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[/] [openarty/] [trunk/] [rtl/] [wbddrsdram.v] - Rev 17
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//////////////////////////////////////////////////////////////////////////////// // // Filename: wbddrsdram.v // // Project: OpenArty, an entirely open SoC based upon the Arty platform // // Purpose: // // Creator: Dan Gisselquist, Ph.D. // Gisselquist Technology, LLC // //////////////////////////////////////////////////////////////////////////////// // // Copyright (C) 2015-2016, Gisselquist Technology, LLC // // This program is free software (firmware): you can redistribute it and/or // modify it under the terms of the GNU General Public License as published // by the Free Software Foundation, either version 3 of the License, or (at // your option) any later version. // // This program is distributed in the hope that it will be useful, but WITHOUT // ANY WARRANTY; without even the implied warranty of MERCHANTIBILITY or // FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License // for more details. // // You should have received a copy of the GNU General Public License along // with this program. (It's in the $(ROOT)/doc directory, run make with no // target there if the PDF file isn't present.) If not, see // <http://www.gnu.org/licenses/> for a copy. // // License: GPL, v3, as defined and found on www.gnu.org, // http://www.gnu.org/licenses/gpl.html // // //////////////////////////////////////////////////////////////////////////////// // // // Possible commands to the DDR3 memory. These consist of settings for the // bits: o_wb_cs_n, o_wb_ras_n, o_wb_cas_n, and o_wb_we_n, respectively. `define DDR_MRSET 4'b0000 `define DDR_REFRESH 4'b0001 `define DDR_PRECHARGE 4'b0010 `define DDR_ACTIVATE 4'b0011 `define DDR_WRITE 4'b0100 `define DDR_READ 4'b0101 `define DDR_ZQS 4'b0110 `define DDR_NOOP 4'b0111 //`define DDR_DESELECT 4'b1??? // // In this controller, 24-bit commands tend to be passed around. These // 'commands' are bit fields. Here we specify the bits associated with // the bit fields. `define DDR_RSTDONE 24 // End the reset sequence? `define DDR_RSTTIMER 23 // Does this reset command take multiple clocks? `define DDR_RSTBIT 22 // Value to place on reset_n `define DDR_CKEBIT 21 // Should this reset command set CKE? // // Refresh command bit fields `define DDR_NEEDREFRESH 23 `define DDR_RFTIMER 22 `define DDR_RFBEGIN 21 // `define DDR_CMDLEN 21 `define DDR_CSBIT 20 `define DDR_RASBIT 19 `define DDR_CASBIT 18 `define DDR_WEBIT 17 `define DDR_NOPTIMER 16 // Steal this from BA bits `define DDR_BABITS 3 // BABITS are really from 18:16, they are 3 bits `define DDR_ADDR_BITS 14 // module wbddrsdram(i_clk, i_reset, i_wb_cyc, i_wb_stb, i_wb_we, i_wb_addr, i_wb_data, o_wb_ack, o_wb_stall, o_wb_data, o_ddr_reset_n, o_ddr_cke, o_ddr_cs_n, o_ddr_ras_n, o_ddr_cas_n, o_ddr_we_n, o_ddr_dqs, o_ddr_dm, o_ddr_odt, o_ddr_bus_oe, o_ddr_addr, o_ddr_ba, o_ddr_data, i_ddr_data); parameter CKRBITS = 13, // Bits in CKREFI4 CKREFI = 13'd1560, // 4 * 7.8us at 200 MHz clock CKRFC = 320, CKWR = 3, CKRP = 11, // (=tRTP)Time from precharge to open command CKCAS = 11, // CAS Latency, tCL CKXPR = CKRFC+5+2, // Clocks per tXPR timeout BUSREG= 2+CKCAS, BUSNOW= 3+CKCAS; input i_clk, i_reset; // Wishbone inputs input i_wb_cyc, i_wb_stb, i_wb_we; input [25:0] i_wb_addr; input [31:0] i_wb_data; // Wishbone outputs output reg o_wb_ack; output reg o_wb_stall; output reg [31:0] o_wb_data; // DDR3 RAM Controller output reg o_ddr_reset_n, o_ddr_cke; // Control outputs output wire o_ddr_cs_n, o_ddr_ras_n, o_ddr_cas_n,o_ddr_we_n; // DQS outputs:set to 3'b010 when data is active, 3'b100 (i.e. 2'bzz) ow output wire o_ddr_dqs; output reg o_ddr_dm; output reg o_ddr_odt; output wire o_ddr_bus_oe; // Address outputs output wire [13:0] o_ddr_addr; output