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//--------------------------------------------------------------------------- // RISC 16F84 "clk2x" core // // This file is part of the "risc_16F84" project. // http://www.opencores.org/cores/risc_16F84 // // // Description: See description below (which suffices for IP core // specification document.) // // Copyright (C) 1999 Sumio Morioka (original VHDL design version) // Copyright (C) 2001 John Clayton and OPENCORES.ORG (this Verilog version) // // NOTE: This source code is free for educational/hobby use only. It cannot // be used for commercial purposes without the consent of Microchip // Technology incorporated. // // 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 // //--------------------------------------------------------------------------- // // Author: John Clayton // Date : January 29, 2002 // // (NOTE: Date formatted as day/month/year.) // Update: 29/01/02 copied this file from memory_sizer.v (pared down). // Translated the module and signal declarations. // Transformed the instruction wires to lowercase. // Transformed the addressing wires to lowercase. // Update: 31/01/02 Translated the instruction decoder. // Update: 5/02/02 Determined that stack is simply a circular buffer of // 8 locations, 13 bits per location. Started translating // "main_efsm" process. Added all code from piccore.vhd // into this file for eventual translation. Concluded that // "stack_full_node" is not needed. // Update: 6/02/02 Translated the "ram_i_node" if/else precedural assignment. // Update: 7/02/02 Changed all := to <=, changed all '0' to 0 and '1' to 1. // Replaced all " downto " with ":". // Finished translating QRESET state. // Update: 20/02/02 Replaced all instances of Qreset with QRESET_PP. Also // replaced other state designations with their new names. // Finished translating Q1, Q2 states. // Update: 22/02/02 Translated section 2-4-1-1 (aluout register) // Update: 27/02/02 Replaced all "or" with "||" in if statements // Replaced all "and" with "&&" in if statements. // Replaced all "not" with "~" in if statements. // Finished translating Q3,Q4 states. // Translated output signal assignments at end of code. // Translated interrupt trigger processes. // Update: 28/02/02 Finished translation of WDT and TMR0 prescaler. // Trimmed line length to 80 characters throughout. // Prepared to attempt initial syntax checking. // Cleaned up some naming conventions, and verified that // all I/O pins have _i or _o appended in the body of the // code. // Update: 03/04/02 Changed "progdata_i" to "prog_dat_i" Also changed // "progadr_o" to "prog_adr_o" // Update: 04/04/02 Created new file "risc16f84_lite.v" This file is reduced // and simplified from the original "risc16f84.v" file. // Specifically, I am removing EEPROM support, and // consolidating porta and portb I/O pins so that they // are bidirectional. // Update: 04/04/02 Created a new file "risc16f84_small.v" This file is // further reduced and simplified from "risc16f84_lite.v" // Specifically, I am removing the prescaler, TMR0 and WDT. // Also, I am removing support for portb interrupts, leaving // only rb0/int as an interrupt source. This pin will be // the only way to wake up from the SLEEP instruction... // Obviously, the CLEARWDT instruction will no longer do // anything. // Update: 05/04/02 Removed the "powerdown_o", "startclk_o" and "clk_o" pins // from the small design. Also removed "rbpu_o", so if you // want pullups, you have to add them explicitly in the // constraints file, and option_reg[7] doesn't control them. // Update: 08/04/02 Decided to modify "risc16f84_small.v" in order to try for // more performance (only 2 states per instruction!) // The new file is called "risc16f84_clk2x.v" The resulting // code was synthesized, but not tested yet. // Update: 11/04/02 Decided to remove porta and portb from this unit, and add // instead an auxiliary bus, which is intended to allow I/O // using an indirect approach, similar to using the FSR. // However, the aux_adr_o is 16 bits wide, so that larger // RAM may be accessed indirectly by the processor... The use // of FSR for this purpose proved undesirable, since any new // page of RAM contains "holes" to accomodate the registers // in the first 12 locations (including FSR!) so that large // contiguous blocks of memory could not be accessed in an // effective way. This auxiliary bus solves that problem. // Since this processor is implemented inside of an FPGA, // and it is not a goal to maintain compatibility with // existing libraries of code, there is no need to maintain // porta and portb in the hardware. // The aux_adr_lo and aux_adr_hi registers are located at // 88h and 89h, and the aux_dat_io location is decoded at // 08h. // Also, changed to using "ram_we_o" instead of "readram_o" // and "writeram_o" // Update: 16/04/02 Added clock enable signal, for processor single stepping. // "aux_dat_io" is only driven when "clk_en_i" is high... // Update: 17/04/02 Removed "reset_condition" and moved "inc_pc_node" out of // the clocking area, making it non-registered. In fact, I // moved everything other than the state machine out of the // clocked logic section. Changed "aluout_reg" to "aluout" // since it is no longer registered. // Update: 26/04/02 Fixed bug in aluout logic. The AND and OR functions were // coded with logical AND/OR instead of bitwise AND/OR! // Update: 26/04/02 Changed location of aux_adr_lo and aux_adr_hi registers // to 05h and 06h, respectively. This was done to save // code space because when using the aux data bus, no bank // switching is necessary since they will now reside in the // same bank. // Update: 01/05/02 Fixed another bug -- the rrf and rlf instructions were // coded incorrectly. // Update: 03/05/02 Fixed another bug -- the carry bit was incorrect (the // problem was discovered while performing SUBWF X,W where // W contained 0 and X contained 1. (1-0). The logic for // the carry bit appears to have been incorrect even in // the original VHDL code by Sumio Morioka. // Update: 11/18/02 Fixed bug in PCL addressing mode (near line 791) // Removed parameters associated with WDT. // Update: 11/25/02 Re-wrote much of the main FSM. Attempted to generate logic // to recognize the falling edge of an interrupt, and was // unsuccessful (not simulation, actual hardware tests.) // Realized that falling edge interrupt can be equivalent to // rising edge interrupt with a NOT gate on the signal. Since // NOTs are practically free inside of an FPGA, decided to // abandon the negative edge aspect of recognizing interrupts. // Therefore, removed the "option_reg" since it is no longer // needed in this design. // Update: 08/08/03 Fixed a mathematical error, which was introduced by the bug // fix of 03/05/02. The fix of 03/05/02 correctly generated the // C bit for subtraction of zero, but unfortunately it introduced // an error such that all subtraction results were off by 1. // Obviously, this was unacceptable, and I think it has been fixed // by the new signals "c_subtract_zero" and "c_dig_subtract_zero" // // Update: 23 june 2014 (Stanislav Corboot) // // - Bug fixed: interrupt handler executed one and the same // instruction twice - before interruption and after it. // - Bug fixed: incorrect behavior of the zero flag after LITERAL //   instructions (xxxLW) if operand was equal 0x03 and if result //   equal zero. // Example: // movlw 0x03 // xorlw 0x03 -> WREG=0x00, ZF=0 - ERROR! // or // movlw 0xFD // addlw 0x03 -> WREG=0x00, ZF=0 - ERROR! // or // movlw 0x00 // andlw 0x03 -> WREG=0x00, ZF=0 - ERROR! // etc. // // Description //--------------------------------------------------------------------------- // This logic module implements a small RISC microcontroller, with functions // and instruction set very similar to those of the Microchip 16F84 chip. // This work is a translation (from VHDL to Verilog) of the "CQPIC" design // published in 1999 by Sumio Morioka of Japan, and published in the December // 1999 issue of "Transistor Gijutsu Magazine." The translation was performed // by John Clayton, without the use of any translation tools. // // Original version used as basis for translation: CQPIC version 1.00b // (December 10, 2000) // // Further revisions and re-writing have been completed on this code by John // Clayton. The interrupt mechanism has been completely re-done, and the // way in which the program counter is generated is expressed in a new way. // // In the comments, a "cycle" is