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[/] [sdr_ctrl/] [trunk/] [verif/] [model/] [mt48lc4m32b2.v] - Rev 30
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////////////////////////////////////////////////////////////////////////////// // File name : mt48lc4m32b2.v ////////////////////////////////////////////////////////////////////////////// // Copyright (C) 2006 Free Model Foundry; http://www.freemodelfoundry.com // // This program is free software; you can redistribute it and/or modify // it under the terms of the GNU General Public License version 2 as // published by the Free Software Foundation. // // MODIFICATION HISTORY: // // version: | author: | mod date: | changes made: // V1.0 I.Milutinovic 06 Apr 18 Initial release // ////////////////////////////////////////////////////////////////////////////// // PART DESCRIPTION: // // Library: RAM // Technology: LVTTL // Part: MT48LC4M32B2 // // Description: 1M x 32 x 4Banks SDRAM // ////////////////////////////////////////////////////////////////////////////// // Known Bugs: // ////////////////////////////////////////////////////////////////////////////// ////////////////////////////////////////////////////////////////////////////// // MODULE DECLARATION // ////////////////////////////////////////////////////////////////////////////// `timescale 1 ns/100 ps module mt48lc4m32b2 ( A11 , A10 , A9 , A8 , A7 , A6 , A5 , A4 , A3 , A2 , A1 , A0 , DQ31 , DQ30 , DQ29 , DQ28 , DQ27 , DQ26 , DQ25 , DQ24 , DQ23 , DQ22 , DQ21 , DQ20 , DQ19 , DQ18 , DQ17 , DQ16 , DQ15 , DQ14 , DQ13 , DQ12 , DQ11 , DQ10 , DQ9 , DQ8 , DQ7 , DQ6 , DQ5 , DQ4 , DQ3 , DQ2 , DQ1 , DQ0 , BA0 , BA1 , DQM3 , DQM2 , DQM1 , DQM0 , CLK , CKE , WENeg , RASNeg , CSNeg , CASNeg ); //////////////////////////////////////////////////////////////////////// // Port / Part Pin Declarations //////////////////////////////////////////////////////////////////////// input A11 ; input A10 ; input A9 ; input A8 ; input A7 ; input A6 ; input A5 ; input A4 ; input A3 ; input A2 ; input A1 ; input A0 ; inout DQ31 ; inout DQ30 ; inout DQ29 ; inout DQ28 ; inout DQ27 ; inout DQ26 ; inout DQ25 ; inout DQ24 ; inout DQ23 ; inout DQ22 ; inout DQ21 ; inout DQ20 ; inout DQ19 ; inout DQ18 ; inout DQ17 ; inout DQ16 ; inout DQ15 ; inout DQ14 ; inout DQ13 ; inout DQ12 ; inout DQ11 ; inout DQ10 ; inout DQ9 ; inout DQ8 ; inout DQ7 ; inout DQ6 ; inout DQ5 ; inout DQ4 ; inout DQ3 ; inout DQ2 ; inout DQ1 ; inout DQ0 ; input BA0 ; input BA1 ; input DQM3 ; input DQM2 ; input DQM1 ; input DQM0 ; input CLK ; input CKE ; input WENeg ; input RASNeg ; input CSNeg ; input CASNeg ; // interconnect path delay signals wire A11_ipd ; wire A10_ipd ; wire A9_ipd ; wire A8_ipd ; wire A7_ipd ; wire A6_ipd ; wire A5_ipd ; wire A4_ipd ; wire A3_ipd ; wire A2_ipd ; wire A1_ipd ; wire A0_ipd ; wire [11 : 0] A; assign A = {A11_ipd, A10_ipd, A9_ipd, A8_ipd, A7_ipd, A6_ipd, A5_ipd, A4_ipd, A3_ipd, A2_ipd, A1_ipd, A0_ipd }; wire DQ31_ipd ; wire DQ30_ipd ; wire DQ29_ipd ; wire DQ28_ipd ; wire DQ27_ipd ; wire DQ26_ipd ; wire DQ25_ipd ; wire DQ24_ipd ; wire DQ23_ipd ; wire DQ22_ipd ; wire DQ21_ipd ; wire DQ20_ipd ; wire DQ19_ipd ; wire DQ18_ipd ; wire DQ17_ipd ; wire DQ16_ipd ; wire DQ15_ipd ; wire DQ14_ipd ; wire DQ13_ipd ; wire DQ12_ipd ; wire DQ11_ipd ; wire DQ10_ipd ; wire DQ9_ipd ; wire DQ8_ipd ; wire DQ7_ipd ; wire DQ6_ipd ; wire DQ5_ipd ; wire DQ4_ipd ; wire DQ3_ipd ; wire DQ2_ipd ; wire DQ1_ipd ; wire DQ0_ipd ; wire [31 : 0 ] DQIn; assign DQIn = { DQ31_ipd, DQ30_ipd, DQ29_ipd, DQ28_ipd, DQ27_ipd, DQ26_ipd, DQ25_ipd, DQ24_ipd, DQ23_ipd, DQ22_ipd, DQ21_ipd, DQ20_ipd, DQ19_ipd, DQ18_ipd, DQ17_ipd, DQ16_ipd, DQ15_ipd, DQ14_ipd, DQ13_ipd, DQ12_ipd, DQ11_ipd, DQ10_ipd, DQ9_ipd, DQ8_ipd, DQ7_ipd, DQ6_ipd, DQ5_ipd, DQ4_ipd, DQ3_ipd, DQ2_ipd, DQ1_ipd, DQ0_ipd }; wire [31 : 0] DQOut; assign DQOut = { DQ31, DQ30, DQ29, DQ28, DQ27, DQ26, DQ25, DQ24, DQ23, DQ22, DQ21, DQ20, DQ19, DQ18, DQ17, DQ16, DQ15, DQ14, DQ13, DQ12, DQ11, DQ10, DQ9, DQ8, DQ7, DQ6, DQ5, DQ4, DQ3, DQ2, DQ1, DQ0 }; wire BA0_ipd ; wire BA1_ipd ; wire DQM3_ipd ; wire DQM2_ipd ; wire DQM1_ipd ; wire DQM0_ipd ; wire CLK_ipd ; wire CKE_ipd ; wire WENeg_ipd ; wire RASNeg_ipd ; wire CSNeg_ipd ; wire CASNeg_ipd ; integer bank; integer bank_tmp; // internal delays reg rct_in ; reg rct_out; reg [3:0] rcdt_in ; reg [3:0] rcdt_out; reg pre_in ; reg pre_out ; reg refreshed_in ; reg refreshed_out ; reg rcar_out ; reg rcar_in ; reg wrt_in ; reg wrt_out ; reg [3:0] ras_in = 1'b0; reg [3:0] ras_out = 1'b0; reg [31 : 0] DQ_zd = 32'bz; assign {DQ31_zd, DQ30_zd, DQ29_zd, DQ28_zd, DQ27_zd, DQ26_zd, DQ25_zd, DQ24_zd, DQ23_zd, DQ22_zd, DQ21_zd, DQ20_zd, DQ19_zd, DQ18_zd, DQ17_zd, DQ16_zd, DQ15_zd, DQ14_zd, DQ13_zd, DQ12_zd, DQ11_zd, DQ10_zd, DQ9_zd, DQ8_zd, DQ7_zd, DQ6_zd, DQ5_zd, DQ4_zd, DQ3_zd, DQ2_zd, DQ1_zd, DQ0_zd } = DQ_zd; parameter UserPreload = 1'b1; parameter mem_file_name = "none"; //"mt48lc4m32b2.mem"; parameter TimingModel = "DefaultTimingModel"; parameter PartID = "mt48lc4m32b2"; parameter hi_bank = 3; parameter depth = 25'h100000; reg PoweredUp = 1'b0; reg CKEreg = 1'b0; reg CAS_Lat ; reg CAS_Lat2; reg [31:0] DataDrive = 32'bz ; // Memory array declaration integer Mem [0:(hi_bank+1)*depth*4-1]; // Type definition for state machine parameter pwron = 5'd0; parameter precharge = 5'd1; parameter idle = 5'd2; parameter mode_set = 5'd3; parameter self_refresh = 5'd4; parameter auto_refresh = 5'd5; parameter pwrdwn = 5'd6; parameter bank_act = 5'd7; parameter bank_act_pwrdwn = 5'd8; parameter write = 5'd9; parameter write_suspend = 5'd10; parameter read = 5'd11; parameter read_suspend = 5'd12; parameter write_auto_pre = 5'd13; parameter read_auto_pre = 5'd14; reg [4:0] statebank [hi_bank:0]; // Type definition for commands parameter desl = 4'd0; parameter nop = 4'd1; parameter bst = 