wire [2:0] o_ddr_ba; // And the data inputs and outputs output reg [31:0] o_ddr_data; input [31:0] i_ddr_data; reg drive_dqs; // The pending transaction reg [31:0] r_data; reg r_pending, r_we; reg [25:0] r_addr; reg [13:0] r_row; reg [2:0] r_bank; reg [9:0] r_col; reg [1:0] r_sub; reg r_move; // It was accepted, and can move to next stage // The pending transaction, one further into the pipeline. This is // the stage where the read/write command is actually given to the // interface if we haven't stalled. reg [31:0] s_data; reg s_pending, s_we; // , s_match; reg [25:0] s_addr; reg [13:0] s_row, s_nxt_row; reg [2:0] s_bank, s_nxt_bank; reg [9:0] s_col; reg [1:0] s_sub; // Can the pending transaction be satisfied with the current (ongoing) // transaction? reg m_move, m_match, m_pending, m_we; reg [25:0] m_addr; reg [13:0] m_row; reg [2:0] m_bank; reg [9:0] m_col; reg [1:0] m_sub; // Can we preload the next bank? reg [13:0] r_nxt_row; reg [2:0] r_nxt_bank; reg need_close_bank, need_close_this_bank, last_close_bank, maybe_close_next_bank, last_maybe_close, need_open_bank, last_open_bank, maybe_open_next_bank, last_maybe_open, valid_bank, last_valid_bank; reg [(`DDR_CMDLEN-1):0] close_bank_cmd, activate_bank_cmd, maybe_close_cmd, maybe_open_cmd, rw_cmd; reg [1:0] rw_sub; reg rw_we; wire w_this_closing_bank, w_this_opening_bank, w_this_maybe_close, w_this_maybe_open, w_this_rw_move; reg last_closing_bank, last_opening_bank; wire w_need_close_this_bank, w_need_open_bank, w_r_valid, w_s_valid, w_s_match; // // tWTR = 7.5 // tRRD = 7.5 // tREFI= 7.8 // tFAW = 45 // tRTP = 7.5 // tCKE = 5.625 // tRFC = 160 // tRP = 13.5 // tRAS = 36 // tRCD = 13.5 // // RESET: // 1. Hold o_reset_n = 1'b0; for 200 us, or 40,000 clocks (65536 perhaps?) // Hold cke low during this time as well // The clock should be free running into the chip during this time // Leave command in NOOP state: {cs,ras,cas,we} = 4'h7; // ODT must be held low // 2. Hold cke low for another 500us, or 100,000 clocks // 3. Raise CKE, continue outputting a NOOP for // tXPR, tDLLk, and tZQInit // 4. Load MRS2, wait tMRD // 4. Load MRS3, wait tMRD // 4. Load MRS1, wait tMOD // Before using the SDRAM, we'll need to program at least 3 of the mode // registers, if not all 4. // tMOD clocks are required to program the mode registers, during which // time the RAM must be idle. // // NOOP: CS low, RAS, CAS, and WE high // // Reset logic should be simple, and is given as follows: // note that it depends upon a ROM memory, reset_mem, and an address into that // memory: reset_address. Each memory location provides either a "command" to // the DDR3 SDRAM, or a timer to wait until the next command. Further, the // timer commands indicate whether or not the command during the timer is to // be set to idle, or whether the command is instead left as it was. reg reset_override, reset_ztimer, maintenance_override; reg [4:0] reset_address; reg [(`DDR_CMDLEN-1):0] reset_cmd, cmd, refresh_cmd, maintenance_cmd; reg [24:0] reset_instruction; reg [16:0] reset_timer; initial reset_override = 1'b1; initial reset_address = 5'h0; always @(posedge i_clk) if (i_reset) begin reset_override <= 1'b1; reset_cmd <= { `DDR_NOOP, reset_instruction[16:0]}; end else if (reset_ztimer) begin if (reset_instruction[`DDR_RSTDONE]) reset_override <= 1'b0; reset_cmd <= reset_instruction[20:0]; end initial reset_ztimer = 1'b0; // Is the timer zero? initial reset_timer = 17'h02; always @(posedge i_clk) if (i_reset) begin reset_ztimer <= 1'b0; reset_timer <= 17'd2; end else if (!reset_ztimer) begin reset_ztimer <= (reset_timer == 17'h01); reset_timer <= reset_timer - 17'h01; end else if (reset_instruction[`DDR_RSTTIMER]) begin reset_ztimer <= 1'b0; reset_timer <= reset_instruction[16:0]; end wire [16:0] w_ckXPR, w_ckRST, w_ckRP, w_ckRFC_first; wire [2:0] w_ckCAS_MR2, w_ckCAS_MR0, w_ckCAS, w_ckFIVE; wire [13:0] w_MR0, w_MR1, w_MR2; assign w_ckXPR = CKXPR; assign w_ckRST = 4; assign w_ckRP = CKRP-2; /* verilator lint_off WIDTH */ assign w_ckCAS = CKCAS; /* verilator lint_on WIDTH */ assign w_ckRFC_first = CKRFC-2-9+8; assign w_ckFIVE = 3'h5; assign w_ckCAS_MR2 = w_ckFIVE-3'h5; // w_ckCAS-3'h5; assign w_ckCAS_MR0 = w_ckFIVE-3'h4; // w_ckCAS-3'h4; assign w_MR2 = { 3'h0, 2'b00, 1'b0, 1'b0, 1'b1, w_ckCAS_MR2, 3'b0 }; assign w_MR1 = { 1'h0, // Reserved for Future Use (RFU) 1'b0, // Qoff - output buffer enabled 1'b1, // TDQS ... enabled 1'b0, // RFU 1'b0, // High order bit, Rtt_Nom (3'b011) 1'b0, // RFU // 1'b0, // Disable write-leveling 1'b1, // Mid order bit of Rtt_Nom 1'b0, // High order bit of Output Drvr Impedence Ctrl 2'b0, // Additive latency = 0 1'b1, // Low order bit of Rtt_Nom 1'b0, // DIC set to 2'b00 1'b0 // MRS1, DLL enable }; assign w_MR0 = { 1'b0, // Reserved for future use 1'b0, // PPD control, (slow exit(DLL off)) 3'b1, // Write recovery for auto precharge 1'b0, // DLL Reset (No) // 1'b0, // TM mode normal w_ckCAS_MR0, // High 3-bits, CAS latency (=4'b1110=4'd5,tCL=11) // 1'b0, // Read burst type = nibble sequential (CKCAS>11)? 1'b1:1'b0, // Low bit of cas latency 2'b0 // Burst length = 8 (Fixed) }; always @(posedge i_clk) if (i_reset) reset_instruction <= { 4'h4, `DDR_NOOP, 17'd40_000 }; else if (reset_ztimer) case(reset_address) // RSTDONE, TIMER, CKE, ?? // 1. Reset asserted (active low) for 200 us. (@200MHz) 5'h0: reset_instruction <= { 4'h4, `DDR_NOOP, 17'd40_000 }; // 2. Reset de-asserted, wait 500 us before asserting CKE 5'h1: reset_instruction <= { 4'h6, `DDR_NOOP, 17'd100_000 }; // 3. Assert CKE, wait minimum of Reset CKE Exit time 5'h2: reset_instruction <= { 4'h7, `DDR_NOOP, w_ckXPR }; // 4. Look MR2. (1CK, no TIMER) 5'h3: reset_instruction <= { 4'h3, `DDR_NOOP, 3'h2, w_MR2 }; 5'h4: reset_instruction <= { 4'h3, `DDR_MRSET, 3'h2, w_MR2 }; 5'h5: reset_instruction <= { 4'h3, `DDR_NOOP, 3'h2, w_MR2 }; // 3. Wait 4 clocks (tMRD) 5'h6: reset_instruction <= { 4'h7, `DDR_NOOP, 17'h02 }; // 5. Set MR1 5'h7: reset_instruction <= { 4'h3, `DDR_NOOP, 3'h1, w_MR1 }; 5'h8: reset_instruction <= { 4'h3, `DDR_MRSET, 3'h1, w_MR1 }; 5'h9: reset_instruction <= { 4'h3, `DDR_NOOP, 3'h1, w_MR1 }; // 7. Wait another 4 clocks 5'ha: reset_instruction <= { 4'h7, `DDR_NOOP, 17'h02 }; // 8. Send MRS0 5'hb: reset_instruction <= { 4'h3, `DDR_NOOP, 3'h0, w_MR0 }; 5'hc: reset_instruction <= { 4'h3, `DDR_MRSET, 3'h0, w_MR0 }; 5'hd: reset_instruction <= { 4'h3, `DDR_NOOP, 3'h0, w_MR0 }; // 9. Wait tMOD, is max(12 clocks, 15ns) 5'he: reset_instruction <= { 4'h7, `DDR_NOOP, 17'h0a }; // 10. Issue a ZQCL command to start ZQ calibration, A10 is high 5'hf: reset_instruction <= { 4'h3, `DDR_ZQS, 6'h0, 1'b1, 10'h0}; //11.Wait for both tDLLK and tZQinit completed, both are 512 cks 5'h10: reset_instruction <= { 4'h7, `DDR_NOOP, 17'd512 }; // 12. Precharge all command 5'h11: reset_instruction <= { 4'h3, `DDR_PRECHARGE, 6'h0, 1'b1, 10'h0 }; // 13. Wait for the precharge to complete 5'h12: reset_instruction <= { 4'h7, `DDR_NOOP, w_ckRP }; // 14. A single Auto Refresh commands 5'h13: reset_instruction <= { 4'h3, `DDR_REFRESH, 17'h00 }; // 15. Wait for the auto refresh to complete 5'h14: reset_instruction <= { 4'h7, `DDR_NOOP, w_ckRFC_first }; // Two Auto Refresh commands default: reset_instruction <={4'hb, `DDR_NOOP, 17'd00_000 }; endcase // reset_instruction <= reset_mem[reset_address]; initial reset_address = 5'h0; always @(posedge i_clk) if (i_reset) reset_address <= 5'h1; else if ((reset_ztimer)&&(reset_override)) reset_address <= reset_address + 5'h1; // // initial reset_mem = // 0. !DONE, TIMER,RESET_N=0, CKE=0, CMD = NOOP, TIMER = 200us ( 40,000) // 1. !DONE, TIMER,RESET_N=1, CKE=0, CMD = NOOP, TIMER = 500us (100,000) // 2. !DONE, TIMER,RESET_N=1, CKE=1, CMD = NOOP, TIMER = (Look me up) // 3. !DONE,!TIMER,RESET_N=1, CKE=1, CMD = MODE, MRS // 4. !DONE,!TIMER,RESET_N=1, CKE=1, CMD = NOOP, TIMER = tMRS // 5. !DONE,!TIMER,RESET_N=1, CKE=1, CMD = MODE, MRS3 // 6. !DONE,!TIMER,RESET_N=1, CKE=1, CMD = NOOP, TIMER = tMRS // 7. !DONE,!TIMER,RESET_N=1, CKE=1, CMD = MODE, MRS1 // 8. !DONE,!TIMER,RESET_N=1, CKE=1, CMD = NOOP, TIMER = tMRS // 9. !DONE,!TIMER,RESET_N=1, CKE=1, CMD = MODE, MRS1 // 10. !DONE,!TIMER,RESET_N=1, CKE=1, CMD = NOOP, TIMER = tMOD // 11. !DONE,!TIMER,RESET_N=1, CKE=1, (Pre-charge all) // 12. !DONE,!TIMER,RESET_N=1, CKE=1, (wait) // 13. !DONE,!TIMER,RESET_N=1, CKE=1, (Auto-refresh) // 14. !DONE,!TIMER,RESET_N=1, CKE=1, (Auto-refresh) // 15. !DONE,!TIMER,RESET_N=1, CKE=1, (wait) // // // Let's keep track of any open banks. There are 8 of them to keep track of. // // A precharge requires 3 clocks at 200MHz to complete, 2 clocks at 100MHz. // // // reg need_refresh; wire w_precharge_all; reg [CKRP:0] bank_status [0:7]; reg [13:0] bank_address [0:7]; reg [3:0] bank_wr_ck [0:7]; // tWTR reg bank_wr_ckzro [0:7]; // tWTR reg [7:0] bank_open; reg [7:0] bank_closed; wire [3:0] write_recycle_clocks; assign write_recycle_clocks = CKWR+4+4; initial bank_open = 0; initial bank_closed = 8'hff; always @(posedge i_clk) begin bank_status[0] <= { bank_status[0][(CKRP-1):0], bank_status[0][0] }; bank_status[1] <= { bank_status[1][(CKRP-1):0], bank_status[1][0] }; bank_status[2] <= { bank_status[2][(CKRP-1):0], bank_status[2][0] }; bank_status[3] <= { bank_status[3][(CKRP-1):0], bank_status[3][0] }; bank_status[4] <= { bank_status[4][(CKRP-1):0], bank_status[4][0] }; bank_status[5] <= { bank_status[5][(CKRP-1):0], bank_status[5][0] }; bank_status[6] <= { bank_status[6][(CKRP-1):0], bank_status[6][0] }; bank_status[7] <= { bank_status[7][(CKRP-1):0], bank_status[7][0] }; bank_wr_ck[0] <= (|bank_wr_ck[0])?(bank_wr_ck[0]-4'h1):4'h0; bank_wr_ck[1] <= (|bank_wr_ck[1])?(bank_wr_ck[1]-4'h1):4'h0; bank_wr_ck[2] <= (|bank_wr_ck[2])?(bank_wr_ck[2]-4'h1):4'h0; bank_wr_ck[3] <= (|bank_wr_ck[3])?(bank_wr_ck[3]-4'h1):4'h0; bank_wr_ck[4] <= (|bank_wr_ck[4])?(bank_wr_ck[4]-4'h1):4'h0; bank_wr_ck[5] <= (|bank_wr_ck[5])?(bank_wr_ck[5]-4'h1):4'h0; bank_wr_ck[6] <= (|bank_wr_ck[6])?(bank_wr_ck[6]-4'h1):4'h0; bank_wr_ck[7] <= (|bank_wr_ck[7])?(bank_wr_ck[7]-4'h1):4'h0; bank_wr_ckzro[0] <= (bank_wr_ck[0][3:1]==3'b00); bank_wr_ckzro[1] <= (bank_wr_ck[1][3:1]==3'b00); bank_wr_ckzro[2] <= (bank_wr_ck[2][3:1]==3'b00); bank_wr_ckzro[3] <= (bank_wr_ck[3][3:1]==3'b00); bank_wr_ckzro[4] <= (bank_wr_ck[4][3:1]==3'b00); bank_wr_ckzro[5] <= (bank_wr_ck[5][3:1]==3'b00); bank_wr_ckzro[6] <= (bank_wr_ck[6][3:1]==3'b00); bank_wr_ckzro[7] <= (bank_wr_ck[7][3:1]==3'b00); bank_open[0] <= (bank_status[0][(CKRP-2):0] =={(CKRP-1){1'b1}}); bank_open[1] <= (bank_status[1][(CKRP-2):0] =={(CKRP-1){1'b1}}); bank_open[2] <= (bank_status[2][(CKRP-2):0] =={(CKRP-1){1'b1}}); bank_open[3] <= (bank_status[3][(CKRP-2):0] =={(CKRP-1){1'b1}}); bank_open[4] <= (bank_status[4][(CKRP-2):0] =={(CKRP-1){1'b1}}); bank_open[5] <= (bank_status[5][(CKRP-2):0] =={(CKRP-1){1'b1}}); bank_open[6] <= (bank_status[6][(CKRP-2):0] =={(CKRP-1){1'b1}}); bank_open[7] <= (bank_status[7][(CKRP-2):0] =={(CKRP-1){1'b1}}); bank_closed[0] <= (bank_status[0][(CKRP-3):0] == 0); bank_closed[1] <= (bank_status[1][(CKRP-3):0] == 0); bank_closed[2] <= (bank_status[2][(CKRP-3):0] == 0); bank_closed[3] <= (bank_status[3][(CKRP-3):0] == 0); bank_closed[4] <= (bank_status[4][(CKRP-3):0] == 0); bank_closed[5] <= (bank_status[5][(CKRP-3):0] == 0); bank_closed[6] <= (bank_status[6][(CKRP-3):0] == 0); bank_closed[7] <= (bank_status[7][(CKRP-3):0] == 0); if (w_this_rw_move) bank_wr_ck[rw_cmd[16:14]] <= (rw_cmd[`DDR_WEBIT])? 