defined as a processor cycle of 2 states. // Thus, passing through states Q2_PP and Q4_PP completes one cycle. // The numbers "1-3" and so forth are left from the comments in the original // source code used as the basis of the translation. //--------------------------------------------------------------------------- `define STATEBIT_SIZE 2 // Size of state machine register (bits) module risc16f84_clk2x ( prog_dat_i, // [13:0] ROM read data prog_adr_o, // [12:0] ROM address ram_dat_i, // [7:0] RAM read data ram_dat_o, // [7:0] RAM write data ram_adr_o, // [8:0] RAM address; ram_adr[8:7] indicates RAM-BANK ram_we_o, // RAM write strobe (H active) aux_adr_o, // [15:0] Auxiliary address bus aux_dat_io, // [7:0] Auxiliary data bus (tri-state bidirectional) aux_we_o, // Auxiliary write strobe (H active) int0_i, // PORT-B(0) INT reset_i, // Power-on reset (H active) clk_en_i, // Clock enable for all clocked logic clk_i // Clock input ); // You can change the following parameters as you would like parameter STACK_SIZE_PP = 8; // Size of PC stack parameter LOG2_STACK_SIZE_PP = 3; // Log_2(stack_size) // State definitions for state machine, provided as parameters to allow // for redefinition of state values by the instantiator if desired. parameter Q2_PP = 2'b00; // state Q2 parameter Q4_PP = 2'b01; // state Q4 parameter QINT_PP = 2'b10; // interrupt state (substitute for Q4) parameter QSLEEP_PP = 2'b11; // sleep state // I/O declarations // program ROM data bus/address bus input [13:0] prog_dat_i; // ROM read data output [12:0] prog_adr_o; // ROM address // data RAM data bus/address bus/control signals input [7:0] ram_dat_i; // RAM read data output [7:0] ram_dat_o; // RAM write data output [8:0] ram_adr_o; // RAM address; ram_adr[8:7] indicates RAM-BANK output ram_we_o; // RAM write strobe (H active) // auxiliary data bus/address bus/control signals output [15:0] aux_adr_o; // AUX address bus inout [7:0] aux_dat_io; // AUX data bus output aux_we_o; // AUX write strobe (H active) // interrupt input input int0_i; // INT // CPU reset input reset_i; // Power-on reset (H active) // CPU clock input clk_en_i; // Clock enable input input clk_i; // Clock input // Internal signal declarations // User registers reg [7:0] w_reg; // W reg [12:0] pc_reg; // PCH/PCL -- Address currently being fetched reg [12:0] old_pc_reg; // Address fetched previous to this one. reg [7:0] status_reg; // STATUS reg [7:0] fsr_reg; // FSR reg [4:0] pclath_reg; // PCLATH reg [7:0] intcon_reg; // INTCON reg [7:0] aux_adr_hi_reg; // AUX address high byte reg [7:0] aux_adr_lo_reg; // AUX address low byte // Internal registers for controlling instruction execution reg [13:0] inst_reg; // Holds fetched op-code/operand reg [7:0] aluinp1_reg; // data source (1 of 2) reg [7:0] aluinp2_reg; // data source (2 of 2) reg exec_stall_reg; // if H (i.e. after GOTO etc), stall execution. // Stack // stack (array of data-registers) reg [12:0] stack_reg [STACK_SIZE_PP-1:0]; // stack pointer reg [LOG2_STACK_SIZE_PP-1:0] stack_pnt_reg; wire [12:0] stack_top; // More compatible with sensitivity list than // "stack_reg[stack_pnt_reg]" // Interrupt registers/nodes wire int_condition; // Indicates that an interrupt should be recognized wire intrise; // High indicates edge was detected reg intrise_reg; // detect positive edge of PORT-B inputs // Synchronizer for interrupt reg inte_sync_reg; // State register reg [`STATEBIT_SIZE-1:0] state_reg; reg [`STATEBIT_SIZE-1:0] next_state_node; // Result of decoding instruction -- only 1 is active at a time wire inst_addlw; wire inst_addwf; wire inst_andlw; wire inst_andwf; wire inst_bcf; wire inst_bsf; wire inst_btfsc; wire inst_btfss; wire inst_call; wire inst_clrf; wire inst_clrw; wire inst_comf; wire inst_decf; wire inst_decfsz; wire inst_goto; wire inst_incf; wire inst_incfsz; wire inst_iorlw; wire inst_iorwf; wire inst_movlw; wire inst_movf; wire inst_movwf; wire inst_retfie; wire inst_retlw; wire inst_ret; wire inst_rlf; wire inst_rrf; wire inst_sleep; wire inst_sublw; wire inst_subwf; wire inst_swapf; wire inst_xorlw; wire inst_xorwf; // Result of calculating RAM access address wire [8:0] ram_adr_node; // RAM access address // These wires indicate accesses to special registers... // Only 1 is active at