📄 ddr_cntl_a_controller_0.v
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//////////////////////////////////////////////////////////////////////////////
// Copyright (c) 2005 Xilinx, Inc.
// This design is confidential and proprietary of Xilinx, All Rights Reserved.
///////////////////////////////////////////////////////////////////////////////
// ____ ____
// / /\/ /
// /___/ \ / Vendor: Xilinx
// \ \ \/ Version: 1.6
// \ \ Application : MIG
// / / Filename: ddr_cntl_a_controller_0.v
// /___/ /\ Date Last Modified: Tue Jul 11 2006
// \ \ / \ Date Created: Mon May 2 2005
// \___\/\___\
// Device: Spartan-3/3e
// Design Name: DDR1_S3/S3e
// Description: Main DDR SDRAM controller block. This includes the following
// features:
// - The controller state machine that controls the
// initialization process upon power up, as well as the
// read, write and refresh commands.
// - Accepts and decodes the user commands.
// - Generates the address and Bank address signals
// - Generates control signals for other modules, including
// the control signals for the dqs_en block.
///////////////////////////////////////////////////////////////////////////////
`include "../rtl/ddr_cntl_a_parameters_0.v"
`timescale 1ns/100ps
module ddr_cntl_a_controller_0(
clk,
rst0,
rst180,
address,
bank_address,
config_register,
command_register,
burst_done,
ddr_rasb_cntrl,
ddr_casb_cntrl,
ddr_web_cntrl,
ddr_ba_cntrl,
ddr_address_cntrl,
ddr_cke_cntrl,
ddr_csb_cntrl,
dqs_enable,
dqs_reset,
write_enable,
rst_calib,
rst_dqs_div_int,
cmd_ack,
init,
ar_done,
wait_200us,
auto_ref_req
);
input clk;
input rst0;
input rst180;
input[((`row_address + `col_ap_width) -1):0] address;
input[`bank_address-1:0] bank_address;
input[9:0] config_register;
input[2:0] command_register;
input burst_done;
output ddr_rasb_cntrl;
output ddr_casb_cntrl;
output ddr_web_cntrl;
output[`bank_address-1:0] ddr_ba_cntrl;
output[`row_address-1:0] ddr_address_cntrl;
output ddr_cke_cntrl;
output ddr_csb_cntrl;
output dqs_enable;
output dqs_reset;
output write_enable;
output rst_calib;
output rst_dqs_div_int;
output cmd_ack;
output init;
output ar_done;
input wait_200us ;
output auto_ref_req;
reg [`row_address-1:0]ddr_address_cntrl;
reg [`bank_address-1:0]ddr_ba_cntrl;
parameter [3:0] IDLE = 0,
PRECHARGE = 1,
LOAD_MODE_REG = 2,
AUTO_REFRESH =3,
ACTIVE = 4,
FIRST_WRITE =5,
WRITE_WAIT = 6,
BURST_WRITE = 7,
READ_AFTER_WRITE = 8,
PRECHARGE_AFTER_WRITE = 9,
PRECHARGE_AFTER_WRITE_2 = 10,
READ_WAIT =11,
BURST_READ = 12,
BURST_STOP = 13,//D
ACTIVE_WAIT = 14;//E
reg ar_done;
reg write_enable;
reg [3:0] next_state;
reg [3:0] next_state1;
wire ack_reg;
wire ack_o;
reg [((`row_address + `col_ap_width) -1):0] address_reg;
wire [`row_address-1:0] address_config;
reg auto_ref;
wire auto_ref1;
wire AUTOREF_value;
reg AUTO_REF_detect;
reg AUTO_REF_detect1;
reg AUTO_REF_pulse_end;
reg [10:0] AUTOREF_COUNT;
wire [10:0] AUTOREF_CNT_val;
reg Auto_Ref_issued;
wire Auto_Ref_issued_p;