4'h0 : write_recycle_clocks; if (maintenance_override) begin bank_status[0][0] <= 1'b0; bank_status[1][0] <= 1'b0; bank_status[2][0] <= 1'b0; bank_status[3][0] <= 1'b0; bank_status[4][0] <= 1'b0; bank_status[5][0] <= 1'b0; bank_status[6][0] <= 1'b0; bank_status[7][0] <= 1'b0; bank_open <= 0; bank_closed <= 8'hff; end else if (need_close_bank) begin bank_status[close_bank_cmd[16:14]] <= { bank_status[close_bank_cmd[16:14]][(CKRP-1):0], 1'b0 }; bank_open[close_bank_cmd[16:14]] <= 1'b0; // bank_status[close_bank_cmd[16:14]][0] <= 1'b0; end else if (need_open_bank) begin bank_status[activate_bank_cmd[16:14]] <= { bank_status[activate_bank_cmd[16:14]][(CKRP-1):0], 1'b1 }; // bank_status[activate_bank_cmd[16:14]][0] <= 1'b1; bank_closed[activate_bank_cmd[16:14]] <= 1'b0; end else if (valid_bank) ; else if (maybe_close_next_bank) begin bank_status[maybe_close_cmd[16:14]] <= { bank_status[maybe_close_cmd[16:14]][(CKRP-1):0], 1'b0 }; bank_open[maybe_close_cmd[16:14]] <= 1'b0; end else if (maybe_open_next_bank) begin bank_status[maybe_open_cmd[16:14]] <= { bank_status[maybe_open_cmd[16:14]][(CKRP-1):0], 1'b1 }; // bank_status[activate_bank_cmd[16:14]][0] <= 1'b1; bank_closed[maybe_open_cmd[16:14]] <= 1'b0; end end always @(posedge i_clk) // if (cmd[22:19] == `DDR_ACTIVATE) if (w_this_opening_bank) bank_address[activate_bank_cmd[16:14]] <= activate_bank_cmd[13:0]; else if (!w_this_maybe_open) bank_address[maybe_open_cmd[16:14]] <= maybe_open_cmd[13:0]; // // // Okay, let's investigate when we need to do a refresh. Our plan will be to // do 4 refreshes every tREFI*4 seconds. tREFI = 7.8us, but its a parameter // in the number of clocks so that we can handle both 100MHz and 200MHz clocks. // // Note that 160ns are needed between refresh commands (JEDEC, p172), or // 320 clocks @200MHz, or equivalently 160 clocks @100MHz. Thus to issue 4 // of these refresh cycles will require 4*320=1280 clocks@200 MHz. After this // time, no more refreshes will be needed for 6240 clocks. // // Let's think this through: // REFRESH_COST = (n*(320)+24)/(n*1560) // // // reg refresh_ztimer; reg [16:0] refresh_counter; reg [2:0] refresh_addr; reg [23:0] refresh_instruction; always @(posedge i_clk) if (reset_override) refresh_addr <= 3'hf; else if (refresh_ztimer) refresh_addr <= refresh_addr + 3'h1; else if (refresh_instruction[`DDR_RFBEGIN]) refresh_addr <= 3'h0; always @(posedge i_clk) if (reset_override) begin refresh_ztimer <= 1'b1; refresh_counter <= 17'd0; end else if (!refresh_ztimer) begin refresh_ztimer <= (refresh_counter == 17'h1); refresh_counter <= (refresh_counter - 17'h1); end else if (refresh_instruction[`DDR_RFTIMER]) begin refresh_ztimer <= 1'b0; refresh_counter <= refresh_instruction[16:0]; end `ifdef QUADRUPLE_REFRESH // REFI4 = 13'd6240 wire [16:0] w_ckREFIn, w_ckREFRst, w_wait_for_idle, w_precharge_to_refresh; assign w_wait_for_idle = 5+CKCAS; assign w_precharge_to_refresh = CKRP-1; assign w_ckREFIn[(CKRBITS-1): 0] = CKREFI4-5*CKRFC-2-10; assign w_ckREFIn[ 16:(CKRBITS)] = 0; assign w_ckREFRst = CKRFC-2-12; always @(posedge i_clk) if (refresh_ztimer) case(refresh_addr)//NEED-RFC, HAVE-TIMER, 4'h0: refresh_instruction <= { 3'h2, `DDR_NOOP, w_ckREFIn }; // 17'd10 = time to complete write, plus write recovery time // minus two (cause we can't count zero or one) // = WL+4+tWR-2 = 10 // = 5+4+3-2 = 10 4'h1: refresh_instruction <= { 3'h6, `DDR_NOOP, w_wait_for_idle }; 4'h2: refresh_instruction <= { 3'h4, `DDR_PRECHARGE, 17'h0400 }; 4'h3: refresh_instruction <= { 3'h6, `DDR_NOOP, w_precharge_to_refresh }; 4'h4: refresh_instruction <= { 3'h4, `DDR_REFRESH, 17'h00 }; 4'h5: refresh_instruction <= { 3'h6, `DDR_NOOP, w_ckRFC }; 4'h6: refresh_instruction <= { 3'h4, `DDR_REFRESH, 17'h00 }; 4'h7: refresh_instruction <= { 3'h6, `DDR_NOOP, w_ckRFC }; 4'h8: refresh_instruction <= { 3'h4, `DDR_REFRESH, 17'h00 }; 4'h9: refresh_instruction <= { 3'h6, `DDR_NOOP, w_ckRFC }; 4'ha: refresh_instruction <= { 