insn/data cache if implemented // (consider available FPGA memory resources) // //`define OR1200_IC_1W_512B //`define OR1200_IC_1W_4KB `define OR1200_IC_1W_8KB //`define OR1200_DC_1W_4KB `define OR1200_DC_1W_8KB `endif ////////////////////////////////////////////////////////// // // Do not change below unless you know what you are doing // // // Reset active low // //`define OR1200_RST_ACT_LOW // // Enable RAM BIST // // At the moment this only works for Virtual Silicon // single port RAMs. For other RAMs it has not effect. // Special wrapper for VS RAMs needs to be provided // with scan flops to facilitate bist scan. // //`define OR1200_BIST // // Register OR1200 WISHBONE outputs // (must be defined/enabled) // `define OR1200_REGISTERED_OUTPUTS // // Register OR1200 WISHBONE inputs // // (must be undefined/disabled) // //`define OR1200_REGISTERED_INPUTS // // Disable bursts if they are not supported by the // memory subsystem (only affect cache line fill) // //`define OR1200_NO_BURSTS // // // WISHBONE retry counter range // // 2^value range for retry counter. Retry counter // is activated whenever *wb_rty_i is asserted and // until retry counter expires, corresponding // WISHBONE interface is deactivated. // // To disable retry counters and *wb_rty_i all together, // undefine this macro. // //`define OR1200_WB_RETRY 7 // // WISHBONE Consecutive Address Burst // // This was used prior to WISHBONE B3 specification // to identify bursts. It is no longer needed but // remains enabled for compatibility with old designs. // // To remove *wb_cab_o ports undefine this macro. // //`define OR1200_WB_CAB // // WISHBONE B3 compatible interface // // This follows the WISHBONE B3 specification. // It is not enabled by default because most // designs still don't use WB b3. // // To enable *wb_cti_o/*wb_bte_o ports, // define this macro. // `define OR1200_WB_B3 // // LOG all WISHBONE accesses // `define OR1200_LOG_WB_ACCESS // // Enable additional synthesis directives if using // _Synopsys_ synthesis tool // //`define OR1200_ADDITIONAL_SYNOPSYS_DIRECTIVES // // Enables default statement in some case blocks // and disables Synopsys synthesis directive full_case // // By default it is enabled. When disabled it // can increase clock frequency. // `define OR1200_CASE_DEFAULT // // Operand width / register file address width // // (DO NOT CHANGE) // `define OR1200_OPERAND_WIDTH 32 `define OR1200_REGFILE_ADDR_WIDTH 5 // // l.add/l.addi/l.and and optional l.addc/l.addic // also set (compare) flag when result of their // operation equals zero // // At the time of writing this, default or32 // C/C++ compiler doesn't generate code that // would benefit from this optimization. // // By default this optimization is disabled to // save area. // //`define OR1200_ADDITIONAL_FLAG_MODIFIERS // // Implement l.addc/l.addic instructions // // By default implementation of l.addc/l.addic // instructions is enabled in case you need them. // If you don't use them, then disable implementation // to save area. // //`define OR1200_IMPL_ADDC // // Implement l.sub instruction // // By default implementation of l.sub instructions // is enabled to be compliant with the simulator. // If you don't use carry bit, then disable // implementation to save area. // `define OR1200_IMPL_SUB // // Implement carry bit SR[CY] // // // By default implementation of SR[CY] is enabled // to be compliant with the simulator. However SR[CY] // is explicitly only used by l.addc/l.addic/l.sub // instructions and if these three insns are not // implemented there is not much point having SR[CY]. // //`define OR1200_IMPL_CY // // Implement rotate in the ALU // // At the time of writing this, or32 // C/C++ compiler doesn't generate rotate // instructions. However or32 assembler // can assemble code that uses rotate insn. // This means that rotate instructions // must be used manually inserted. // // By default implementation of rotate // is disabled to save area and increase // clock frequency. // //`define OR1200_IMPL_ALU_ROTATE // // Type of ALU compare to implement // // Try either one to find what yields // higher clock frequencyin your case. // //`define OR1200_IMPL_ALU_COMP1 `define OR1200_IMPL_ALU_COMP2 // // Implement Find First/Last '1' // `define OR1200_IMPL_ALU_FFL1 // // Implement multiplier // // By default multiplier is implemented // `define OR1200_MULT_IMPLEMENTED // // Implement multiply-and-accumulate // // By default MAC is implemented. To // implement MAC, multiplier needs to be // implemented. // `define OR1200_MAC_IMPLEMENTED // // Implement optional l.div/l.divu instructions // // By default divide instructions are not implemented // to save area and increase clock frequency. or32 C/C++ // compiler can use soft library for division. // // To implement divide, both multiplier and MAC needs to be implemented. // `define OR1200_DIV_IMPLEMENTED // // Low power, slower multiplier // // Select between low-power (larger) multiplier // and faster multiplier. The actual difference // is only AND logic that prevents distribution // of operands into the multiplier when instruction // in execution is not multiply instruction // //`define OR1200_LOWPWR_MULT // // Implement HW Single Precision FPU // `define OR1200_FPU_IMPLEMENTED // // Clock ratio RISC clock versus WB clock // // If you plan to run WB:RISC clock fixed to 1:1, disable // both defines // // For WB:RISC 1:2 or 1:1, enable