URL
https://opencores.org/ocsvn/openrisc/openrisc/trunk
Subversion Repositories openrisc
[/] [openrisc/] [trunk/] [orpsocv2/] [rtl/] [verilog/] [cfi_ctrl/] [cfi_ctrl_engine.v] - Rev 864
Go to most recent revision | Compare with Previous | Blame | View Log
////////////////////////////////////////////////////////////////// //// //// //// //// Common Flash Interface (CFI) controller //// //// //// //// This file is part of the cfi_ctrl project //// //// http://opencores.org/project,cfi_ctrl //// //// //// //// Description //// //// See below //// //// //// //// To Do: //// //// - //// //// //// //// Author(s): //// //// - Julius Baxter, julius@opencores.org //// //// //// ////////////////////////////////////////////////////////////////////// //// //// //// Copyright (C) 2011 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.gnu.org/copyleft/lesser.html //// //// //// ////////////////////////////////////////////////////////////////////// /* CFI controller engine. Contains main state machine and bus controls. Controlled via a simple interface to a bus controller interface. For now just implements an asynchronous controller. do_rst_i - reset the flash device do_init_i - initialise the device (write "read configuration register") do_readstatus_i - read the status of the device do_eraseblock_i - erase a block do_write_i - write a word an address do_read_i - read a word from an address bus_dat_o - data out to bus controller bus_dat_i - data in from bus controller bus_req_done_o - bus request done */ module cfi_ctrl_engine ( clk_i, rst_i, do_rst_i, do_init_i, do_readstatus_i, do_clearstatus_i, do_eraseblock_i, do_unlockblock_i, do_write_i, do_read_i, do_readdeviceident_i, do_cfiquery_i, bus_dat_o, bus_dat_i, bus_adr_i, bus_req_done_o, bus_busy_o, flash_dq_io, flash_adr_o, flash_adv_n_o, flash_ce_n_o, flash_clk_o, flash_oe_n_o, flash_rst_n_o, flash_wait_i, flash_we_n_o, flash_wp_n_o ); parameter flash_dq_width = 16; parameter flash_adr_width = 24; input clk_i, rst_i; input do_rst_i, do_init_i, do_readstatus_i, do_clearstatus_i, do_eraseblock_i, do_unlockblock_i, do_write_i, do_read_i, do_readdeviceident_i, do_cfiquery_i; output reg [flash_dq_width-1:0] bus_dat_o; input [flash_dq_width-1:0] bus_dat_i; input [flash_adr_width-1:0] bus_adr_i; output bus_req_done_o; output bus_busy_o; inout [flash_dq_width-1:0] flash_dq_io; output [flash_adr_width-1:0] flash_adr_o; output flash_adv_n_o; output flash_ce_n_o; output flash_clk_o; output flash_oe_n_o; output flash_rst_n_o; input flash_wait_i; output flash_we_n_o; output flash_wp_n_o; wire clk, rst; assign clk = clk_i; assign rst = rst_i; reg [5:0] bus_control_state; reg [flash_dq_width-1:0] flash_cmd_to_write; /* regs for flash bus control signals */ reg flash_adv_n_r; reg flash_ce_n_r; reg flash_oe_n_r; reg flash_we_n_r; reg flash_wp_n_r; reg flash_rst_n_r; reg [flash_dq_width-1:0] flash_dq_o_r; reg [flash_adr_width-1:0] flash_adr_r; reg [3:0] flash_phy_state; reg [3:0] flash_phy_ctr; wire flash_phy_async_wait; `define CFI_PHY_FSM_IDLE 