reg [5:0] RFC_COUNTER_value;
wire AR_done_p;
reg [`bank_address-1:0] BA_address_active;
reg BA_address_conflict;
reg [`bank_address-1:0] BA_address_reg;
reg [2:0] burst_length;
wire [2:0] burst_cnt_max;
reg [2:0] CAS_COUNT; //Modifiedd by Abhishake for BL=8
wire [2:0] cas_count_value; //Modifiedd by Abhishake for BL=8
reg [2:0] cas_latency;
reg [`row_address -1:0] column_address_reg;
reg [`row_address -1:0] column_address_reg1;
reg [`row_address -1:0] column_address_reg2;
reg [`row_address -1:0] column_address_reg3;
reg [`row_address -1:0] column_address_reg4;
reg [`row_address -1:0] column_address_reg5;
reg [`row_address -1:0] column_address_reg6;
wire[`row_address -1:0] column_address;
reg [2:0] command_reg;
reg [9:0] config_reg;
reg CONFLICT;
wire CONFLICT_value;
wire ddr_rasb1;
wire ddr_casb1;
wire ddr_web1;
reg ddr_rasb2;
reg ddr_casb2;
reg ddr_web2;
reg ddr_rasb3;
reg ddr_casb3;
reg ddr_web3;
reg ddr_rasb4;
reg ddr_casb4;
reg ddr_web4;
reg ddr_rst_dqs_rasb4;
reg ddr_rst_dqs_casb4;
reg ddr_rst_dqs_web4;
reg ddr_rasb5;
reg ddr_casb5;
reg ddr_web5;
wire[`bank_address-1:0] ddr_ba1;
reg [`bank_address-1:0] ddr_ba2;
reg [`bank_address-1:0] ddr_ba3;
reg [`bank_address-1:0] ddr_ba4;
reg [`bank_address-1:0] ddr_ba5;
wire [`row_address-1:0] ddr_address1;
reg [`row_address-1:0] ddr_address2;
reg [`row_address-1:0] ddr_address3;
reg [`row_address-1:0] ddr_address4;
reg [`row_address-1:0] ddr_address5;
wire DQS_enable_out;
wire DQS_reset_out;
wire [2:0] INIT_COUNT_value;
reg [2:0] INIT_COUNT;
wire [7:0] DLL_RST_COUNT_value;
reg [7:0] DLL_RST_COUNT;
reg INIT_DONE;
wire init_done_value;
reg init_memory;
wire init_mem;
wire initialize_memory;
wire ld_mode;
wire [1:0] MRD_COUNT_value;
reg [10:0] max_ref_cnt;
reg [1:0] MRD_COUNT;
wire PRECHARGE_CMD;
wire [3:0] ras_count_value;
reg [3:0] RAS_COUNT;
wire rdburst_chk;
wire read_cmd;
reg read_cmd1;
reg read_cmd2;
reg read_cmd3;
reg read_cmd4;
reg read_cmd5;
reg read_cmd6;
reg read_cmd7;
reg read_cmd8;
reg read_rcd_end;
reg read_cmd_reg;
wire read_write_state;
reg [1:0] RRD_COUNT;
reg [2:0] RCDR_COUNT;
reg [1:0] RCDW_COUNT;
wire [2:0] rp_cnt_value;
wire [4:0] RFC_COUNT_value;
reg RFC_COUNT_reg;
reg AR_Done_reg;
wire [1:0] RRD_COUNT_value;
wire [2:0] RCDR_COUNT_value;
wire [1:0] RCDW_COUNT_value;
wire [3:0] RC_COUNT_value;
wire [2:0] rdburst_end_cnt_value;
reg [2:0] RDBURST_END_CNT;
reg rdburst_end_1;
reg rdburst_end_2;
reg rdburst_end_3;
reg rdburst_end_4;
reg rdburst_end_5;
reg rdburst_end_6;
reg rdburst_end_7;
reg rdburst_end_8;
wire rdburst_end_r;
wire read_enable_out_r;
wire rdburst_end;
reg [2:0] RP_COUNT;
reg [3:0] RC_COUNT;
reg [4:0] RFC_COUNT;
wire read_enable_out;
wire [`row_address-1:0] ROW_ADDRESS;
reg [`row_address-1:0] row_address_reg;
reg [`row_address-1:0] row_address_active_reg;
reg row_address_conflict;
reg rst_dqs_div_r;
wire rst_dqs_div_r1;
reg dly_dqs_div_r; //Added to delay the rst_dqs_div_r by 1 clock pulse for BL = 2 .