3'h4, `DDR_REFRESH, 17'h00 }; 4'hb: refresh_instruction <= { 3'h6, `DDR_NOOP, w_ckRFC }; 4'hc: refresh_instruction <= { 3'h2, `DDR_NOOP, w_ckREFRst }; default: refresh_instruction <= { 3'h1, `DDR_NOOP, 17'h00 }; endcase `else wire [16:0] w_ckREFI_left, w_ckRFC_nxt, w_wait_for_idle, w_precharge_to_refresh; assign w_wait_for_idle = 5+CKCAS; assign w_precharge_to_refresh = CKRP-2; assign w_ckREFI_left[16:0] = { 4'h0, CKREFI }-CKRFC-9 -w_wait_for_idle -w_precharge_to_refresh; // assign w_ckREFI_left[16:13] = 0; assign w_ckRFC_nxt[8:0] = CKRFC+9'h2; assign w_ckRFC_nxt[16:9] = 0; always @(posedge i_clk) if (refresh_ztimer) case(refresh_addr)//NEED-REFRESH, HAVE-TIMER, BEGIN(start-over) 3'h0: refresh_instruction <= { 3'h2, `DDR_NOOP, w_ckREFI_left }; 3'h1: refresh_instruction <= { 3'h6, `DDR_NOOP, w_wait_for_idle }; 3'h2: refresh_instruction <= { 3'h4, `DDR_PRECHARGE, 17'h0400 }; 3'h3: refresh_instruction <= { 3'h6, `DDR_NOOP, w_precharge_to_refresh }; 3'h4: refresh_instruction <= { 3'h4, `DDR_REFRESH, 17'h00 }; 3'h5: refresh_instruction <= { 3'h6, `DDR_NOOP, w_ckRFC_nxt }; default: refresh_instruction <= { 3'h1, `DDR_NOOP, 17'h00 }; endcase `endif always @(posedge i_clk) if (reset_override) refresh_cmd <= { `DDR_NOOP, w_ckREFI_left }; else if (refresh_ztimer) refresh_cmd <= refresh_instruction[20:0]; always @(posedge i_clk) if (reset_override) need_refresh <= 1'b0; else if (refresh_ztimer) need_refresh <= refresh_instruction[`DDR_NEEDREFRESH]; // // // Let's track: when will our bus be active? When will we be reading or // writing? // // reg [BUSNOW:0] bus_active, bus_read, bus_new, bus_ack; reg [1:0] bus_subaddr [BUSNOW:0]; initial bus_active = 0; initial bus_ack = 0; always @(posedge i_clk) begin bus_active[BUSNOW:0] <= { bus_active[(BUSNOW-1):0], 1'b0 }; bus_read[BUSNOW:0] <= { bus_read[(BUSNOW-1):0], 1'b0 }; // Drive the d-bus? // Is this a new command? i.e., the start of a transaction? bus_new[BUSNOW:0] <= { bus_new[(BUSNOW-1):0], 1'b0 }; // Will this position on the bus get a wishbone acknowledgement? bus_ack[BUSNOW:0] <= { bus_ack[(BUSNOW-1):0], 1'b0 }; //bus_mask[8:0] <= { bus_mask[7:0], 1'b1 }; // Write this value? bus_subaddr[8] <= bus_subaddr[7]; bus_subaddr[7] <= bus_subaddr[6]; bus_subaddr[6] <= bus_subaddr[5]; bus_subaddr[5] <= bus_subaddr[4]; bus_subaddr[4] <= bus_subaddr[3]; bus_subaddr[3] <= bus_subaddr[2]; bus_subaddr[2] <= bus_subaddr[1]; bus_subaddr[1] <= bus_subaddr[0]; bus_subaddr[0] <= 2'h3; bus_ack[5] <= (bus_ack[4])&& ((bus_subaddr[5] != bus_subaddr[4]) ||(bus_new[4])); if (w_this_rw_move) begin bus_active[3:0]<= 4'hf; // Once per clock bus_subaddr[3] <= 2'h0; bus_subaddr[2] <= 2'h1; bus_subaddr[1] <= 2'h2; bus_new[{ 2'b0, rw_sub }] <= 1'b1; bus_ack[3:0] <= 4'h0; bus_ack[{ 2'b0, rw_sub }] <= 1'b1; bus_read[3:0] <= (rw_we)? 4'h0:4'hf; end else if ((s_pending)&&(!pipe_stall)) begin if (bus_subaddr[3] == s_sub) bus_ack[4] <= 1'b1; if (bus_subaddr[2] == s_sub) bus_ack[3] <= 1'b1; if (bus_subaddr[1] == s_sub) bus_ack[2] <= 1'b1; if (bus_subaddr[0] == s_sub) bus_ack[1] <= 1'b1; end end // Need to set o_wb_dqs high one clock prior to any read. always @(posedge i_clk) drive_dqs <= (|bus_active[BUSREG:(BUSREG-1)]) &&(~(|bus_read[BUSREG:(BUSREG-1)])); // // // Now, let's see, can we issue a read command? // // reg pre_valid; always @(posedge i_clk) if ((refresh_ztimer)&&(refresh_instruction[`DDR_NEEDREFRESH])) pre_valid <= 1'b0; else if (need_refresh) pre_valid <= 1'b0; else if (w_this_rw_move) pre_valid <= 1'b0; else if (bus_active[0]) pre_valid <= 1'b0; else pre_valid <= 1'b1; assign w_r_valid = (pre_valid)&&(r_pending) &&(bank_status[r_bank][(CKRP-2)]) &&(bank_address[r_bank]==r_row) &&((r_we)||(bank_wr_ckzro[r_bank])); assign w_s_valid = (pre_valid)&&(s_pending) &&(bank_status[s_bank][(CKRP-2)]) &&(bank_address[s_bank]==s_row) &&((s_we)||(bank_wr_ckzro[s_bank])); assign