a time. wire addr_pcl; wire addr_stat; wire addr_fsr; wire addr_pclath; wire addr_intcon; wire addr_aux_adr_lo; wire addr_aux_adr_hi; wire addr_aux_dat; wire addr_sram; // Other output registers (for removing hazards) reg ram_we_reg; // data-sram write strobe reg aux_we_reg; // AUX write strobe // Signals used in "main_efsm" procedure // (Intermediate nodes used for resource sharing.) wire [7:0] ram_i_node; // result of reading RAM/Special registers wire [7:0] mask_node; // bit mask for logical operations wire [8:0] add_node; // result of 8bit addition wire [4:0] addlow_node; // result of low-4bit addition wire aluout_zero_node; // H if ALUOUT = 0 reg [12:0] next_pc_node; // value of next PC reg [7:0] aluout; // result of calculation reg writew_node; // H if destination is W register reg writeram_node; // H if destination is RAM/Special registers reg c_subtract_zero; // High for special case of C bit, when subtracting zero reg c_dig_subtract_zero; // High for special case of C bit, when subtracting zero wire next_exec_stall; //-------------------------------------------------------------------------- // Instantiations //-------------------------------------------------------------------------- //-------------------------------------------------------------------------- // Functions & Tasks //-------------------------------------------------------------------------- //-------------------------------------------------------------------------- // Module code //-------------------------------------------------------------------------- // This represents the instruction fetch from program memory. // inst_reg[13:0] stores the instruction. This happens at the end of Q4. // So the memory access time is one processor cycle (2 clocks!) minus // the setup-time of this register, and minus the delay to drive the // address out onto the prog_adr_o bus. always @(posedge clk_i) begin if (reset_i) inst_reg <= 0; else if (clk_en_i && (state_reg == Q4_PP)) inst_reg <= prog_dat_i; end // NOTE: There is an extra "15th" bit of inst_reg, which represents an // interrupt execution cycle. This is included in inst_reg so that when // an interrupt instruction is executing, it effectively "pre-empts" the // other instructions. // The fifteenth bit, inst_reg[14], is set by the interrupt logic. // Decode OPcode (see pp.54 of PIC16F84 data sheet) // only 1 signal of the following signals will be '1' assign inst_call = (inst_reg[13:11] == 3'b100 ); assign inst_goto = (inst_reg[13:11] == 3'b101 ); assign inst_bcf = (inst_reg[13:10] == 4'b0100 ); assign inst_bsf = (inst_reg[13:10] == 4'b0101 ); assign inst_btfsc = (inst_reg[13:10] == 4'b0110 ); assign inst_btfss = (inst_reg[13:10] == 4'b0111 ); assign inst_movlw = (inst_reg[13:10] == 4'b1100 ); assign inst_retlw = (inst_reg[13:10] == 4'b1101 ); assign inst_sublw = (inst_reg[13:9] == 5'b11110 ); assign inst_addlw = (inst_reg[13:9] == 5'b11111 ); assign inst_iorlw = (inst_reg[13:8] == 6'b111000 ); assign inst_andlw = (inst_reg[13:8] == 6'b111001 ); assign inst_xorlw = (inst_reg[13:8] == 6'b111010 ); assign inst_subwf = (inst_reg[13:8] == 6'b000010 ); assign inst_decf = (inst_reg[13:8] == 6'b000011 ); assign inst_iorwf = (inst_reg[13:8] == 6'b000100 ); assign inst_andwf = (inst_reg[13:8] == 6'b000101 ); assign inst_xorwf = (inst_reg[13:8] == 6'b000110 ); assign inst_addwf = (inst_reg[13:8] == 6'b000111 ); assign inst_movf = (inst_reg[13:8] == 6'b001000 ); assign inst_comf = (inst_reg[13:8] == 6'b001001 ); assign inst_incf = (inst_reg[13:8] == 6'b001010 ); assign inst_decfsz = (inst_reg[13:8] == 6'b001011 ); assign inst_rrf = (inst_reg[13:8] == 6'b001100 ); assign inst_rlf = (inst_reg[13:8] == 6'b001101 ); assign inst_swapf = (inst_reg[13:8] == 6'b001110 ); assign inst_incfsz = (inst_reg[13:8] == 6'b001111 ); assign inst_movwf = (inst_reg[13:7] == 7'b0000001 ); assign inst_clrw = (inst_reg[13:7] == 7'b0000010 ); assign inst_clrf = (inst_reg[13:7] == 7'b0000011 ); assign inst_ret = (inst_reg[13:0] == 14'b00000000001000); assign inst_retfie = (inst_reg[13:0] == 14'b00000000001001); assign inst_sleep = (inst_reg[13:0] == 14'b00000001100011); // Calculate RAM access address (see pp.19 of PIC16F84 data sheet) // if "d"=0, indirect addressing is used, so RAM address is BANK+FSR // otherwise, RAM address is BANK+"d" // (see pp.19 of PIC16F84 data sheet) assign ram_adr_node = (inst_reg[6:0]==0)?