OR1200_CLKDIV_2_SUPPORTED // and use clmode to set ratio // // For WB:RISC 1:4, 1:2 or 1:1, enable both defines and use // clmode to set ratio // //`define OR1200_CLKDIV_2_SUPPORTED //`define OR1200_CLKDIV_4_SUPPORTED // // Type of register file RAM // // Memory macro w/ two ports (see or1200_tpram_32x32.v) //`define OR1200_RFRAM_TWOPORT // // Memory macro dual port (see or1200_dpram.v) `define OR1200_RFRAM_DUALPORT // // Generic (flip-flop based) register file (see or1200_rfram_generic.v) //`define OR1200_RFRAM_GENERIC // Generic register file supports - 16 registers `ifdef OR1200_RFRAM_GENERIC // `define OR1200_RFRAM_16REG `endif // // Type of mem2reg aligner to implement. // // Once OR1200_IMPL_MEM2REG2 yielded faster // circuit, however with today tools it will // most probably give you slower circuit. // `define OR1200_IMPL_MEM2REG1 //`define OR1200_IMPL_MEM2REG2 // // Reset value and event // `ifdef OR1200_RST_ACT_LOW `define OR1200_RST_VALUE (1'b0) `define OR1200_RST_EVENT negedge `else `define OR1200_RST_VALUE (1'b1) `define OR1200_RST_EVENT posedge `endif // // ALUOPs // `define OR1200_ALUOP_WIDTH 4 `define OR1200_ALUOP_NOP 4'd4 /* Order defined by arith insns that have two source operands both in regs (see binutils/include/opcode/or32.h) */ `define OR1200_ALUOP_ADD 4'd0 `define OR1200_ALUOP_ADDC 4'd1 `define OR1200_ALUOP_SUB 4'd2 `define OR1200_ALUOP_AND 4'd3 `define OR1200_ALUOP_OR 4'd4 `define OR1200_ALUOP_XOR 4'd5 `define OR1200_ALUOP_MUL 4'd6 `define OR1200_ALUOP_CUST5 4'd7 `define OR1200_ALUOP_SHROT 4'd8 `define OR1200_ALUOP_DIV 4'd9 `define OR1200_ALUOP_DIVU 4'd10 /* Order not specifically defined. */ `define OR1200_ALUOP_IMM 4'd11 `define OR1200_ALUOP_MOVHI 4'd12 `define OR1200_ALUOP_COMP 4'd13 `define OR1200_ALUOP_MTSR 4'd14 `define OR1200_ALUOP_MFSR 4'd15 `define OR1200_ALUOP_CMOV 4'd14 `define OR1200_ALUOP_FFL1 4'd15 // ALU instructions second opcode field (previously multicycle field in // machine word) `define OR1200_ALUOP2_POS 9:8 `define OR1200_ALUOP2_WIDTH 2 // // MACOPs // `define OR1200_MACOP_WIDTH 3 `define OR1200_MACOP_NOP 3'b000 `define OR1200_MACOP_MAC 3'b001 `define OR1200_MACOP_MSB 3'b010 // // Shift/rotate ops // `define OR1200_SHROTOP_WIDTH 2 `define OR1200_SHROTOP_NOP 2'd0 `define OR1200_SHROTOP_SLL 2'd0 `define OR1200_SHROTOP_SRL 2'd1 `define OR1200_SHROTOP_SRA 2'd2 `define OR1200_SHROTOP_ROR 2'd3 // Execution cycles per instruction `define OR1200_MULTICYCLE_WIDTH 3 `define OR1200_ONE_CYCLE 3'd0 `define OR1200_TWO_CYCLES 3'd1 // Execution control which will "wait on" a module to finish `define OR1200_WAIT_ON_WIDTH 2 `define OR1200_WAIT_ON_FPU `OR1200_WAIT_ON_WIDTH'd1 `define OR1200_WAIT_ON_MTSPR `OR1200_WAIT_ON_WIDTH'd2 // Operand MUX selects `define OR1200_SEL_WIDTH 2 `define OR1200_SEL_RF 2'd0 `define OR1200_SEL_IMM 2'd1 `define OR1200_SEL_EX_FORW 2'd2 `define OR1200_SEL_WB_FORW 2'd3 // // BRANCHOPs // `define OR1200_BRANCHOP_WIDTH 3 `define OR1200_BRANCHOP_NOP 3'd0 `define OR1200_BRANCHOP_J 3'd1 `define OR1200_BRANCHOP_JR 3'd2 `define OR1200_BRANCHOP_BAL 3'd3 `define OR1200_BRANCHOP_BF 3'd4 `define OR1200_BRANCHOP_BNF 3'd5 `define OR1200_BRANCHOP_RFE 3'd6 // // LSUOPs // // Bit 0: sign extend // Bits 1-2: 00 doubleword, 01 byte, 10 halfword, 11 singleword // Bit 3: 0 load, 1 store `define OR1200_LSUOP_WIDTH 4 `define OR1200_LSUOP_NOP 4'b0000 `define OR1200_LSUOP_LBZ 4'b0010 `define OR1200_LSUOP_LBS 4'b0011 `define OR1200_LSUOP_LHZ 4'b0100 `define OR1200_LSUOP_LHS 4'b0101 `define OR1200_LSUOP_LWZ 4'b0110 `define OR1200_LSUOP_LWS 4'b0111 `define OR1200_LSUOP_LD 4'b0001 `define OR1200_LSUOP_SD 4'b1000 `define OR1200_LSUOP_SB 4'b1010 `define OR1200_LSUOP_SH 4'b1100 `define OR1200_LSUOP_SW 4'b1110 // Number of bits of load/store EA precalculated in ID stage // for balancing ID and EX stages. // // Valid range: 2,3,...,30,31 `define OR1200_LSUEA_PRECALC 2 // FETCHOPs `define OR1200_FETCHOP_WIDTH 1 `define OR1200_FETCHOP_NOP 1'b0 `define OR1200_FETCHOP_LW 1'b1 // // Register File Write-Back OPs // // Bit 0: register file write enable // Bits 3-1: write-back mux selects // `define OR1200_RFWBOP_WIDTH 4 `define OR1200_RFWBOP_NOP 4'b0000 `define OR1200_RFWBOP_ALU 3'b000 `define OR1200_RFWBOP_LSU 3'b001 `define OR1200_RFWBOP_SPRS 3'b010 `define OR1200_RFWBOP_LR 3'b011 `define OR1200_RFWBOP_FPU 3'b100 // Compare instructions `define OR1200_COP_SFEQ 3'b000 `define OR1200_COP_SFNE 3'b001 `define OR1200_COP_SFGT 3'b010 `define OR1200_COP_SFGE 3'b011 `define OR1200_COP_SFLT 3'b100 `define OR1200_COP_SFLE 3'b101 `define OR1200_COP_X 3'b111 `define OR1200_SIGNED_COMPARE 'd3 `define OR1200_COMPOP_WIDTH 4 // // FP OPs // // MSbit indicates FPU operation valid // `define OR1200_FPUOP_WIDTH 8 // FPU unit from Usselman takes 5 cycles from decode, so 4 ex. cycles `define OR1200_FPUOP_CYCLES 3'd4 // FP instruction is double precision if bit 4 is set. We're a 32-bit // implementation thus do not support double precision FP `define OR1200_FPUOP_DOUBLE_BIT 4 `define OR1200_FPUOP_ADD 8'b0000_0000 `define OR1200_FPUOP_SUB 8'b0000_0001 `define OR1200_FPUOP_MUL 8'b0000_0010 `define OR1200_FPUOP_DIV 8'b0000_0011 `define OR1200_FPUOP_ITOF 8'b0000_0100 `define OR1200_FPUOP_FTOI 8'b0000_0101 `define OR1200_FPUOP_REM 8'b0000_0110 `define OR1200_FPUOP_RESERVED 8'b0000_0111 // FP Compare instructions `define OR1200_FPCOP_SFEQ 8'b0000_1000 `define OR1200_FPCOP_SFNE 8'b0000_1001 `define OR1200_FPCOP_SFGT 8'b0000_1010 `define OR1200_FPCOP_SFGE 8'b0000_1011 `define OR1200_FPCOP_SFLT 8'b0000_1100 `define OR1200_FPCOP_SFLE 8'b0000_1101 // // TAGs for instruction bus // `define OR1200_ITAG_IDLE 4'h0 // idle bus `define OR1200_ITAG_NI 4'h1 // normal insn `define OR1200_ITAG_BE 4'hb // Bus error exception `define OR1200_ITAG_PE 4'hc // Page fault exception `define OR1200_ITAG_TE 4'hd // TLB miss exception // // TAGs for data bus // `define OR1200_DTAG_IDLE 4'h0 // idle bus `define OR1200_DTAG_ND 4'h1 // normal data `define OR1200_DTAG_AE 4'ha // Alignment exception `define OR1200_DTAG_BE 4'hb // Bus error exception `define OR1200_DTAG_PE 4'hc // Page fault exception `define OR1200_DTAG_TE 4'hd // TLB miss exception ////////////////////////////////////////////// // // ORBIS32 ISA specifics // // SHROT_OP position in machine word `define OR1200_SHROTOP_POS 7:6 // // Instruction opcode groups (basic) // `define OR1200_OR32_J 6'b000000 `define OR1200_OR32_JAL 6'b000001 `define OR1200_OR32_BNF 6'b000011 `define OR1200_OR32_BF 6'b000100 `define OR1200_OR32_NOP 6'b000101 `define OR1200_OR32_MOVHI 6'b000110 `define OR1200_OR32_XSYNC 6'b001000 `define OR1200_OR32_RFE 6'b001001 /* */ `define OR1200_OR32_JR 6'b010001 `define OR1200_OR32_JALR 6'b010010 `define OR1200_OR32_MACI 6'b010011 /* */ `define OR1200_OR32_LWZ 6'b100001 `define OR1200_OR32_LBZ 6'b100011 `define OR1200_OR32_LBS 6'b100100 `define OR1200_OR32_LHZ 6'b100101 `define OR1200_OR32_LHS 6'b100110 `define OR1200_OR32_ADDI 6'b100111 `define OR1200_OR32_ADDIC 6'b101000 `define OR1200_OR32_ANDI 6'b101001 `define OR1200_OR32_ORI 6'b101010 `define OR1200_OR32_XORI 6'b101011 `define OR1200_OR32_MULI 6'b101100 `define OR1200_OR32_MFSPR 6'b101101 `define OR1200_OR32_SH_ROTI 6'b101110 `define OR1200_OR32_SFXXI 6'b101111 /* */ `define OR1200_OR32_MTSPR 6'b110000 `define OR1200_OR32_MACMSB 6'b110001 `define OR1200_OR32_FLOAT 6'b110010 /* */ `define OR1200_OR32_SW 6'b110101 `define OR1200_OR32_SB 6'b110110 `define OR1200_OR32_SH 6'b110111 `define OR1200_OR32_ALU 6'b111000 `define OR1200_OR32_SFXX 6'b111001 //`define OR1200_OR32_CUST5 6'b111100 ///////////////////////////////////////////////////// // // Exceptions // // // Exception vectors per OR1K architecture: // 0xPPPPP100 - reset // 0xPPPPP200 - bus error // ... etc // where P represents exception prefix. // // Exception vectors can be customized as per // the following formula: // 0xPPPPPNVV - exception N // // P represents exception prefix // N represents exception N // VV represents length of the individual vector space, // usually it is 8 bits wide and starts with all bits zero // // // PPPPP and VV parts // // Sum of these two defines needs to be 28 // `define OR1200_EXCEPT_EPH0_P 20'h00000 `define OR1200_EXCEPT_EPH1_P 20'hF0000 `define OR1200_EXCEPT_V 8'h00 // // N part width // `define OR1200_EXCEPT_WIDTH 4 // // Definition of exception vectors // // To avoid implementation of a certain exception, // simply comment out corresponding line // `define OR1200_EXCEPT_UNUSED `OR1200_EXCEPT_WIDTH'hf `define OR1200_EXCEPT_TRAP `OR1200_EXCEPT_WIDTH'he `define OR1200_EXCEPT_FLOAT `OR1200_EXCEPT_WIDTH'hd `define OR1200_EXCEPT_SYSCALL `OR1200_EXCEPT_WIDTH'hc `define OR1200_EXCEPT_RANGE `OR1200_EXCEPT_WIDTH'hb `define OR1200_EXCEPT_ITLBMISS `OR1200_EXCEPT_WIDTH'ha `define OR1200_EXCEPT_DTLBMISS `OR1200_EXCEPT_WIDTH'h9 `define OR1200_EXCEPT_INT `OR1200_EXCEPT_WIDTH'h8 `define OR1200_EXCEPT_ILLEGAL `OR1200_EXCEPT_WIDTH'h7 `define OR1200_EXCEPT_ALIGN `OR1200_EXCEPT_WIDTH'h6 `define OR1200_EXCEPT_TICK `OR1200_EXCEPT_WIDTH'h5 `define OR1200_EXCEPT_IPF `OR1200_EXCEPT_WIDTH'h4 `define OR1200_EXCEPT_DPF `OR1200_EXCEPT_WIDTH'h3 `define OR1200_EXCEPT_BUSERR `OR1200_EXCEPT_WIDTH'h2 `define OR1200_EXCEPT_RESET `OR1200_EXCEPT_WIDTH'h1 `define OR1200_EXCEPT_NONE `OR1200_EXCEPT_WIDTH'h0 ///////////////////////////////////////////////////// // // SPR groups // // Bits that define the group `define OR1200_SPR_GROUP_BITS 15:11 // Width of the group bits `define OR1200_SPR_GROUP_WIDTH 5 // Bits that define offset inside the group `define OR1200_SPR_OFS_BITS 10:0 // List of groups `define OR1200_SPR_GROUP_SYS 5'd00 `define OR1200_SPR_GROUP_DMMU 5'd01 `define OR1200_SPR_GROUP_IMMU 5'd02 `define OR1200_SPR_GROUP_DC 5'd03 `define OR1200_SPR_GROUP_IC 5'd04 `define OR1200_SPR_GROUP_MAC 5'd05 `define OR1200_SPR_GROUP_DU 5'd06 `define OR1200_SPR_GROUP_PM 5'd08 `define OR1200_SPR_GROUP_PIC 5'd09 `define OR1200_SPR_GROUP_TT 5'd10 `define OR1200_SPR_GROUP_FPU 5'd11 ///////////////////////////////////////////////////// // // System group // // // System registers // `define OR1200_SPR_CFGR 7'd0 `define OR1200_SPR_RF 6'd32 // 1024 >> 5 `define OR1200_SPR_NPC 11'd16 `define OR1200_SPR_SR 11'd17 `define OR1200_SPR_PPC 11'd18 `define OR1200_SPR_FPCSR 11'd20 `define OR1200_SPR_EPCR 11'd32 `define OR1200_SPR_EEAR 11'd48 `define OR1200_SPR_ESR 11'd64 // // SR bits // `define OR1200_SR_WIDTH 17 `define OR1200_SR_SM 0 `define OR1200_SR_TEE 1 `define OR1200_SR_IEE 2 `define OR1200_SR_DCE 3 `define OR1200_SR_ICE 4 `define OR1200_SR_DME 5 `define OR1200_SR_IME 6 `define OR1200_SR_LEE 7 `define OR1200_SR_CE 8 `define OR1200_SR_F 9 `define OR1200_SR_CY 10 // Unused `define OR1200_SR_OV 11 // Unused `define OR1200_SR_OVE 12 // Unused `define OR1200_SR_DSX 13 // Unused `define OR1200_SR_EPH 14 `define OR1200_SR_FO 15 `define OR1200_SR_TED 16 `define OR1200_SR_CID 31:28 // Unimplemented // // Bits that