wire [2:0] wrburst_end_cnt_value;
reg [2:0] wrburst_end_cnt;
wire wrburst_end;
reg wrburst_end_1;
reg wrburst_end_2;
reg wrburst_end_3;
reg wrburst_end_4;
reg wrburst_end_5;
reg wrburst_end_6;
reg wrburst_end_7;
reg wrburst_end_8;
reg wrburst_end_9;
wire wrburst_chk;
reg [1:0] WR_COUNT;
wire [1:0] WR_COUNT_value;
wire write_enable_out;
reg write_cmd;
wire write_cmd_in;
reg write_cmd2;
reg write_cmd3;
reg write_cmd4;
reg write_cmd5;
reg write_cmd1;
reg write_cmd6;
reg write_cmd7;
reg write_cmd8;
wire GND;
reg [2:0] dqs_div_cascount;
reg [2:0] dqs_div_rdburstcount;
wire rst_dqs_div_int;
reg DQS_enable1;
reg DQS_enable2;
reg DQS_enable3;
reg DQS_enable4;
reg DQS_reset1_clk0;
reg DQS_reset2_clk0;
reg DQS_reset3_clk0;
reg DQS_reset4_clk0;
reg DQS_enable_int;
reg DQS_reset_int;
reg rst180_r;
reg rst0_r;
wire GO_TO_ACTIVE_value;
reg GO_TO_ACTIVE;
reg rpCnt0;
reg rpCnt1;
reg mrdCnt0;
reg mrdCnt1;
reg rcdrCnt0;
reg rcdrCnt1;
reg rcdwCnt0;
reg rcdwCnt1;
reg rcCnt0;
wire accept_cmd_in;
reg ldMdReg_flag ;
reg precharge_flag;
reg aref_flag;
reg idle_flag;
reg auto_ref_wait;
reg auto_ref_wait1;
reg auto_ref_wait2;
// Input : CONFIG REGISTER FORMAT
// config_register = { EMR(Enable/Disable DLL),
// BMR (Normal operation/Normal Operation with Reset DLL),
// BMR/EMR,
// CAS_latency (3),
// Burst type ,
// Burst_length (3) }
//
// Input : COMMAND REGISTER FORMAT
// 000 - NOP
// 001 - Precharge
// 010 - Auto Refresh
// 011 - SElf REfresh
// 100 - Write Request
// 101 - Load Mode Register
// 110 - Read request
// 111 - Burst terminate
//
// Input : Address format
// row address = input address(19 downto 8)
// column addrs = input address( 7 downto 0)
assign ddr_csb_cntrl = 1'b0; // dip3;
assign ddr_cke_cntrl = ~wait_200us;
assign ROW_ADDRESS = address_reg[((`row_address + `col_ap_width )-1):`col_ap_width];
assign column_address = address_reg[`row_address -1:0];
assign init = INIT_DONE;
assign GND = 1'b0;
assign ddr_rasb_cntrl = ddr_rasb2;
assign ddr_casb_cntrl = ddr_casb2;
assign ddr_web_cntrl = ddr_web2;
assign auto_ref_req = auto_ref_wait;
always @ (negedge clk)
begin
rst180_r <= rst180;
end
always @ (posedge clk)
begin
rst0_r <= rst0;
end
//********************************************************************************************
// register input commands from the user
//
//********************************************************************************************
always @ (negedge clk) //(posedge clk180)
begin
if (rst180_r == 1'b1)
begin
config_reg <= 10'b0000000000;
command_reg <= 3'b000;
row_address_reg <= `row_address'b0;
column_address_reg <= `row_address'b0;
BA_address_reg <= `bank_address'b0;
address_reg <= `row_address + `col_ap_width'b0;
end
else
begin
config_reg <= config_register;
command_reg <= command_register;
row_address_reg <= ROW_ADDRESS;
column_address_reg <= column_address;
BA_address_reg <= bank_address;
address_reg <= address;
end
end
always @ (negedge clk) //(posedge clk180)
begin
if (rst180_r == 1'b1)
begin
burst_length <= 3'b000;
cas_latency <= 3'b000;
end
else
begin
burst_length <= config_reg[2:0];
cas_latency <= config_reg[6:4];
end
end
assign accept_cmd_in = ((next_state == IDLE ) && rpCnt0 && RFC_COUNT_reg && !auto_ref_wait);
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