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[/] [openrisc/] [trunk/] [orpsocv2/] [rtl/] [verilog/] [cfi_ctrl/] [cfi_ctrl.v] - Rev 866
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////////////////////////////////////////////////////////////////// //// //// //// //// 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 //// //// //// ////////////////////////////////////////////////////////////////////// /* Top level of CFI controller with 32-bit Wishbone classic interface Intended to be used at about 66MHz with a 32MB CFI flash part with 16-bit data interface. This module has two configurations - one where it pulls in the CFI control engine, which is intended to simplify accesses to a CFI flash, such as block unlock, erase, and programming. The alternate configuration is essentially mapping Wishbone accesses to the flash's bus. CFI Engine Wishbone interface: Basic functionality: Bits [27:26] decode the operation. 2'b00 : read/write to the flash memory 2'b01 : unlock block 2'b10 : erase block 2'b11 : block registers, other flash control features 0xc00_0000 : block status/control register bits: [0]: r/o : CFI controller busy [1]: w/o : clear flash status register [2]: w/o : reset flash device and controller 0xc00_0004 : flash device status register bits [7:0] : r/o : flash device status register 0xe00_0000 : read device identifier information User is able to access the device identifier information such as: offset 0x0 : manufacturer code offset 0x2 : device id offset bba + 0x4 : block (add increments of 128KB block size) offset 0xa : read config register See CFI docs for further details (shift offset left by 1) 0xe01_0000 : CFI query User is able to access the CFI query information The hex offsets in the CFI spec should be shifted left by one before applying to the Wishbone bus. Addresses under 0x000_0000 cause direct access to the flash Addresses under 0x400_0000 cause the block (addressed in [24:0]) to be unlocked Addresses under 0x800_0000 cause the block (addressed in [24:0]) to be erased */ module cfi_ctrl ( wb_clk_i, wb_rst_i, wb_dat_i, wb_adr_i, wb_stb_i, wb_cyc_i, wb_we_i, wb_sel_i, wb_dat_o, wb_ack_o, wb_err_o, wb_rty_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; parameter flash_write_cycles = 4; // wlwh/Tclk = 50ns / 15 ns (66Mhz) parameter flash_read_cycles = 7; // elqv/Tclk = 95 / 15 ns (66MHz) parameter cfi_engine = "ENABLED"; 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; input wb_clk_i, wb_rst_i; input [31:0] wb_dat_i, wb_adr_i; input wb_stb_i, wb_cyc_i, wb_we_i; input [3:0] wb_sel_i; output reg [31:0] wb_dat_o; output reg wb_ack_o; output wb_err_o, wb_rty_o; reg [3:0] wb_state; generate if (cfi_engine == "ENABLED") begin : cfi_engine_gen wire do_rst, do_init, do_readstatus; wire do_clearstatus, do_eraseblock, do_write, do_read, do_unlockblock; /* Track when we have new bus accesses and are currently serving them */ reg wb_req_in_progress; wire wb_req_new; always @(posedge wb_clk_i) if (wb_rst_i) wb_req_in_progress <= 0; else if (wb_req_new) wb_req_in_progress <= 1'b1; else if (wb_ack_o) wb_req_in_progress <= 0; assign wb_req_new = (wb_stb_i & wb_cyc_i) & !wb_req_in_progress; /* Registers for interfacing with the CFI controller */ reg [15:0] cfi_bus_dat_i; wire [15:0] cfi_bus_dat_o; reg [23:0] cfi_bus_adr_i; wire cfi_bus_ack_o; wire cfi_bus_busy_o; wire cfi_rw_sel; wire cfi_unlock_sel; wire cfi_erase_sel; wire cfi_scr_sel; wire cfi_readstatus_sel; wire cfi_clearstatus_sel; wire cfi_rst_sel; wire cfi_busy_sel; wire cfi_readdeviceident_sel; wire cfi_cfiquery_sel; reg cfi_bus_go; reg cfi_first_of_two_accesses; assign cfi_rw_sel = wb_adr_i[27:26]==2'b00; assign cfi_unlock_sel = wb_adr_i[27:26]==2'b01 && wb_we_i; assign cfi_erase_sel = wb_adr_i[27:26]==2'b10 && wb_we_i; assign cfi_scr_sel = wb_adr_i[27:26]==2'b11 && wb_adr_i[25:0]==26'd0; assign cfi_readstatus_sel = wb_adr_i[27:26]==2'b11 && wb_adr_i[25:0]==26'd4 && !wb_we_i; assign cfi_clearstatus_sel = cfi_scr_sel && wb_dat_i[1] && wb_we_i; assign cfi_rst_sel = cfi_scr_sel && wb_dat_i[2] && wb_we_i; assign cfi_busy_sel = cfi_scr_sel & !wb_we_i; assign cfi_readdeviceident_sel = wb_adr_i[27:26]==2'b11 && wb_adr_i[25]==1'b1 && !wb_adr_i[16]==1'b1 && !wb_we_i; assign cfi_cfiquery_sel = wb_adr_i[27:26]==2'b11 && wb_adr_i[25]==1'b1 && wb_adr_i[16]==1'b1 && !wb_we_i; assign do_rst = cfi_rst_sel & cfi_bus_go; assign do_init = 0; assign do_readstatus = cfi_readstatus_sel & cfi_bus_go; assign do_clearstatus = cfi_clearstatus_sel & cfi_bus_go; assign do_eraseblock = cfi_erase_sel & cfi_bus_go; assign do_write = cfi_rw_sel & wb_we_i & cfi_bus_go ; assign do_read = cfi_rw_sel & !wb_we_i & cfi_bus_go ; assign do_unlockblock = cfi_unlock_sel & cfi_bus_go ; assign do_readdeviceident = cfi_readdeviceident_sel & cfi_bus_go ; assign do_cfiquery = cfi_cfiquery_sel & cfi_bus_go ; /* Main statemachine */ `define WB_FSM_IDLE 0 `define WB_FSM_CFI_CMD_WAIT 2 always @(posedge wb_clk_i) if (wb_rst_i) begin wb_state <= `WB_FSM_IDLE; cfi_bus_go <= 0; /* Wishbone regs */ wb_dat_o <= 0; wb_ack_o <= 0; cfi_first_of_two_accesses <= 0; end else begin case (wb_state) `WB_FSM_IDLE: begin wb_ack_o <= 0; cfi_bus_go <= 0; /* Pickup new incoming accesses */ /* Potentially get into a state where we received a bus request but the CFI was still busy so waited. In this case we'll get a ACK from the controller and have a new request registered */ if (wb_req_new) begin if (cfi_busy_sel) /* want to read the busy flag */ begin wb_ack_o <= 1; wb_dat_o <= {30'd0, cfi_bus_busy_o}; end else if (!cfi_bus_busy_o | (wb_req_in_progress & cfi_bus_ack_o)) begin if (cfi_rw_sel | cfi_unlock_sel | cfi_erase_sel | cfi_readstatus_sel | cfi_clearstatus_sel | cfi_rst_sel | cfi_readdeviceident_sel | cfi_cfiquery_sel) begin wb_state <= `WB_FSM_CFI_CMD_WAIT; cfi_bus_go <= 1; if (cfi_rw_sel) begin /* Map address onto the 16-bit word bus*/ /* Reads always do full 32-bits, so adjust address accordingly.