define offset inside the group // `define OR1200_SPROFS_BITS 10:0 // // Default Exception Prefix // // 1'b0 - OR1200_EXCEPT_EPH0_P (0x0000_0000) // 1'b1 - OR1200_EXCEPT_EPH1_P (0xF000_0000) // `define OR1200_SR_EPH_DEF 1'b0 // // FPCSR bits // `define OR1200_FPCSR_WIDTH 12 `define OR1200_FPCSR_FPEE 0 `define OR1200_FPCSR_RM 2:1 `define OR1200_FPCSR_OVF 3 `define OR1200_FPCSR_UNF 4 `define OR1200_FPCSR_SNF 5 `define OR1200_FPCSR_QNF 6 `define OR1200_FPCSR_ZF 7 `define OR1200_FPCSR_IXF 8 `define OR1200_FPCSR_IVF 9 `define OR1200_FPCSR_INF 10 `define OR1200_FPCSR_DZF 11 `define OR1200_FPCSR_RES 31:12 ///////////////////////////////////////////////////// // // Power Management (PM) // // Define it if you want PM implemented //`define OR1200_PM_IMPLEMENTED // Bit positions inside PMR (don't change) `define OR1200_PM_PMR_SDF 3:0 `define OR1200_PM_PMR_DME 4 `define OR1200_PM_PMR_SME 5 `define OR1200_PM_PMR_DCGE 6 `define OR1200_PM_PMR_UNUSED 31:7 // PMR offset inside PM group of registers `define OR1200_PM_OFS_PMR 11'b0 // PM group `define OR1200_SPRGRP_PM 5'd8 // Define if PMR can be read/written at any address inside PM group `define OR1200_PM_PARTIAL_DECODING // Define if reading PMR is allowed `define OR1200_PM_READREGS // Define if unused PMR bits should be zero `define OR1200_PM_UNUSED_ZERO ///////////////////////////////////////////////////// // // Debug Unit (DU) // // Define it if you want DU implemented `define OR1200_DU_IMPLEMENTED // // Define if you want HW Breakpoints // (if HW breakpoints are not implemented // only default software trapping is // possible with l.trap insn - this is // however already enough for use // with or32 gdb) // //`define OR1200_DU_HWBKPTS // Number of DVR/DCR pairs if HW breakpoints enabled // Comment / uncomment DU_DVRn / DU_DCRn pairs bellow according to this number ! // DU_DVR0..DU_DVR7 should be uncommented for 8 DU_DVRDCR_PAIRS `define OR1200_DU_DVRDCR_PAIRS 8 // Define if you want trace buffer // (for now only available for Xilinx Virtex FPGAs) //`define OR1200_DU_TB_IMPLEMENTED // // Address offsets of DU registers inside DU group // // To not implement a register, doq not define its address // `ifdef OR1200_DU_HWBKPTS `define OR1200_DU_DVR0 11'd0 `define OR1200_DU_DVR1 11'd1 `define OR1200_DU_DVR2 11'd2 `define OR1200_DU_DVR3 11'd3 `define OR1200_DU_DVR4 11'd4 `define OR1200_DU_DVR5 11'd5 `define OR1200_DU_DVR6 11'd6 `define OR1200_DU_DVR7 11'd7 `define OR1200_DU_DCR0 11'd8 `define OR1200_DU_DCR1 11'd9 `define OR1200_DU_DCR2 11'd10 `define OR1200_DU_DCR3 11'd11 `define OR1200_DU_DCR4 11'd12 `define OR1200_DU_DCR5 11'd13 `define OR1200_DU_DCR6 11'd14 `define OR1200_DU_DCR7 11'd15 `endif `define OR1200_DU_DMR1 11'd16 `ifdef OR1200_DU_HWBKPTS `define OR1200_DU_DMR2 11'd17 `define OR1200_DU_DWCR0 11'd18 `define OR1200_DU_DWCR1 11'd19 `endif `define OR1200_DU_DSR 11'd20 `define OR1200_DU_DRR 11'd21 `ifdef OR1200_DU_TB_IMPLEMENTED `define OR1200_DU_TBADR 11'h0ff `define OR1200_DU_TBIA 11'h1?? `define OR1200_DU_TBIM 11'h2?? `define OR1200_DU_TBAR 11'h3?? `define OR1200_DU_TBTS 11'h4?? `endif // Position of offset bits inside SPR address `define OR1200_DUOFS_BITS 10:0 // DCR bits `define OR1200_DU_DCR_DP 0 `define OR1200_DU_DCR_CC 3:1 `define OR1200_DU_DCR_SC 4 `define OR1200_DU_DCR_CT 7:5 // DMR1 bits `define OR1200_DU_DMR1_CW0 1:0 `define OR1200_DU_DMR1_CW1 3:2 `define OR1200_DU_DMR1_CW2 5:4 `define OR1200_DU_DMR1_CW3 7:6 `define OR1200_DU_DMR1_CW4 9:8 `define OR1200_DU_DMR1_CW5 11:10 `define OR1200_DU_DMR1_CW6 13:12 `define OR1200_DU_DMR1_CW7 15:14 `define OR1200_DU_DMR1_CW8 17:16 `define OR1200_DU_DMR1_CW9 19:18 `define OR1200_DU_DMR1_CW10 21:20 `define OR1200_DU_DMR1_ST 22 `define OR1200_DU_DMR1_BT 23 `define OR1200_DU_DMR1_DXFW 24 `define OR1200_DU_DMR1_ETE 25 // DMR2 bits `define OR1200_DU_DMR2_WCE0 0 `define OR1200_DU_DMR2_WCE1 1 `define OR1200_DU_DMR2_AWTC 12:2 `define OR1200_DU_DMR2_WGB 23:13 // DWCR bits `define OR1200_DU_DWCR_COUNT 15:0 `define OR1200_DU_DWCR_MATCH 31:16 // DSR bits `define OR1200_DU_DSR_WIDTH 14 `define OR1200_DU_DSR_RSTE 0 `define OR1200_DU_DSR_BUSEE 1 `define OR1200_DU_DSR_DPFE 2 `define OR1200_DU_DSR_IPFE 3 `define OR1200_DU_DSR_TTE 4 `define OR1200_DU_DSR_AE 5 `define OR1200_DU_DSR_IIE 6 `define OR1200_DU_DSR_IE 7 `define OR1200_DU_DSR_DME 8 `define OR1200_DU_DSR_IME 9 `define OR1200_DU_DSR_RE 10 `define OR1200_DU_DSR_SCE 11 `define OR1200_DU_DSR_FPE 12 `define OR1200_DU_DSR_TE 13 // DRR bits `define OR1200_DU_DRR_RSTE 0 `define OR1200_DU_DRR_BUSEE 1 `define OR1200_DU_DRR_DPFE 2 `define OR1200_DU_DRR_IPFE 3 `define OR1200_DU_DRR_TTE 4 `define OR1200_DU_DRR_AE 5 `define OR1200_DU_DRR_IIE 6 `define OR1200_DU_DRR_IE 7 `define OR1200_DU_DRR_DME 8 `define OR1200_DU_DRR_IME 9 `define OR1200_DU_DRR_RE 10 `define OR1200_DU_DRR_SCE 11 `define OR1200_DU_DRR_FPE 12 `define OR1200_DU_DRR_TE 13 // Define if reading DU regs is allowed `define OR1200_DU_READREGS // Define if unused DU registers bits should be zero `define OR1200_DU_UNUSED_ZERO // Define if IF/LSU status is not needed by devel i/f `define OR1200_DU_STATUS_UNIMPLEMENTED ///////////////////////////////////////////////////// // // Programmable Interrupt Controller (PIC) // // Define it if you want PIC implemented `define OR1200_PIC_IMPLEMENTED // Define number of interrupt inputs (2-31) `define OR1200_PIC_INTS 31 // Address offsets of PIC registers inside PIC group `define OR1200_PIC_OFS_PICMR 2'd0 `define