{status_reg[7],fsr_reg[7:0]}: {status_reg[6:5],inst_reg[6:0]}; // check if this is an access to external RAM or not assign addr_sram = (ram_adr_node[6:0] > 7'b0001011); //0CH-7FH,8CH-FFH // check if this is an access to special register or not // only 1 signal of the following signals will be '1' assign addr_pcl = (ram_adr_node[6:0] == 7'b0000010); // 02H, 82H assign addr_stat = (ram_adr_node[6:0] == 7'b0000011); // 03H, 83H assign addr_fsr = (ram_adr_node[6:0] == 7'b0000100); // 04H, 84H assign addr_aux_dat = (ram_adr_node[7:0] == 8'b00001000); // 08H assign addr_pclath = (ram_adr_node[6:0] == 7'b0001010); // 0AH, 8AH assign addr_intcon = (ram_adr_node[6:0] == 7'b0001011); // 0BH, 8BH assign addr_aux_adr_lo = (ram_adr_node[7:0] == 8'b00000101); // 05H assign addr_aux_adr_hi = (ram_adr_node[7:0] == 8'b00000110); // 06H // construct bit-mask for logical operations and bit tests assign mask_node = 1 << inst_reg[9:7]; // Create the exec_stall signal, based on the contents of the currently // executing instruction (inst_reg). next_exec_stall reflects the state // to assign to exec_stall following the conclusion of the next Q4 state. // All of these instructions cause an execution stall in the next cycle // because they modify the program counter, and a new value is presented // for fetching during the stall cycle, during which time no instruction // should be executed. // // The conditional instructions are given along with their conditions for // execution. If the conditions are not met, there is no stall and nothing // to execute. assign next_exec_stall = ( inst_goto || inst_call || inst_ret || inst_retlw || inst_retfie || ( (inst_btfsc || inst_decfsz || inst_incfsz) && aluout_zero_node ) || (inst_btfss && ~aluout_zero_node) || (addr_pcl && writeram_node) ); always @(posedge clk_i) begin if (reset_i) exec_stall_reg <= 0; else if (clk_en_i && (state_reg == QINT_PP)) exec_stall_reg <= 1; else if (clk_en_i && (state_reg == Q4_PP)) exec_stall_reg <= (next_exec_stall && ~exec_stall_reg); // exec stall should never be generated during a stall cycle, because // a stall cycle doesn't execute anything... end assign stack_top = stack_reg[stack_pnt_reg]; // Formulate the next pc_reg value (the program counter.) // During stall cycles, the pc is simply incremented... always @( pc_reg or pclath_reg or aluout or stack_pnt_reg or stack_top or inst_ret or inst_retlw or inst_retfie or inst_goto or inst_call or inst_reg or writeram_node or addr_pcl or exec_stall_reg ) begin if (~exec_stall_reg &&(inst_ret || inst_retlw || inst_retfie)) next_pc_node <= stack_top; else if (~exec_stall_reg &&(inst_goto || inst_call)) next_pc_node <= {pclath_reg[4:3],inst_reg[10:0]}; else if (~exec_stall_reg && (writeram_node && addr_pcl)) // PCL is data-destination, but update the entire PC. next_pc_node <= {pclath_reg[4:0],aluout}; else next_pc_node <= pc_reg + 1; end // Set the program counter // If the sleep instruction is executing, then the PC is not allowed to be // updated, since the processor will "freeze" and the instruction being fetched // during the sleep instruction must be executed upon wakeup interrupt. // Obviously, if the PC were to change at the end of the sleep instruction, then // a different (incorrect) address would be fetched during the sleep time. always @(posedge clk_i) begin if (reset_i) begin pc_reg <= 0; old_pc_reg <= 0; end else if (clk_en_i && (state_reg == QINT_PP)) begin old_pc_reg <= pc_reg; pc_reg <= 4; end else if (clk_en_i && ~inst_sleep && (state_reg == Q4_PP)) begin old_pc_reg <= pc_reg; pc_reg <= next_pc_node; end end // 1. Intermediate nodes for resource sharing // Tri-state drivers instead of a huge selector... It produces smaller // results, and runs faster. assign ram_i_node = (addr_sram) ?ram_dat_i:8'bZ; assign ram_i_node = (addr_pcl) ?pc_reg[7:0]:8'bZ; assign ram_i_node = (addr_stat) ?status_reg:8'bZ; assign ram_i_node = (addr_fsr) ?fsr_reg:8'bZ; assign ram_i_node = (addr_aux_dat) ?aux_dat_io:8'bZ; assign ram_i_node = (addr_pclath) ?