*/ /* setup address and number of cycles depending on request */ if (wb_we_i) begin /* Writing */ /* Only possible to write shorts at a time */ cfi_bus_dat_i <= wb_sel_i[1:0]==2'b11 ? wb_dat_i[15:0] : wb_dat_i[31:16]; cfi_bus_adr_i[23:0] <= wb_adr_i[24:1]; end else begin /* Reading */ /* Full or part word? */ if ((&wb_sel_i)) begin /* 32-bits */ cfi_first_of_two_accesses <= 1; cfi_bus_adr_i[23:0] <= {wb_adr_i[24:2],1'b0}; end else begin /*16-bits or byte */ cfi_bus_adr_i[23:0] <= {wb_adr_i[24:1]}; end end end if (cfi_unlock_sel | cfi_erase_sel) cfi_bus_adr_i[23:0] <= wb_adr_i[24:1]; if (cfi_readdeviceident_sel) cfi_bus_adr_i[23:0] <= {wb_adr_i[24:17],1'b0, 7'd0,wb_adr_i[9:1]}; if (cfi_cfiquery_sel) cfi_bus_adr_i[23:0] <= {14'd0,wb_adr_i[10:1]}; end // if (cfi_rw_sel | cfi_unlock_sel | ... end // if (!cfi_bus_busy_o | (wb_req_in_progress & ... end // if (wb_req_new) end // case: `WB_FSM_IDLE `WB_FSM_CFI_CMD_WAIT: begin cfi_bus_go <= 0; /* Wait for the CFI controller to do its thing */ if (cfi_bus_ack_o) begin if (cfi_rw_sel) begin /* Is this the first of two accesses? */ if (cfi_first_of_two_accesses) begin cfi_bus_adr_i <= cfi_bus_adr_i+1; cfi_first_of_two_accesses <= 0; cfi_bus_go <= 1; /* Dealing with a read or a write */ /* if (wb_we_i) cfi_bus_dat_i <= wb_dat_i[31:16]; else */ wb_dat_o[31:16] <= cfi_bus_dat_o; end else begin wb_state <= `WB_FSM_IDLE; wb_ack_o <= 1'b1; if (!wb_we_i) begin if (&wb_sel_i) wb_dat_o[15:0] <= cfi_bus_dat_o; else begin case (wb_sel_i) 4'b0001 : wb_dat_o[31:0] <= {4{cfi_bus_dat_o[7:0]}}; 4'b0010: wb_dat_o[31:0] <= {4{cfi_bus_dat_o[15:8]}}; 4'b0011 : wb_dat_o[31:0] <= {cfi_bus_dat_o,cfi_bus_dat_o}; 4'b0100 : wb_dat_o[31:0] <= {4{cfi_bus_dat_o[7:0]}}; 4'b1100 : wb_dat_o[31:0] <= {cfi_bus_dat_o,cfi_bus_dat_o}; 4'b1000 : wb_dat_o[31:0] <= {4{cfi_bus_dat_o[15:8]}}; endcase // case (wb_sel_i) end end end // else: !if(cfi_first_of_two_accesses) end // if (cfi_rw_sel) else begin /* All other accesses should be a single go of the CFI controller */ wb_state <= `WB_FSM_IDLE; wb_ack_o <= 1'b1; /* Get the read status data out */ if (cfi_readstatus_sel) wb_dat_o <= {4{cfi_bus_dat_o[7:0]}}; if (cfi_readdeviceident_sel | cfi_cfiquery_sel) wb_dat_o <= {2{cfi_bus_dat_o[15:0]}}; end end // if (cfi_bus_ack_o) else if (cfi_rst_sel)begin /* The reset command won't ACK back over the bus, incase the FSM hung and it actually reset all of its internals */ wb_state <= `WB_FSM_IDLE; wb_ack_o <= 1'b1; end end // case: `WB_FSM_CFI_CMD_WAIT endcase // case (wb_state) end // else: !if(wb_rst_i) assign wb_err_o = 0; assign wb_rty_o = 0; cfi_ctrl_engine # (.cfi_part_wlwh_cycles(flash_write_cycles), .cfi_part_elqv_cycles(flash_read_cycles) ) cfi_ctrl_engine0 ( .clk_i(wb_clk_i), .rst_i(wb_rst_i), .do_rst_i(do_rst), .do_init_i(do_init), .do_readstatus_i(do_readstatus), .do_clearstatus_i(do_clearstatus), .do_eraseblock_i(do_eraseblock), .do_unlockblock_i(do_unlockblock), .do_write_i(do_write), .do_read_i(do_read), .do_readdeviceident_i(do_readdeviceident), .do_cfiquery_i(do_cfiquery), .bus_dat_o(cfi_bus_dat_o), .bus_dat_i(cfi_bus_dat_i), .bus_adr_i(cfi_bus_adr_i), .bus_req_done_o(cfi_bus_ack_o), .bus_busy_o(cfi_bus_busy_o), .flash_dq_io(flash_dq_io), .flash_adr_o(flash_adr_o), .flash_adv_n_o(flash_adv_n_o), .flash_ce_n_o(flash_ce_n_o), .flash_clk_o(flash_clk_o), .flash_oe_n_o(flash_oe_n_o), .flash_rst_n_o(flash_rst_n_o), .flash_wait_i(flash_wait_i), .flash_we_n_o(flash_we_n_o), .flash_wp_n_o(flash_wp_n_o) ); end // if (cfi_engine == "ENABLED") else begin : cfi_simple reg long_read; reg [4:0] flash_ctr; reg [3:0] wb_state; reg [flash_dq_width-1:0] flash_dq_o_r; reg [flash_adr_width-1:0] flash_adr_o_r; reg flash_oe_n_o_r; reg flash_we_n_o_r; reg flash_rst_n_o_r; wire our_flash_oe; assign flash_ce_n_o = 0; assign flash_clk_o = 1; assign flash_rst_n_o = flash_rst_n_o_r; assign flash_wp_n_o = 1; assign flash_adv_n_o = 0; assign flash_dq_io = (our_flash_oe) ? flash_dq_o_r : {flash_dq_width{1'bz}}; assign flash_adr_o = flash_adr_o_r; assign flash_oe_n_o = flash_oe_n_o_r; assign flash_we_n_o = flash_we_n_o_r; `define WB_STATE_IDLE 0 `define WB_STATE_WAIT 1 assign our_flash_oe = (wb_state == `WB_STATE_WAIT || wb_ack_o) & wb_we_i; always @(posedge wb_clk_i) if (wb_rst_i) begin wb_ack_o <= 0; wb_dat_o <= 0; wb_state <= `WB_STATE_IDLE; flash_dq_o_r <= 0; flash_adr_o_r <= 0; flash_oe_n_o_r <= 1; flash_we_n_o_r <= 1; flash_rst_n_o_r <= 0; /* active */ long_read <= 0; flash_ctr <= 0; end else begin if (|flash_ctr) flash_ctr <= flash_ctr - 1; case(wb_state) `WB_STATE_IDLE: begin /* reset some signals to NOP status */ wb_ack_o <= 0; flash_oe_n_o_r <= 1; flash_we_n_o_r <= 1; flash_rst_n_o_r <= 1; if (wb_stb_i & wb_cyc_i & !wb_ack_o) begin flash_adr_o_r <= wb_adr_i[flash_adr_width:1]; wb_state <= `WB_STATE_WAIT; if (wb_adr_i[27]) begin /* Reset the flash, no matter the access */ flash_rst_n_o_r <= 0; flash_ctr <= 5'd16; end else if (wb_we_i) begin /* load counter with write cycle counter */ flash_ctr <= flash_write_cycles - 1; /* flash bus write command */ flash_we_n_o_r <= 0; flash_dq_o_r <= (|wb_sel_i[3:2]) ? wb_dat_i[31:16] : wb_dat_i[15:0]; end else begin /* load counter with write cycle counter */ flash_ctr <= flash_read_cycles - 1; if (&wb_sel_i) long_read <= 1; // Full 32-bit read, 2 read cycles flash_oe_n_o_r <= 0; end // else: !if(wb_we_i) end // if (wb_stb_i & wb_cyc_i) end `WB_STATE_WAIT: begin if (!(|flash_ctr)) begin if (wb_we_i) begin /* write finished */ wb_ack_o <= 1; wb_state <= `WB_STATE_IDLE; flash_we_n_o_r <= 1; end else begin /* read finished */ if (!(&wb_sel_i)) /* short or byte read */ begin case (wb_sel_i) 4'b0001, 4'b0100: wb_dat_o <= {4{flash_dq_io[7:0]}}; 4'b1000, 4'b0010: wb_dat_o <= {4{flash_dq_io[15:8]}}; default: wb_dat_o <= {2{flash_dq_io}}; endcase // case (wb_sel_i) wb_state <= `WB_STATE_IDLE; wb_ack_o <= 1; flash_oe_n_o_r <= 1; end else if (long_read) begin /* now go on to read next word */ wb_dat_o[31:16] <= flash_dq_io; long_read <= 0; flash_ctr <= flash_read_cycles; flash_adr_o_r <= flash_adr_o_r + 1; end else begin /* finished two-part read */ wb_dat_o[15:0] <= flash_dq_io; wb_state <= `WB_STATE_IDLE; wb_ack_o <= 1; flash_oe_n_o_r <= 1; end end end end default: wb_state <= `WB_STATE_IDLE; endcase // case (wb_state) end // else: !if(wb_rst_i) end // block: cfi_simple endgenerate endmodule // cfi_ctrl
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