OR1200_PIC_OFS_PICSR 2'd2 // Position of offset bits inside SPR address `define OR1200_PICOFS_BITS 1:0 // Define if you want these PIC registers to be implemented `define OR1200_PIC_PICMR `define OR1200_PIC_PICSR // Define if reading PIC registers is allowed `define OR1200_PIC_READREGS // Define if unused PIC register bits should be zero `define OR1200_PIC_UNUSED_ZERO ///////////////////////////////////////////////////// // // Tick Timer (TT) // // Define it if you want TT implemented `define OR1200_TT_IMPLEMENTED // Address offsets of TT registers inside TT group `define OR1200_TT_OFS_TTMR 1'd0 `define OR1200_TT_OFS_TTCR 1'd1 // Position of offset bits inside SPR group `define OR1200_TTOFS_BITS 0 // Define if you want these TT registers to be implemented `define OR1200_TT_TTMR `define OR1200_TT_TTCR // TTMR bits `define OR1200_TT_TTMR_TP 27:0 `define OR1200_TT_TTMR_IP 28 `define OR1200_TT_TTMR_IE 29 `define OR1200_TT_TTMR_M 31:30 // Define if reading TT registers is allowed `define OR1200_TT_READREGS ////////////////////////////////////////////// // // MAC // `define OR1200_MAC_ADDR 0 // MACLO 0xxxxxxxx1, MACHI 0xxxxxxxx0 `define OR1200_MAC_SPR_WE // Define if MACLO/MACHI are SPR writable // // Shift {MACHI,MACLO} into destination register when executing l.macrc // // According to architecture manual there is no shift, so default value is 0. // However the implementation has deviated in this from the arch manual and had // hard coded shift by 28 bits which is a useful optimization for MP3 decoding // (if using libmad fixed point library). Shifts are no longer default setup, // but if you need to remain backward compatible, define your shift bits, which // were normally // dest_GPR = {MACHI,MACLO}[59:28] `define OR1200_MAC_SHIFTBY 0 // 0 = According to arch manual, 28 = obsolete backward compatibility ////////////////////////////////////////////// // // Data MMU (DMMU) // // // Address that selects between TLB TR and MR // `define OR1200_DTLB_TM_ADDR 7 // // DTLBMR fields // `define OR1200_DTLBMR_V_BITS 0 `define OR1200_DTLBMR_CID_BITS 4:1 `define OR1200_DTLBMR_RES_BITS 11:5 `define OR1200_DTLBMR_VPN_BITS 31:13 // // DTLBTR fields // `define OR1200_DTLBTR_CC_BITS 0 `define OR1200_DTLBTR_CI_BITS 1 `define OR1200_DTLBTR_WBC_BITS 2 `define OR1200_DTLBTR_WOM_BITS 3 `define OR1200_DTLBTR_A_BITS 4 `define OR1200_DTLBTR_D_BITS 5 `define OR1200_DTLBTR_URE_BITS 6 `define OR1200_DTLBTR_UWE_BITS 7 `define OR1200_DTLBTR_SRE_BITS 8 `define OR1200_DTLBTR_SWE_BITS 9 `define OR1200_DTLBTR_RES_BITS 11:10 `define OR1200_DTLBTR_PPN_BITS 31:13 // // DTLB configuration // `define OR1200_DMMU_PS 13 // 13 for 8KB page size `define OR1200_DTLB_INDXW 6 // 6 for 64 entry DTLB 7 for 128 entries `define OR1200_DTLB_INDXL `OR1200_DMMU_PS // 13 13 `define OR1200_DTLB_INDXH `OR1200_DMMU_PS+`OR1200_DTLB_INDXW-1 // 18 19 `define OR1200_DTLB_INDX `OR1200_DTLB_INDXH:`OR1200_DTLB_INDXL // 18:13 19:13 `define OR1200_DTLB_TAGW 32-`OR1200_DTLB_INDXW-`OR1200_DMMU_PS // 13 12 `define OR1200_DTLB_TAGL `OR1200_DTLB_INDXH+1 // 19 20 `define OR1200_DTLB_TAG 31:`OR1200_DTLB_TAGL // 31:19 31:20 `define OR1200_DTLBMRW `OR1200_DTLB_TAGW+1 // +1 because of V bit `define OR1200_DTLBTRW 32-`OR1200_DMMU_PS+5 // +5 because of protection bits and CI // // Cache inhibit while DMMU is not enabled/implemented // // cache inhibited 0GB-4GB 1'b1 // cache inhibited 0GB-2GB !dcpu_adr_i[31] // cache inhibited 0GB-1GB 2GB-3GB !dcpu_adr_i[30] // cache inhibited 1GB-2GB 3GB-4GB dcpu_adr_i[30] // cache inhibited 2GB-4GB (default) dcpu_adr_i[31] // cached 0GB-4GB 1'b0 // `define OR1200_DMMU_CI dcpu_adr_i[31] ////////////////////////////////////////////// // // Insn MMU (IMMU) // // // Address that selects between TLB TR and MR // `define OR1200_ITLB_TM_ADDR 7 // // ITLBMR fields // `define OR1200_ITLBMR_V_BITS 0 `define OR1200_ITLBMR_CID_BITS 4:1 `define OR1200_ITLBMR_RES_BITS 11:5 `define OR1200_ITLBMR_VPN_BITS 31:13 // // ITLBTR fields // `define OR1200_ITLBTR_CC_BITS 0 `define OR1200_ITLBTR_CI_BITS 1 `define OR1200_ITLBTR_WBC_BITS 2 `define OR1200_ITLBTR_WOM_BITS 3 `define OR1200_ITLBTR_A_BITS 4 `define OR1200_ITLBTR_D_BITS 5 `define OR1200_ITLBTR_SXE_BITS 6 `define OR1200_ITLBTR_UXE_BITS 7 `define OR1200_ITLBTR_RES_BITS 11:8 `define OR1200_ITLBTR_PPN_BITS 31:13 // // ITLB configuration // `define OR1200_IMMU_PS 13 // 13 for 8KB page size `define OR1200_ITLB_INDXW 6 // 6 for 64 entry ITLB 7 for 128 entries `define OR1200_ITLB_INDXL `OR1200_IMMU_PS // 13 13 `define OR1200_ITLB_INDXH `OR1200_IMMU_PS+`OR1200_ITLB_INDXW-1 // 18 19 `define OR1200_ITLB_INDX `OR1200_ITLB_INDXH:`OR1200_ITLB_INDXL // 18:13 19:13 `define OR1200_ITLB_TAGW 32-`OR1200_ITLB_INDXW-`OR1200_IMMU_PS // 13 12 `define OR1200_ITLB_TAGL `OR1200_ITLB_INDXH+1 // 19 20 `define OR1200_ITLB_TAG 31:`OR1200_ITLB_TAGL // 31:19 31:20 `define OR1200_ITLBMRW `OR1200_ITLB_TAGW+1 // +1 because of V bit `define OR1200_ITLBTRW 32-`OR1200_IMMU_PS+3 // +3 because of protection bits and CI // // Cache inhibit while IMMU is not enabled/implemented // Note: all combinations that use icpu_adr_i cause async loop // // cache inhibited 0GB-4GB 1'b1 // cache inhibited 0GB-2GB !icpu_adr_i[31] // cache inhibited 0GB-1GB 2GB-3GB !icpu_adr_i[30] // cache inhibited 1GB-2GB 3GB-4GB icpu_adr_i[30] // cache inhibited 2GB-4GB (default) icpu_adr_i[31] // cached 0GB-4GB 1'b0 // `define OR1200_IMMU_CI 1'b0 ///////////////////////////////////////////////// // // Insn