{3'b0,pclath_reg}:8'bZ; assign ram_i_node = (addr_intcon) ?intcon_reg:8'bZ; assign ram_i_node = (addr_aux_adr_lo) ?aux_adr_lo_reg:8'bZ; assign ram_i_node = (addr_aux_adr_hi) ?aux_adr_hi_reg:8'bZ; // 1-3. Adder (ALU) // full 8bit-addition, with carry in/out. // Note that "temp" and "dtemp" are intended to be thrown away. // Also, addlow_node[3:0] are thrown away. // Even though they are assigned, they should never be used. assign add_node = {1'b0,aluinp1_reg} + {1'b0,aluinp2_reg}; // lower 4bit-addition assign addlow_node = {1'b0,aluinp1_reg[3:0]} + {1'b0,aluinp2_reg[3:0]}; // 1-4. Test if aluout = 0 assign aluout_zero_node = (aluout == 0)?1:0; // 1-5. Determine destination always @( inst_reg or inst_movwf or inst_bcf or inst_bsf or inst_clrf or inst_movlw or inst_addlw or inst_sublw or inst_andlw or inst_iorlw or inst_xorlw or inst_retlw or inst_clrw or inst_movf or inst_swapf or inst_addwf or inst_subwf or inst_andwf or inst_iorwf or inst_xorwf or inst_decf or inst_incf or inst_rlf or inst_rrf or inst_decfsz or inst_incfsz or inst_comf ) begin if (inst_movwf || inst_bcf || inst_bsf || inst_clrf) begin writew_node <= 0; writeram_node <= 1; end else if ( inst_movlw || inst_addlw || inst_sublw || inst_andlw || inst_iorlw || inst_xorlw || inst_retlw || inst_clrw) begin writew_node <= 1; writeram_node <= 0; end else if ( inst_movf || inst_swapf || inst_addwf || inst_subwf || inst_andwf || inst_iorwf || inst_xorwf || inst_decf || inst_incf || inst_rlf || inst_rrf || inst_decfsz || inst_incfsz || inst_comf) begin writew_node <= ~inst_reg[7]; // ("d" field of fetched instruction) writeram_node <= inst_reg[7]; // ("d" field of fetched instruction) end else begin writew_node <= 0; writeram_node <= 0; end end // End of determine destination logic // 2-4-1. Calculation and store result into alu-output register always @( add_node or aluinp1_reg or aluinp2_reg or status_reg or inst_reg or inst_movwf or inst_bcf or inst_bsf or inst_btfsc or inst_btfss or inst_clrf or inst_addlw or inst_sublw or inst_andlw or inst_iorlw or inst_xorlw or inst_retlw or inst_clrw or inst_swapf or inst_addwf or inst_subwf or inst_andwf or inst_iorwf or inst_xorwf or inst_decf or inst_incf or inst_rlf or inst_rrf or inst_decfsz or inst_incfsz or inst_comf ) begin // 2-4-1-1. Set aluout register // Rotate left if (inst_rlf) aluout <= {aluinp1_reg[6:0],status_reg[0]}; // Rotate right else if (inst_rrf) aluout <= {status_reg[0],aluinp1_reg[7:1]}; // Swap nibbles else if (inst_swapf) aluout <= {aluinp1_reg[3:0],aluinp1_reg[7:4]}; // Logical inversion else if (inst_comf) aluout <= ~aluinp1_reg; // Logical AND, bit clear/bit test else if ( inst_andlw || inst_andwf || inst_bcf || inst_btfsc || inst_btfss) aluout <= (aluinp1_reg & aluinp2_reg); // Logical OR, bit set else if (inst_bsf || inst_iorlw || inst_iorwf) aluout <= (aluinp1_reg | aluinp2_reg); // Logical XOR else if (inst_xorlw || inst_xorwf) aluout <= (aluinp1_reg ^ aluinp2_reg); // Addition, Subtraction, Increment, Decrement else if ( inst_addlw || inst_addwf || inst_sublw || inst_subwf || inst_decf || inst_decfsz || inst_incf || inst_incfsz) aluout <= add_node[7:0]; // Pass through else aluout <= aluinp1_reg; end // MAIN EFSM: description of register value changes in each clock cycle always @(posedge clk_i) begin // Assign reset (default) values of registers if (reset_i) begin status_reg[7:5] <= 3'b0; pclath_reg <= 0; // 0 intcon_reg[7:1] <= 7'b0; aux_adr_lo_reg <= 0; aux_adr_hi_reg <= 0; ram_we_reg <= 0; status_reg[4] <= 1; // /T0 = 1 status_reg[3] <= 1; // /PD = 1 stack_pnt_reg <= 0; // Reset stack pointer end // End of reset assignments else if (~exec_stall_reg && clk_en_i) begin // Execution ceases during a stall cycle. if (state_reg == Q2_PP) // 2-3. Q2 cycle begin if( ~int_condition ) // Bug fixed begin // 2-3-1. Read data-RAM and store values to alu-input regs // 2-3-1-1. Set aluinp1 register (source #1) if ( inst_movf || inst_swapf || inst_addwf || inst_subwf || inst_andwf || inst_iorwf || inst_xorwf || inst_decf || inst_incf || inst_rlf || inst_rrf || inst_bcf || inst_bsf || inst_btfsc || inst_btfss || inst_decfsz || inst_incfsz || inst_comf) aluinp1_reg <= ram_i_node; // RAM/Special registers else if ( inst_movlw || inst_addlw || inst_sublw || inst_andlw || inst_iorlw || inst_xorlw || inst_retlw) aluinp1_reg <= inst_reg[7:0]; // Immediate value ("k") else if ( inst_clrf || inst_clrw) aluinp1_reg <= 0; // 0 else aluinp1_reg <= w_reg; // W register // 2-3-1-2. Set aluinp2 register (source #2) c_subtract_zero <= 0; // default to non-special case c_dig_subtract_zero <= 0; // default to non-special case if (inst_decf || inst_decfsz) aluinp2_reg <= -1; // for decr. else if (inst_incf || inst_incfsz) aluinp2_reg <= 1; // for incr. // -1 * W register (for subtract) else if (inst_sublw || inst_subwf) begin aluinp2_reg <= ~w_reg + 1; c_subtract_zero <= (w_reg == 0); // Indicate special case c_dig_subtract_zero <= (w_reg[3:0] == 0); // Indicate special case end // operation of BCF: AND with inverted mask ("1..101..1") // mask for BCF: value of only one position is 0 else if (inst_bcf) aluinp2_reg <= ~mask_node; // operation of BSF: OR with mask_node ("0..010..0") // operation of FSC and FSS: AND with mask_node, compare to 0 else if (inst_btfsc || inst_btfss || inst_bsf) aluinp2_reg <= mask_node; else aluinp2_reg <= w_reg; // W register // 2-3-1-3. Set stack pointer register (pop stack) if (inst_ret || inst_retlw || inst_retfie) stack_pnt_reg <= stack_pnt_reg - 1; // cycles 3,2,1,0,7,6... // 2-4-1-3. Set data-SRAM write enable (hazard-free) // Set the write enables depending on the destination. // (These have been implemented as registers to avoid glitches? // It is not known to me (John Clayton) whether any glitches would // really occur. It might be possible to generate these signals // using combinational logic only, without using registers! ram_we_reg <= (writeram_node && addr_sram); aux_we_reg <= (writeram_node && addr_aux_dat); end // Bug fixed end // End of Q2 state //--------------------------------------------------------------------- else if (state_reg == QINT_PP) // Interrupt execution (instead of Q4_PP) begin // PORT-B0 INT intcon_reg[1] <= 1; // set INTF intcon_reg[7] <= 0; // clear GIE stack_reg[stack_pnt_reg] <= old_pc_reg; // Push old PC stack_pnt_reg <= stack_pnt_reg + 1; // increment stack pointer // The old PC is pushed, so that the pre-empted instruction can be // restarted later, when the retfie is executed. end //--------------------------------------------------------------------- else if (state_reg == Q4_PP) // Execution & writing of results. begin if (inst_call) begin stack_reg[stack_pnt_reg] <= pc_reg; // Push current PC stack_pnt_reg <= stack_pnt_reg + 1; // increment stack pointer end if (inst_retfie) // "return from interrupt" instruction begin intcon_reg[7] <= 1; // Set GIE end // 2-4-1-2. Set C flag and DC flag if (inst_addlw || inst_addwf || inst_sublw || inst_subwf) begin // c_dig_subtract_zero and c_subtract_zero are used to take care of the // special case when subtracting zero, where the carry bit should be 1 // (meaning no borrow). It is explicitly set by these signals during // that condition. See 16F84 datasheet, page 8 for further information // about the C bit. status_reg[1] <= addlow_node[4] || c_dig_subtract_zero; // DC flag status_reg[0] <= add_node[8] || c_subtract_zero; // C flag end else if (inst_rlf) status_reg[0] <= aluinp1_reg[7]; // C flag else if (inst_rrf) status_reg[0] <= aluinp1_reg[0]; // C flag // 2-5-2. Store calculation result into destination, // 2-5-2-1. Set W register if (writew_node) w_reg <= aluout; // write W reg // 2-5-2-2. Set data RAM/special registers, if (writeram_node) begin if (addr_stat) begin status_reg[7:5] <= aluout[7:5]; // write IRP,RP1,RP0 // status(4),status(3)...unwritable, see below (/PD,/T0 part) status_reg[1:0] <= aluout[1:0]; // write DC,C end if (addr_fsr) fsr_reg <= aluout; // write FSR if (addr_pclath) pclath_reg <= aluout[4:0]; // write PCLATH if (addr_intcon) intcon_reg <= aluout; // write INTCON if (addr_aux_adr_lo) aux_adr_lo_reg <= aluout; // write AUX low if (addr_aux_adr_hi) aux_adr_hi_reg <= aluout; // write AUX high end // 2-5-2-3. Set/clear Z flag. if (addr_stat && !writew_node) status_reg[2] <= aluout[2]; // (dest. is Z flag) // Bug fixed else if ( inst_addlw || inst_addwf || inst_andlw || inst_andwf || inst_clrf || inst_clrw || inst_comf || inst_decf || inst_incf || inst_movf || inst_sublw || inst_subwf || inst_xorlw || inst_xorwf || inst_iorlw || inst_iorwf ) status_reg[2] <= aluout_zero_node; // Z=1 if result == 0 // 2-5-3. Clear RAM write enables (hazard-free) ram_we_reg <= 0; aux_we_reg <= 0; end // End of Q4 state end // End of "if (~exec_stall_reg)" end // End of process // Calculation of next processor state. // (Not including reset conditions, which are covered by the clocked logic, // which also includes a "global clock enable." always @( state_reg or inst_sleep or inte_sync_reg or exec_stall_reg or int_condition ) begin case (state_reg) Q2_PP : if (int_condition) next_state_node <= QINT_PP; else next_state_node <= Q4_PP; Q4_PP : if (~exec_stall_reg && inst_sleep) next_state_node <= QSLEEP_PP; else next_state_node <= Q2_PP; QINT_PP : next_state_node <= Q2_PP; QSLEEP_PP : if (inte_sync_reg) next_state_node <= Q2_PP; else next_state_node <= QSLEEP_PP; // Default condition provided for convention and completeness // only. Logically, all of the conditions are already covered. default : next_state_node <= Q2_PP; endcase end // Clocked state transitions, based upon dataflow (non-clocked logic) in // the previous always block. always @(posedge clk_i) begin if (reset_i) state_reg <= Q2_PP; else if (clk_en_i) state_reg <= next_state_node; end // End of process // Detect external interrupt requests // You can code multiple interrupts if you wish, or use the single interrupt // provided and simply have the interrupt service routine (ISR) check to find // out the source of the interrupt, by or-ing together all of the interrupt // sources and providing a readable register of their values at the time // the interrupt occurred. // // When an interrupt is recognized by the processor, this is signified by // entering "QINT_PP," which is treated like an executable instruction. // The interrupt instruction can only be executed when not in a stall condition. // It simply "pre-empts" the instruction that would have been executed during // that cycle. Then, when retfie is executed, the pre-empted instruction is // re-started (the stall cycle of the retfie is when the address of the // instruction being re-started is fetched.) // // I was unable to obtain correct operation for capturing the negative edge, // so I am discarding it. If one really needs to generate an interrupt on the // falling edge, just use an inverted version of the signal (the inversion is // often "free" inside of an FPGA anyhow.) // // Upon further testing, I discovered that even the rising edge "trigger" was not // really truly an edge detection, it was more like a "set-reset" flip flop // type of behavior. Rather than mess around with it any more, I am implementing // a clocked "poor man's rising edge detector." // Capture the rising edge of the interrupt input... This part is self clearing. // It also means that the interrupt must last longer than one clock cycle in // order to be properly recognized. (It is "pseudo edge triggered", not a true // rising edge trigger.) // When the interrupt is recognized, inte_sync_reg is cleared. always @(posedge clk_i) begin if (clk_en_i) intrise_reg <= int0_i; end // process assign intrise = (int0_i && ~intrise_reg); // The inte_sync_reg signal is used for waking up from SLEEP. // (this flip flop is also a synchronizer to minimize the // possibility of metastability due to changes at the input // occurring at the same time as the processor clock edge...) // It might be possible to eliminate this step, and issue the interrupt // directly without this intermediate synchronizer flip-flop. always @(posedge clk_i) begin if (reset_i || (state_reg == QINT_PP)) inte_sync_reg <= 0; else if (clk_en_i && intrise && intcon_reg[4]) inte_sync_reg <= 1; end // Issue an interrupt when the interrupt is present. // Also, do not issue an interrupt when there is a stall cycle coming! assign int_condition = (inte_sync_reg && ~exec_stall_reg && intcon_reg[7]); // Interrupt must be pending // Next processor cycle must not be a stall // GIE bit must be set to issue interrupt // Circuit's output signals assign prog_adr_o = pc_reg; // program ROM address assign ram_adr_o = ram_adr_node; // data RAM address assign ram_dat_o = aluout; // data RAM write data assign ram_we_o = ram_we_reg; // data RAM write enable assign aux_adr_o = {aux_adr_hi_reg,aux_adr_lo_reg}; assign aux_dat_io = (aux_we_reg && clk_en_i)?aluout:{8{1'bZ}}; assign aux_we_o = aux_we_reg; endmodule //`undef STATEBIT_SIZE