0 `define CFI_PHY_FSM_WRITE_GO 1 `define CFI_PHY_FSM_WRITE_WAIT 2 `define CFI_PHY_FSM_WRITE_DONE 3 `define CFI_PHY_FSM_READ_GO 4 `define CFI_PHY_FSM_READ_WAIT 5 `define CFI_PHY_FSM_READ_DONE 6 `define CFI_PHY_FSM_RESET_GO 7 `define CFI_PHY_FSM_RESET_WAIT 8 `define CFI_PHY_FSM_RESET_DONE 9 /* Defines according to CFI spec */ `define CFI_CMD_DAT_READ_STATUS_REG 8'h70 `define CFI_CMD_DAT_CLEAR_STATUS_REG 8'h50 `define CFI_CMD_DAT_WORD_PROGRAM 8'h40 `define CFI_CMD_DAT_BLOCK_ERASE 8'h20 `define CFI_CMD_DAT_READ_ARRAY 8'hff `define CFI_CMD_DAT_WRITE_RCR 8'h60 `define CFI_CMD_DAT_CONFIRM_WRITE_RCR 8'h03 `define CFI_CMD_DAT_UNLOCKBLOCKSETUP 8'h60 `define CFI_CMD_DAT_CONFIRM_CMD 8'hd0 `define CFI_CMD_DAT_READDEVICEIDENT 8'h90 `define CFI_CMD_DAT_CFIQUERY 8'h98 /* Main bus-controlled FSM states */ `define CFI_FSM_IDLE 0 `define CFI_FSM_DO_WRITE 1 `define CFI_FSM_DO_WRITE_WAIT 2 `define CFI_FSM_DO_READ 3 `define CFI_FSM_DO_READ_WAIT 4 `define CFI_FSM_DO_BUS_ACK 5 `define CFI_FSM_DO_RESET 6 `define CFI_FSM_DO_RESET_WAIT 7 /* Used to internally track what read more we're in 2'b00 : read array mode 2'b01 : read status mode else : something else*/ reg [1:0] flash_device_read_mode; /* Track what read mode we're in */ always @(posedge clk) if (rst) flash_device_read_mode <= 2'b00; else if (!flash_rst_n_o) flash_device_read_mode <= 2'b00; else if (flash_phy_state == `CFI_PHY_FSM_WRITE_DONE) begin if (flash_cmd_to_write == `CFI_CMD_DAT_READ_ARRAY) flash_device_read_mode <= 2'b00; else if (flash_cmd_to_write == `CFI_CMD_DAT_READ_STATUS_REG) flash_device_read_mode <= 2'b01; else /* Some other mode */ flash_device_read_mode <= 2'b11; end /* Main control state machine, controlled by the bus */ always @(posedge clk) if (rst) begin /* Power up and start an asynchronous write to the "read config reg" */ bus_control_state <= `CFI_FSM_IDLE; flash_cmd_to_write <= 0; end else case (bus_control_state) `CFI_FSM_IDLE : begin if (do_readstatus_i) begin // if (flash_device_read_mode != 2'b01) begin flash_cmd_to_write <= `CFI_CMD_DAT_READ_STATUS_REG; bus_control_state <= `CFI_FSM_DO_WRITE; // end // else begin // flash_cmd_to_write <= 0; // bus_control_state <= `CFI_FSM_DO_READ; // end end if (do_clearstatus_i) begin flash_cmd_to_write <= `CFI_CMD_DAT_CLEAR_STATUS_REG; bus_control_state <= `CFI_FSM_DO_WRITE; end if (do_eraseblock_i) begin flash_cmd_to_write <= `CFI_CMD_DAT_BLOCK_ERASE; bus_control_state <= `CFI_FSM_DO_WRITE; end if (do_write_i) begin flash_cmd_to_write <= `CFI_CMD_DAT_WORD_PROGRAM; bus_control_state <= `CFI_FSM_DO_WRITE; end if (do_read_i) begin if (flash_device_read_mode != 2'b00) begin flash_cmd_to_write <= `CFI_CMD_DAT_READ_ARRAY; bus_control_state <= `CFI_FSM_DO_WRITE; end else begin flash_cmd_to_write <= 0; bus_control_state <= `CFI_FSM_DO_READ; end end if (do_unlockblock_i) begin flash_cmd_to_write <= `CFI_CMD_DAT_UNLOCKBLOCKSETUP; bus_control_state <= `CFI_FSM_DO_WRITE; end if (do_rst_i) begin flash_cmd_to_write <= 0; bus_control_state <= `CFI_FSM_DO_RESET; end if (do_readdeviceident_i) begin flash_cmd_to_write <= `CFI_CMD_DAT_READDEVICEIDENT; bus_control_state <= `CFI_FSM_DO_WRITE; end if (do_cfiquery_i) begin flash_cmd_to_write <= `CFI_CMD_DAT_CFIQUERY; bus_control_state <= `CFI_FSM_DO_WRITE; end end // case: `CFI_FSM_IDLE `CFI_FSM_DO_WRITE : begin bus_control_state <= `CFI_FSM_DO_WRITE_WAIT; end `CFI_FSM_DO_WRITE_WAIT : begin /* Wait for phy controller to finish the write command */ if (flash_phy_state==`CFI_PHY_FSM_WRITE_DONE) begin if (flash_cmd_to_write == `CFI_CMD_DAT_READ_STATUS_REG || flash_cmd_to_write == `CFI_CMD_DAT_READ_ARRAY || flash_cmd_to_write == `CFI_CMD_DAT_READDEVICEIDENT || flash_cmd_to_write == `CFI_CMD_DAT_CFIQUERY) begin /* we just changed the read mode, so go ahead and do the read */ bus_control_state <= `CFI_FSM_DO_READ; end else if (flash_cmd_to_write == `CFI_CMD_DAT_WORD_PROGRAM) begin /* Setting up to do a word write, go to write again */ /* clear the command, to use the incoming data from the bus */ flash_cmd_to_write <= 0; bus_control_state <= `CFI_FSM_DO_WRITE; end else if (flash_cmd_to_write == `CFI_CMD_DAT_BLOCK_ERASE || flash_cmd_to_write == `CFI_CMD_DAT_UNLOCKBLOCKSETUP) begin /* first stage of a two-stage command requiring confirm */ bus_control_state <= `CFI_FSM_DO_WRITE; flash_cmd_to_write <= `CFI_CMD_DAT_CONFIRM_CMD; end else /* All other operations should see us acking the bus */ bus_control_state <= `CFI_FSM_DO_BUS_ACK; end end // case: `CFI_FSM_DO_WRITE_WAIT `CFI_FSM_DO_READ : begin bus_control_state <= `CFI_FSM_DO_READ_WAIT; end `CFI_FSM_DO_READ_WAIT : begin if (flash_phy_state==`CFI_PHY_FSM_READ_DONE) begin bus_control_state <= `CFI_FSM_DO_BUS_ACK; end end `CFI_FSM_DO_BUS_ACK : bus_control_state <= `CFI_FSM_IDLE; `CFI_FSM_DO_RESET : bus_control_state <= `CFI_FSM_DO_RESET_WAIT; `CFI_FSM_DO_RESET_WAIT : begin if (flash_phy_state==`CFI_PHY_FSM_RESET_DONE) bus_control_state <= `CFI_FSM_IDLE; end default : bus_control_state <= `CFI_FSM_IDLE; endcase // case (bus_control_state) /* Tell the bus we're done */ assign bus_req_done_o = (bus_control_state==`CFI_FSM_DO_BUS_ACK); assign bus_busy_o = !(bus_control_state == `CFI_FSM_IDLE); /* Sample flash data for the system bus interface */ always @(posedge clk) if (rst) bus_dat_o <= 0; else if ((flash_phy_state == `CFI_PHY_FSM_READ_WAIT) && /* Wait for t_vlqv */ (!flash_phy_async_wait)) /* Sample flash data */ bus_dat_o <= flash_dq_io; /* Flash physical interface control state machine */ always @(posedge clk) if (rst) begin flash_adv_n_r <= 1'b0; flash_ce_n_r <= 1'b1; flash_oe_n_r <= 1'b1; flash_we_n_r <= 1'b1; flash_dq_o_r <= 0; flash_adr_r <= 0; flash_rst_n_r <= 0; flash_phy_state <= `CFI_PHY_FSM_IDLE; end else begin case (flash_phy_state) `CFI_PHY_FSM_IDLE : begin flash_rst_n_r <= 1'b1; flash_ce_n_r <= 1'b0; /* Take address from the bus controller */ flash_adr_r <= bus_adr_i; /* Wait for a read or write command */ if (bus_control_state == `CFI_FSM_DO_WRITE) begin flash_phy_state <= `CFI_PHY_FSM_WRITE_GO; /* Are we going to write a command? */ if (flash_cmd_to_write) begin flash_dq_o_r <= {{(flash_dq_width-8){1'b0}}, flash_cmd_to_write}; end else flash_dq_o_r <= bus_dat_i; end if (bus_control_state == `CFI_FSM_DO_READ) begin flash_phy_state <= `CFI_PHY_FSM_READ_GO; end if (bus_control_state == `CFI_FSM_DO_RESET) begin flash_phy_state <= `CFI_PHY_FSM_RESET_GO; end end `CFI_PHY_FSM_WRITE_GO: begin /* Assert CE, WE */ flash_we_n_r <= 1'b0; flash_phy_state <= `CFI_PHY_FSM_WRITE_WAIT; end `CFI_PHY_FSM_WRITE_WAIT: begin /* Wait for t_wlwh */ if (!flash_phy_async_wait) begin flash_phy_state <= `CFI_PHY_FSM_WRITE_DONE; flash_we_n_r <= 1'b1; end end `CFI_PHY_FSM_WRITE_DONE: begin flash_phy_state <= `CFI_PHY_FSM_IDLE; end `CFI_PHY_FSM_READ_GO: begin /* Assert CE, OE */ /*flash_adv_n_r <= 1'b1;*/ flash_ce_n_r <= 1'b0; flash_oe_n_r <= 1'b0; flash_phy_state <= `CFI_PHY_FSM_READ_WAIT; end `CFI_PHY_FSM_READ_WAIT: begin /* Wait for t_vlqv */ if (!flash_phy_async_wait) begin flash_oe_n_r <= 1'b1; flash_phy_state <= `CFI_PHY_FSM_READ_DONE; end end `CFI_PHY_FSM_READ_DONE: begin flash_phy_state <= `CFI_PHY_FSM_IDLE; end `CFI_PHY_FSM_RESET_GO: begin flash_phy_state <= `CFI_PHY_FSM_RESET_WAIT; flash_rst_n_r <= 1'b0; flash_oe_n_r <= 1'b1; end `CFI_PHY_FSM_RESET_WAIT : begin if (!flash_phy_async_wait) begin flash_rst_n_r <= 1'b1; flash_phy_state <= `CFI_PHY_FSM_RESET_DONE; end end `CFI_PHY_FSM_RESET_DONE : begin flash_phy_state <= `CFI_PHY_FSM_IDLE; end default: flash_phy_state <= `CFI_PHY_FSM_IDLE; endcase end /* Defaults are for 95ns access time part, 66MHz (15.15ns) system clock */ /* wlwh: cycles for WE assert to WE de-assert: write time */ parameter cfi_part_wlwh_cycles = 4; /* wlwh = 50ns, tck = 15ns, cycles = 4*/ /* elqv: cycles from adress to data valid */ parameter cfi_part_elqv_cycles = 7; /* tsop 256mbit elqv = 95ns, tck = 15ns, cycles = 6*/ assign flash_phy_async_wait = (|flash_phy_ctr); /* Load counter with wait times in cycles, determined by parameters. */ always @(posedge clk) if (rst) flash_phy_ctr <= 0; else if (flash_phy_state==`CFI_PHY_FSM_WRITE_GO) flash_phy_ctr <= cfi_part_wlwh_cycles - 1; else if (flash_phy_state==`CFI_PHY_FSM_READ_GO) flash_phy_ctr <= cfi_part_elqv_cycles - 2; else if (flash_phy_state==`CFI_PHY_FSM_RESET_GO) flash_phy_ctr <= 10; else if (|flash_phy_ctr) flash_phy_ctr <= flash_phy_ctr - 1; /* Signal to indicate when we should drive the data bus */ wire flash_bus_write_enable; assign flash_bus_write_enable = (bus_control_state == `CFI_FSM_DO_WRITE) | (bus_control_state == `CFI_FSM_DO_WRITE_WAIT); /* Assign signals to physical bus */ assign flash_dq_io = flash_bus_write_enable ? flash_dq_o_r : {flash_dq_width{1'bz}}; assign flash_adr_o = flash_adr_r; assign flash_adv_n_o = flash_adv_n_r; assign flash_wp_n_o = 1'b1; /* Never write protect */ assign flash_ce_n_o = flash_ce_n_r; assign flash_oe_n_o = flash_oe_n_r; assign flash_we_n_o = flash_we_n_r; assign flash_clk_o = 1'b1; assign flash_rst_n_o = flash_rst_n_r; endmodule // cfi_ctrl_engine
Go to most recent revision | Compare with Previous | Blame | View Log