cache (IC) // // 3 for 8 bytes, 4 for 16 bytes etc `define OR1200_ICLS 4 // // IC configurations // `ifdef OR1200_IC_1W_512B `define OR1200_ICSIZE 9 // 512 `define OR1200_ICINDX `OR1200_ICSIZE-2 // 7 `define OR1200_ICINDXH `OR1200_ICSIZE-1 // 8 `define OR1200_ICTAGL `OR1200_ICINDXH+1 // 9 `define OR1200_ICTAG `OR1200_ICSIZE-`OR1200_ICLS // 5 `define OR1200_ICTAG_W 24 `endif `ifdef OR1200_IC_1W_4KB `define OR1200_ICSIZE 12 // 4096 `define OR1200_ICINDX `OR1200_ICSIZE-2 // 10 `define OR1200_ICINDXH `OR1200_ICSIZE-1 // 11 `define OR1200_ICTAGL `OR1200_ICINDXH+1 // 12 `define OR1200_ICTAG `OR1200_ICSIZE-`OR1200_ICLS // 8 `define OR1200_ICTAG_W 21 `endif `ifdef OR1200_IC_1W_8KB `define OR1200_ICSIZE 13 // 8192 `define OR1200_ICINDX `OR1200_ICSIZE-2 // 11 `define OR1200_ICINDXH `OR1200_ICSIZE-1 // 12 `define OR1200_ICTAGL `OR1200_ICINDXH+1 // 13 `define OR1200_ICTAG `OR1200_ICSIZE-`OR1200_ICLS // 9 `define OR1200_ICTAG_W 20 `endif ///////////////////////////////////////////////// // // Data cache (DC) // // 3 for 8 bytes, 4 for 16 bytes etc `define OR1200_DCLS 4 // Define to enable default behavior of cache as write through // Turning this off enabled write back statergy // `define OR1200_DC_WRITETHROUGH // Define to enable stores from the stack not doing writethrough. // EXPERIMENTAL //`define OR1200_DC_NOSTACKWRITETHROUGH // Data cache SPR definitions `define OR1200_SPRGRP_DC_ADR_WIDTH 3 // Data cache group SPR addresses `define OR1200_SPRGRP_DC_DCCR 3'd0 // Not implemented `define OR1200_SPRGRP_DC_DCBPR 3'd1 // Not implemented `define OR1200_SPRGRP_DC_DCBFR 3'd2 `define OR1200_SPRGRP_DC_DCBIR 3'd3 `define OR1200_SPRGRP_DC_DCBWR 3'd4 // Not implemented `define OR1200_SPRGRP_DC_DCBLR 3'd5 // Not implemented // // DC configurations // `ifdef OR1200_DC_1W_4KB `define OR1200_DCSIZE 12 // 4096 `define OR1200_DCINDX `OR1200_DCSIZE-2 // 10 `define OR1200_DCINDXH `OR1200_DCSIZE-1 // 11 `define OR1200_DCTAGL `OR1200_DCINDXH+1 // 12 `define OR1200_DCTAG `OR1200_DCSIZE-`OR1200_DCLS // 8 `define OR1200_DCTAG_W 21 `endif `ifdef OR1200_DC_1W_8KB `define OR1200_DCSIZE 13 // 8192 `define OR1200_DCINDX `OR1200_DCSIZE-2 // 11 `define OR1200_DCINDXH `OR1200_DCSIZE-1 // 12 `define OR1200_DCTAGL `OR1200_DCINDXH+1 // 13 `define OR1200_DCTAG `OR1200_DCSIZE-`OR1200_DCLS // 9 `define OR1200_DCTAG_W 20 `endif ///////////////////////////////////////////////// // // Store buffer (SB) // // // Store buffer // // It will improve performance by "caching" CPU stores // using store buffer. This is most important for function // prologues because DC can only work in write though mode // and all stores would have to complete external WB writes // to memory. // Store buffer is between DC and data BIU. // All stores will be stored into store buffer and immediately // completed by the CPU, even though actual external writes // will be performed later. As a consequence store buffer masks // all data bus errors related to stores (data bus errors // related to loads are delivered normally). // All pending CPU loads will wait until store buffer is empty to // ensure strict memory model. Right now this is necessary because // we don't make destinction between cached and cache inhibited // address space, so we simply empty store buffer until loads // can begin. // // It makes design a bit bigger, depending what is the number of // entries in SB FIFO. Number of entries can be changed further // down. // //`define OR1200_SB_IMPLEMENTED // // Number of store buffer entries // // Verified number of entries are 4 and 8 entries // (2 and 3 for OR1200_SB_LOG). OR1200_SB_ENTRIES must // always match 2**OR1200_SB_LOG. // To disable store buffer, undefine // OR1200_SB_IMPLEMENTED. // `define OR1200_SB_LOG 2 // 2 or 3 `define OR1200_SB_ENTRIES 4 // 4 or 8 ///////////////////////////////////////////////// // // Quick Embedded Memory (QMEM) // // // Quick Embedded Memory // // Instantiation of dedicated insn/data memory (RAM or ROM). // Insn fetch has effective throughput 1insn / clock cycle. // Data load takes two clock cycles / access, data store // takes 1 clock cycle / access (if there is no insn fetch)). // Memory instantiation is shared between insn and data, // meaning if insn fetch are performed, data load/store // performance will be lower. // // Main reason for QMEM is to put some time critical functions // into this memory and to have predictable and fast access // to these functions. (soft fpu, context switch, exception // handlers, stack, etc) // // It makes design a bit bigger and slower. QMEM sits behind // IMMU/DMMU so all addresses are physical (so the MMUs can be // used with QMEM and QMEM is seen by the CPU just like any other // memory in the system). IC/DC are sitting behind QMEM so the // whole design timing might be worse with QMEM implemented. // //`define OR1200_QMEM_IMPLEMENTED // // Base address and mask of QMEM // // Base address defines first address of QMEM. Mask defines // QMEM range in address space. Actual size of QMEM is however // determined with instantiated RAM/ROM. However bigger // mask will reserve more address space for QMEM, but also // make design faster, while more tight mask will take // less address space but also make design slower. If // instantiated RAM/ROM is smaller than space reserved with // the mask, instatiated RAM/ROM will also be shadowed // at higher addresses in reserved space. // `define OR1200_QMEM_IADDR 32'h0080_0000 `define OR1200_QMEM_IMASK 32'hfff0_0000 // Max QMEM size 1MB `define OR1200_QMEM_DADDR 32'h0080_0000 `define OR1200_QMEM_DMASK 32'hfff0_0000 // Max QMEM size 1MB // // QMEM interface byte-select capability // // To enable qmem_sel* ports, define this macro. // //`define OR1200_QMEM_BSEL // // QMEM interface acknowledge // // To enable qmem_ack port, define this macro. // //`define OR1200_QMEM_ACK ///////////////////////////////////////////////////// // // VR, UPR and Configuration Registers // // // VR, UPR and configuration registers are optional. If // implemented, operating system can automatically figure // out how to use the processor because it knows // what units are available in the processor and how they // are configured. // // This section must be last in or1200_defines.v file so // that all units are already configured and thus // configuration registers are properly set. // // Define if you want configuration registers implemented `define OR1200_CFGR_IMPLEMENTED // Define if you want full address decode inside SYS group `define OR1200_SYS_FULL_DECODE // Offsets of VR, UPR and CFGR registers `define OR1200_SPRGRP_SYS_VR 4'h0 `define OR1200_SPRGRP_SYS_UPR 4'h1 `define OR1200_SPRGRP_SYS_CPUCFGR 4'h2 `define OR1200_SPRGRP_SYS_DMMUCFGR 4'h3 `define OR1200_SPRGRP_SYS_IMMUCFGR 4'h4 `define OR1200_SPRGRP_SYS_DCCFGR 4'h5 `define OR1200_SPRGRP_SYS_ICCFGR 4'h6 `define OR1200_SPRGRP_SYS_DCFGR 4'h7 // VR fields `define OR1200_VR_REV_BITS 5:0 `define OR1200_VR_RES1_BITS 15:6 `define OR1200_VR_CFG_BITS 23:16 `define OR1200_VR_VER_BITS 31:24 // VR values `define OR1200_VR_REV 6'h08 `define OR1200_VR_RES1 10'h000 `define OR1200_VR_CFG 8'h00 `define OR1200_VR_VER 8'h12 // UPR fields `define OR1200_UPR_UP_BITS 0 `define OR1200_UPR_DCP_BITS 1 `define OR1200_UPR_ICP_BITS 2 `define OR1200_UPR_DMP_BITS 3 `define OR1200_UPR_IMP_BITS 4 `define OR1200_UPR_MP_BITS 5 `define OR1200_UPR_DUP_BITS 6 `define OR1200_UPR_PCUP_BITS 7 `define OR1200_UPR_PMP_BITS 8 `define OR1200_UPR_PICP_BITS 9 `define OR1200_UPR_TTP_BITS 10 `define OR1200_UPR_FPP_BITS 11 `define OR1200_UPR_RES1_BITS 23:12 `define OR1200_UPR_CUP_BITS 31:24 // UPR values `define OR1200_UPR_UP 1'b1 `ifdef OR1200_NO_DC `define OR1200_UPR_DCP 1'b0 `else `define OR1200_UPR_DCP 1'b1 `endif `ifdef OR1200_NO_IC `define OR1200_UPR_ICP 1'b0 `else `define OR1200_UPR_ICP 1'b1 `endif `ifdef OR1200_NO_DMMU `define OR1200_UPR_DMP 1'b0 `else `define OR1200_UPR_DMP 1'b1 `endif `ifdef OR1200_NO_IMMU `define OR1200_UPR_IMP 1'b0 `else `define OR1200_UPR_IMP 1'b1 `endif `ifdef OR1200_MAC_IMPLEMENTED `define OR1200_UPR_MP 1'b1 `else `define OR1200_UPR_MP 1'b0 `endif `ifdef OR1200_DU_IMPLEMENTED `define OR1200_UPR_DUP 1'b1 `else `define OR1200_UPR_DUP 1'b0 `endif `define OR1200_UPR_PCUP 1'b0 // Performance counters not present `ifdef OR1200_PM_IMPLEMENTED `define OR1200_UPR_PMP 1'b1 `else `define OR1200_UPR_PMP 1'b0 `endif `ifdef OR1200_PIC_IMPLEMENTED `define OR1200_UPR_PICP 1'b1 `else `define OR1200_UPR_PICP 1'b0 `endif `ifdef OR1200_TT_IMPLEMENTED `define OR1200_UPR_TTP 1'b1 `else `define OR1200_UPR_TTP 1'b0 `endif `ifdef OR1200_FPU_IMPLEMENTED `define OR1200_UPR_FPP 1'b1 `else `define OR1200_UPR_FPP 1'b0 `endif `define OR1200_UPR_RES1 12'h000 `define OR1200_UPR_CUP 8'h00 // CPUCFGR fields `define OR1200_CPUCFGR_NSGF_BITS 3:0 `define OR1200_CPUCFGR_HGF_BITS 4 `define OR1200_CPUCFGR_OB32S_BITS 5 `define OR1200_CPUCFGR_OB64S_BITS 6 `define OR1200_CPUCFGR_OF32S_BITS 7 `define OR1200_CPUCFGR_OF64S_BITS 8 `define OR1200_CPUCFGR_OV64S_BITS 9 `define OR1200_CPUCFGR_RES1_BITS 31:10 // CPUCFGR values `define OR1200_CPUCFGR_NSGF 4'h0 `ifdef OR1200_RFRAM_16REG `define OR1200_CPUCFGR_HGF 1'b1 `else `define OR1200_CPUCFGR_HGF 1'b0 `endif `define OR1200_CPUCFGR_OB32S 1'b1 `define OR1200_CPUCFGR_OB64S 1'b0 `ifdef OR1200_FPU_IMPLEMENTED `define OR1200_CPUCFGR_OF32S 1'b1 `else `define OR1200_CPUCFGR_OF32S 1'b0 `endif `define OR1200_CPUCFGR_OF64S 1'b0 `define OR1200_CPUCFGR_OV64S 1'b0 `define OR1200_CPUCFGR_RES1 22'h000000 // DMMUCFGR fields `define OR1200_DMMUCFGR_NTW_BITS 1:0 `define OR1200_DMMUCFGR_NTS_BITS 4:2 `define OR1200_DMMUCFGR_NAE_BITS 7:5 `define OR1200_DMMUCFGR_CRI_BITS 8 `define OR1200_DMMUCFGR_PRI_BITS 9 `define OR1200_DMMUCFGR_TEIRI_BITS 10 `define OR1200_DMMUCFGR_HTR_BITS 11 `define OR1200_DMMUCFGR_RES1_BITS 31:12 // DMMUCFGR values `ifdef OR1200_NO_DMMU `define OR1200_DMMUCFGR_NTW 2'h0 // Irrelevant `define OR1200_DMMUCFGR_NTS 3'h0 // Irrelevant `define OR1200_DMMUCFGR_NAE 3'h0 // Irrelevant `define OR1200_DMMUCFGR_CRI 1'b0 // Irrelevant `define OR1200_DMMUCFGR_PRI 1'b0 // Irrelevant `define OR1200_DMMUCFGR_TEIRI 1'b0 // Irrelevant `define OR1200_DMMUCFGR_HTR 1'b0 // Irrelevant `define OR1200_DMMUCFGR_RES1 20'h00000 `else `define OR1200_DMMUCFGR_NTW 2'h0 // 1 TLB way `define OR1200_DMMUCFGR_NTS 3'h`OR1200_DTLB_INDXW // Num TLB sets `define OR1200_DMMUCFGR_NAE 3'h0 // No ATB entries `define OR1200_DMMUCFGR_CRI 1'b0 // No control register `define OR1200_DMMUCFGR_PRI 1'b0 // No protection reg `define OR1200_DMMUCFGR_TEIRI 1'b1 // TLB entry inv reg impl. `define OR1200_DMMUCFGR_HTR 1'b0 // No HW TLB reload `define OR1200_DMMUCFGR_RES1 20'h00000 `endif // IMMUCFGR fields `define OR1200_IMMUCFGR_NTW_BITS 1:0 `define OR1200_IMMUCFGR_NTS_BITS 4:2 `define OR1200_IMMUCFGR_NAE_BITS 7:5 `define OR1200_IMMUCFGR_CRI_BITS 8 `define OR1200_IMMUCFGR_PRI_BITS 9 `define OR1200_IMMUCFGR_TEIRI_BITS 10 `define