w_s_match = (s_pending)&&(r_pending)&&(r_we == s_we) &&(r_row == s_row)&&(r_bank == s_bank) &&(r_col == s_col) &&(r_sub > s_sub); reg pipe_stall; always @(posedge i_clk) begin r_pending <= (i_wb_stb)&&(~o_wb_stall) ||(r_pending)&&(pipe_stall); if (~pipe_stall) s_pending <= r_pending; if (~pipe_stall) begin pipe_stall <= (r_pending)&&(((!w_r_valid)||(valid_bank))&&(!w_s_match)); o_wb_stall <= (r_pending)&&(((!w_r_valid)||(valid_bank))&&(!w_s_match)); end else begin // if (pipe_stall) pipe_stall <= (s_pending)&&((!w_s_valid)||(valid_bank)||(r_move)||(last_valid_bank)); o_wb_stall <= (s_pending)&&((!w_s_valid)||(valid_bank)||(r_move)||(last_valid_bank)); end if (need_refresh) o_wb_stall <= 1'b1; if (~pipe_stall) begin r_we <= i_wb_we; r_addr <= i_wb_addr; r_data <= i_wb_data; r_row <= i_wb_addr[25:12]; r_bank <= i_wb_addr[11:9]; r_col <= { i_wb_addr[8:2], 3'b000 }; // 9:2 r_sub <= i_wb_addr[1:0]; // pre-emptive work r_nxt_row <= (i_wb_addr[11:9]==3'h7)?i_wb_addr[25:12]+14'h1:i_wb_addr[25:12]; r_nxt_bank <= i_wb_addr[11:9]+3'h1; end if (~pipe_stall) begin // Moving one down the pipeline s_we <= r_we; s_addr <= r_addr; s_data <= r_data; s_row <= r_row; s_bank <= r_bank; s_col <= r_col; s_sub <= r_sub; // pre-emptive work s_nxt_row <= r_nxt_row; s_nxt_bank <= r_nxt_bank; // s_match <= w_s_match; end end assign w_need_close_this_bank = (r_pending) &&(bank_open[r_bank]) &&(bank_wr_ckzro[r_bank]) &&(r_row != bank_address[r_bank]) ||(pipe_stall)&&(s_pending)&&(bank_open[s_bank]) &&(s_row != bank_address[s_bank]); assign w_need_open_bank = (r_pending)&&(bank_closed[r_bank]) ||(pipe_stall)&&(s_pending)&&(bank_closed[s_bank]); always @(posedge i_clk) begin need_close_bank <= (w_need_close_this_bank) &&(!need_open_bank) &&(!need_close_bank) &&(!w_this_closing_bank); maybe_close_next_bank <= (s_pending) &&(bank_open[s_nxt_bank]) &&(bank_wr_ckzro[s_nxt_bank]) &&(s_nxt_row != bank_address[s_nxt_bank]) &&(!w_this_maybe_close)&&(!last_maybe_close); close_bank_cmd <= { `DDR_PRECHARGE, r_bank, r_row[13:11], 1'b0, r_row[9:0] }; maybe_close_cmd <= { `DDR_PRECHARGE, r_nxt_bank, r_nxt_row[13:11], 1'b0, r_nxt_row[9:0] }; need_open_bank <= (w_need_open_bank) &&(!w_this_opening_bank); last_open_bank <= (w_this_opening_bank); maybe_open_next_bank <= (s_pending) &&(!need_close_bank) &&(!need_open_bank) &&(bank_closed[s_nxt_bank]) &&(!w_this_maybe_open); // &&(!last_maybe_open); activate_bank_cmd<= { `DDR_ACTIVATE, r_bank, r_row[13:0] }; maybe_open_cmd <= { `DDR_ACTIVATE,r_nxt_bank, r_nxt_row[13:0] }; valid_bank <= ((w_r_valid)||((pipe_stall)&&(w_s_valid))) &&(!last_valid_bank)&&(!r_move) &&(!w_this_rw_move); last_valid_bank <= r_move; if ((s_pending)&&(pipe_stall)) rw_cmd[`DDR_CSBIT:`DDR_WEBIT] <= (s_we)?`DDR_WRITE:`DDR_READ; else if (r_pending) rw_cmd[`DDR_CSBIT:`DDR_WEBIT] <= (r_we)?`DDR_WRITE:`DDR_READ; else rw_cmd[`DDR_CSBIT:`DDR_WEBIT] <= `DDR_NOOP; if ((s_pending)&&(pipe_stall)) rw_cmd[`DDR_WEBIT-1:0] <= { s_bank, 3'h0, 1'b0, s_col }; else rw_cmd[`DDR_WEBIT-1:0] <= { r_bank, 3'h0, 1'b0, r_col }; if ((s_pending)&&(pipe_stall)) rw_sub <= 2'b11 - s_sub; else rw_sub <= 2'b11 - r_sub; if ((s_pending)&&(pipe_stall)) rw_we <= s_we; else rw_we <= r_we; end // // // Okay, let's look at the last assignment in our chain. It should look // something like: always @(posedge i_clk) if (i_reset) o_ddr_reset_n <= 1'b0; else if (reset_ztimer) o_ddr_reset_n <= reset_instruction[`DDR_RSTBIT]; always @(posedge i_clk) if (i_reset) o_ddr_cke <= 1'b0; else if (reset_ztimer) o_ddr_cke <= reset_instruction[`DDR_CKEBIT]; always @(posedge i_clk) if (i_reset) maintenance_override <= 1'b1; else maintenance_override <= (reset_override)||(need_refresh); initial maintenance_cmd = { `DDR_NOOP, 17'h00 }; always @(posedge i_clk) if (i_reset) maintenance_cmd <= { `DDR_NOOP, 17'h00 }; else maintenance_cmd <= (reset_override)?reset_cmd:refresh_cmd; assign w_this_closing_bank = (!maintenance_override) &&(need_close_bank); assign w_this_opening_bank = (!maintenance_override) &&(!need_close_bank)&&(need_open_bank); assign w_this_rw_move = (!maintenance_override) &&(!need_close_bank)&&(!need_open_bank) &&(valid_bank); assign w_this_maybe_close = (!maintenance_override) &&(!need_close_bank)&&(!need_open_bank) &&(!valid_bank) &&(maybe_close_next_bank); assign w_this_maybe_open = (!maintenance_override) &&(!need_close_bank)&&(!need_open_bank) &&(!valid_bank) &&(!maybe_close_next_bank) &&(maybe_open_next_bank); always @(posedge i_clk) begin last_opening_bank <= 1'b0; last_closing_bank <= 1'b0; last_maybe_open <= 1'b0; last_maybe_close <= 1'b0; r_move <= 1'b0; if (maintenance_override) // Command from either reset or cmd <= maintenance_cmd; // refresh logic else if (need_close_bank) begin cmd <= close_bank_cmd; last_closing_bank <= 1'b1; end else if (need_open_bank) begin cmd <= activate_bank_cmd; last_opening_bank <= 1'b1; end else if (valid_bank) begin cmd <= rw_cmd; r_move <= 1'b1; end else if (maybe_close_next_bank) begin cmd <= maybe_close_cmd; last_maybe_close <= 1'b1; end else if (maybe_open_next_bank) begin cmd <= maybe_open_cmd; last_maybe_open <= 1'b1; end else cmd <= { `DDR_NOOP, rw_cmd[(`DDR_WEBIT-1):0] }; end `define LGFIFOLN 4 `define FIFOLEN 16 reg [(`LGFIFOLN-1):0] bus_fifo_head, bus_fifo_tail; reg [31:0] bus_fifo_data [0:(`FIFOLEN-1)]; reg [1:0] bus_fifo_sub [0:(`FIFOLEN-1)]; reg bus_fifo_new [0:(`FIFOLEN-1)]; reg pre_ack; // The bus R/W FIFO wire w_bus_fifo_read_next_transaction; assign w_bus_fifo_read_next_transaction = (bus_ack[BUSREG]); always @(posedge i_clk) begin pre_ack <= 1'b0; o_ddr_dm <= 1'b0; if (reset_override) begin bus_fifo_head <= {(`LGFIFOLN){1'b0}}; bus_fifo_tail <= {(`LGFIFOLN){1'b0}}; o_ddr_dm <= 1'b0; end else begin if ((s_pending)&&(!pipe_stall)) bus_fifo_head <= bus_fifo_head + 1'b1; o_ddr_dm <= (bus_active[BUSREG])&&(!bus_read[BUSREG]); if (w_bus_fifo_read_next_transaction) begin bus_fifo_tail <= bus_fifo_tail + 1'b1; pre_ack <= 1'b1; o_ddr_dm <= 1'b0; end end bus_fifo_data[bus_fifo_head] <= s_data; bus_fifo_sub[bus_fifo_head] <= s_sub; bus_fifo_new[bus_fifo_head] <= w_this_rw_move; // // if ((s_pending)&&(!pipe_stall)&&(!nxt_valid)) // nxt_fifo_data <= s_data; // nxt_fifo_sub <= s_sub; // nxt_fifo_new <= w_this_rw_move; // nxt_valid <= 1'b1; // bus_fifo_head <= bus_fifo_head+1; // bus_fifo_tail <= bus_fifo_tail+1; // else if (w_bus_fifo_read_next_transaction) // nxt_fifo_data <= bus_fifo_data[bus_fifo_tail] // nxt_fifo_sub <= bus_fifo_data[bus_fifo_tail] // nxt_fifo_new <= bus_fifo_data[bus_fifo_tail] // nxt_valid <= (bus_fifo_tail+1 == bus_fifo_head); // // if ((!valid)||(w_bus_fifo_next_read_transaction)) // nxt_ <= bus_fifo_x end assign o_ddr_cs_n = cmd[`DDR_CSBIT]; assign o_ddr_ras_n = cmd[`DDR_RASBIT]; assign o_ddr_cas_n = cmd[`DDR_CASBIT]; assign o_ddr_we_n = cmd[`DDR_WEBIT]; assign o_ddr_dqs = drive_dqs; assign o_ddr_addr = cmd[(`DDR_ADDR_BITS-1):0]; assign o_ddr_ba = cmd[(`DDR_BABITS+`DDR_ADDR_BITS-1):`DDR_ADDR_BITS]; always @(posedge i_clk) o_ddr_data <= bus_fifo_data[bus_fifo_tail]; assign w_precharge_all = (cmd[`DDR_CSBIT:`DDR_WEBIT]==`DDR_PRECHARGE) &&(o_ddr_addr[10]); // 5 bits assign o_ddr_bus_oe = drive_dqs; // ~bus_read[BUSNOW]; // ODT must be in high impedence while reset_n=0, then it can be set // to low or high. As per spec, ODT = 0 during reads always @(posedge i_clk) o_ddr_odt <= (bus_active[BUSREG-3])&&(!bus_read[BUSREG-3]) ||(bus_active[BUSREG-4])&&(!bus_read[BUSREG-4]) ||((w_this_rw_move)&&(rw_we)&&(CKCAS<4)) ||(CKCAS>3)&&(bus_active[BUSREG-5])&&(!bus_read[BUSREG-5]); always @(posedge i_clk) o_wb_ack <= pre_ack; always @(posedge i_clk) o_wb_data <= i_ddr_data; endmodule
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