OR1200_IMMUCFGR_HTR_BITS 11 `define OR1200_IMMUCFGR_RES1_BITS 31:12 // IMMUCFGR values `ifdef OR1200_NO_IMMU `define OR1200_IMMUCFGR_NTW 2'h0 // Irrelevant `define OR1200_IMMUCFGR_NTS 3'h0 // Irrelevant `define OR1200_IMMUCFGR_NAE 3'h0 // Irrelevant `define OR1200_IMMUCFGR_CRI 1'b0 // Irrelevant `define OR1200_IMMUCFGR_PRI 1'b0 // Irrelevant `define OR1200_IMMUCFGR_TEIRI 1'b0 // Irrelevant `define OR1200_IMMUCFGR_HTR 1'b0 // Irrelevant `define OR1200_IMMUCFGR_RES1 20'h00000 `else `define OR1200_IMMUCFGR_NTW 2'h0 // 1 TLB way `define OR1200_IMMUCFGR_NTS 3'h`OR1200_ITLB_INDXW // Num TLB sets `define OR1200_IMMUCFGR_NAE 3'h0 // No ATB entry `define OR1200_IMMUCFGR_CRI 1'b0 // No control reg `define OR1200_IMMUCFGR_PRI 1'b0 // No protection reg `define OR1200_IMMUCFGR_TEIRI 1'b1 // TLB entry inv reg impl `define OR1200_IMMUCFGR_HTR 1'b0 // No HW TLB reload `define OR1200_IMMUCFGR_RES1 20'h00000 `endif // DCCFGR fields `define OR1200_DCCFGR_NCW_BITS 2:0 `define OR1200_DCCFGR_NCS_BITS 6:3 `define OR1200_DCCFGR_CBS_BITS 7 `define OR1200_DCCFGR_CWS_BITS 8 `define OR1200_DCCFGR_CCRI_BITS 9 `define OR1200_DCCFGR_CBIRI_BITS 10 `define OR1200_DCCFGR_CBPRI_BITS 11 `define OR1200_DCCFGR_CBLRI_BITS 12 `define OR1200_DCCFGR_CBFRI_BITS 13 `define OR1200_DCCFGR_CBWBRI_BITS 14 `define OR1200_DCCFGR_RES1_BITS 31:15 // DCCFGR values `ifdef OR1200_NO_DC `define OR1200_DCCFGR_NCW 3'h0 // Irrelevant `define OR1200_DCCFGR_NCS 4'h0 // Irrelevant `define OR1200_DCCFGR_CBS 1'b0 // Irrelevant `define OR1200_DCCFGR_CWS 1'b0 // Irrelevant `define OR1200_DCCFGR_CCRI 1'b0 // Irrelevant `define OR1200_DCCFGR_CBIRI 1'b0 // Irrelevant `define OR1200_DCCFGR_CBPRI 1'b0 // Irrelevant `define OR1200_DCCFGR_CBLRI 1'b0 // Irrelevant `define OR1200_DCCFGR_CBFRI 1'b0 // Irrelevant `define OR1200_DCCFGR_CBWBRI 1'b0 // Irrelevant `define OR1200_DCCFGR_RES1 17'h00000 `else `define OR1200_DCCFGR_NCW 3'h0 // 1 cache way `define OR1200_DCCFGR_NCS (`OR1200_DCTAG) // Num cache sets `define OR1200_DCCFGR_CBS `OR1200_DCLS==4 ? 1'b0 : 1'b1 // 16 byte cache block `ifdef OR1200_DC_WRITETHROUGH `define OR1200_DCCFGR_CWS 1'b0 // Write-through strategy `else `define OR1200_DCCFGR_CWS 1'b1 // Write-back strategy `endif `define OR1200_DCCFGR_CCRI 1'b1 // Cache control reg impl. `define OR1200_DCCFGR_CBIRI 1'b1 // Cache block inv reg impl. `define OR1200_DCCFGR_CBPRI 1'b0 // Cache block prefetch reg not impl. `define OR1200_DCCFGR_CBLRI 1'b0 // Cache block lock reg not impl. `define OR1200_DCCFGR_CBFRI 1'b1 // Cache block flush reg impl. `ifdef OR1200_DC_WRITETHROUGH `define OR1200_DCCFGR_CBWBRI 1'b0 // Cache block WB reg not impl. `else `define OR1200_DCCFGR_CBWBRI 1'b1 // Cache block WB reg impl. `endif `define OR1200_DCCFGR_RES1 17'h00000 `endif // ICCFGR fields `define OR1200_ICCFGR_NCW_BITS 2:0 `define OR1200_ICCFGR_NCS_BITS 6:3 `define OR1200_ICCFGR_CBS_BITS 7 `define OR1200_ICCFGR_CWS_BITS 8 `define OR1200_ICCFGR_CCRI_BITS 9 `define OR1200_ICCFGR_CBIRI_BITS 10 `define OR1200_ICCFGR_CBPRI_BITS 11 `define OR1200_ICCFGR_CBLRI_BITS 12 `define OR1200_ICCFGR_CBFRI_BITS 13 `define OR1200_ICCFGR_CBWBRI_BITS 14 `define OR1200_ICCFGR_RES1_BITS 31:15 // ICCFGR values `ifdef OR1200_NO_IC `define OR1200_ICCFGR_NCW 3'h0 // Irrelevant `define OR1200_ICCFGR_NCS 4'h0 // Irrelevant `define OR1200_ICCFGR_CBS 1'b0 // Irrelevant `define OR1200_ICCFGR_CWS 1'b0 // Irrelevant `define OR1200_ICCFGR_CCRI 1'b0 // Irrelevant `define OR1200_ICCFGR_CBIRI 1'b0 // Irrelevant `define OR1200_ICCFGR_CBPRI 1'b0 // Irrelevant `define OR1200_ICCFGR_CBLRI 1'b0 // Irrelevant `define OR1200_ICCFGR_CBFRI 1'b0 // Irrelevant `define OR1200_ICCFGR_CBWBRI 1'b0 // Irrelevant `define OR1200_ICCFGR_RES1 17'h00000 `else `define OR1200_ICCFGR_NCW 3'h0 // 1 cache way `define OR1200_ICCFGR_NCS (`OR1200_ICTAG) // Num cache sets `define OR1200_ICCFGR_CBS `OR1200_ICLS==4 ? 1'b0: 1'b1 // 16 byte cache block `define OR1200_ICCFGR_CWS 1'b0 // Irrelevant `define OR1200_ICCFGR_CCRI 1'b1 // Cache control reg impl. `define OR1200_ICCFGR_CBIRI 1'b1 // Cache block inv reg impl. `define OR1200_ICCFGR_CBPRI 1'b0 // Cache block prefetch reg not impl. `define OR1200_ICCFGR_CBLRI 1'b0 // Cache block lock reg not impl. `define OR1200_ICCFGR_CBFRI 1'b1 // Cache block flush reg impl. `define OR1200_ICCFGR_CBWBRI 1'b0 // Irrelevant `define OR1200_ICCFGR_RES1 17'h00000 `endif // DCFGR fields `define OR1200_DCFGR_NDP_BITS 3:0 `define OR1200_DCFGR_WPCI_BITS 4 `define OR1200_DCFGR_RES1_BITS 31:5 // DCFGR values `ifdef OR1200_DU_HWBKPTS `define OR1200_DCFGR_NDP 4'h`OR1200_DU_DVRDCR_PAIRS // # of DVR/DCR pairs `ifdef OR1200_DU_DWCR0 `define OR1200_DCFGR_WPCI 1'b1 `else `define OR1200_DCFGR_WPCI 1'b0 // WP counters not impl. `endif `else `define OR1200_DCFGR_NDP 4'h0 // Zero DVR/DCR pairs `define OR1200_DCFGR_WPCI 1'b0 // WP counters not impl. `endif `define OR1200_DCFGR_RES1 27'd0 /////////////////////////////////////////////////////////////////////////////// // Boot Address Selection // // This only changes where the initial reset occurs. EPH setting is still // // used to determine where vectors are located. // /////////////////////////////////////////////////////////////////////////////// // Boot from 0xf0000100 `define OR1200_BOOT_PCREG_DEFAULT 30'h3c00003f `define OR1200_BOOT_ADR 32'hf0000100 // Boot from 0x100 // `define OR1200_BOOT_PCREG_DEFAULT 30'h0000003f // `define OR1200_BOOT_ADR 32'h00000100
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