4'd2; parameter rd = 4'd3; parameter writ = 4'd4; parameter act = 4'd5; parameter pre = 4'd6; parameter mrs = 4'd7; parameter ref = 4'd8; reg [3:0] command = desl; // burst type parameter sequential = 1'b0; parameter interleave = 1'b1; reg Burst ; // write burst mode parameter programmed = 1'b0; parameter single = 1'b1; reg WB ; //burst sequences integer intab [0:63]; reg [19:0] MemAddr [hi_bank:0]; integer BurstCnt [hi_bank:0]; integer StartAddr [hi_bank:0]; integer BurstInc [hi_bank:0]; integer BaseLoc [hi_bank:0]; integer Loc; integer BurstLen; integer Burst_Bits; reg written = 1'b0; reg chip_en = 1'b0; integer cur_bank; reg [11:0] ModeReg ; integer Ref_Cnt = 0; time Next_Ref = 0; reg [8*8:1] BankString ; reg Viol = 1'b0; reg [31:0] DataDriveOut = 32'bz; reg [31:0] DataDrive1 = 32'bz; reg [31:0] DataDrive2 = 32'bz; reg [31:0] DataDrive3 = 32'bz; reg DQM0_reg0 ; reg DQM0_reg1 ; reg DQM0_reg2 ; reg DQM1_reg0 ; reg DQM1_reg1 ; reg DQM1_reg2 ; reg DQM2_reg0 ; reg DQM2_reg1 ; reg DQM2_reg2 ; reg DQM3_reg0 ; reg DQM3_reg1 ; reg DQM3_reg2 ; // tdevice values: values for internal delays time tdevice_TRC = 0; time tdevice_TRCAR = 0; time tdevice_TRCD = 0; time tdevice_TRP = 0; time tdevice_TWR = 0; /////////////////////////////////////////////////////////////////////////// //Interconnect Path Delay Section /////////////////////////////////////////////////////////////////////////// buf (A11_ipd, A11); buf (A10_ipd, A10); buf (A9_ipd , A9 ); buf (A8_ipd , A8 ); buf (A7_ipd , A7 ); buf (A6_ipd , A6 ); buf (A5_ipd , A5 ); buf (A4_ipd , A4 ); buf (A3_ipd , A3 ); buf (A2_ipd , A2 ); buf (A1_ipd , A1 ); buf (A0_ipd , A0 ); buf (DQ31_ipd , DQ31 ); buf (DQ30_ipd , DQ30 ); buf (DQ29_ipd , DQ29 ); buf (DQ28_ipd , DQ28 ); buf (DQ27_ipd , DQ27 ); buf (DQ26_ipd , DQ26 ); buf (DQ25_ipd , DQ25 ); buf (DQ24_ipd , DQ24 ); buf (DQ23_ipd , DQ23 ); buf (DQ22_ipd , DQ22 ); buf (DQ21_ipd , DQ21 ); buf (DQ20_ipd , DQ20 ); buf (DQ19_ipd , DQ19 ); buf (DQ18_ipd , DQ18 ); buf (DQ17_ipd , DQ17 ); buf (DQ16_ipd , DQ16 ); buf (DQ15_ipd , DQ15 ); buf (DQ14_ipd , DQ14 ); buf (DQ13_ipd , DQ13 ); buf (DQ12_ipd , DQ12 ); buf (DQ11_ipd , DQ11 ); buf (DQ10_ipd , DQ10 ); buf (DQ9_ipd , DQ9 ); buf (DQ8_ipd , DQ8 ); buf (DQ7_ipd , DQ7 ); buf (DQ6_ipd , DQ6 ); buf (DQ5_ipd , DQ5 ); buf (DQ4_ipd , DQ4 ); buf (DQ3_ipd , DQ3 ); buf (DQ2_ipd , DQ2 ); buf (DQ1_ipd , DQ1 ); buf (DQ0_ipd , DQ0 ); buf (CASNeg_ipd, CASNeg); buf (RASNeg_ipd, RASNeg); buf (BA0_ipd , BA0 ); buf (BA1_ipd , BA1 ); buf (DQM0_ipd , DQM0 ); buf (DQM1_ipd , DQM1 ); buf (DQM2_ipd , DQM2 ); buf (DQM3_ipd , DQM3 ); buf (CLK_ipd , CLK ); buf (CKE_ipd , CKE ); buf (WENeg_ipd , WENeg ); buf (CSNeg_ipd , CSNeg ); /////////////////////////////////////////////////////////////////////////// // Propagation delay Section /////////////////////////////////////////////////////////////////////////// nmos (DQ31 , DQ31_zd , 1); nmos (DQ30 , DQ30_zd , 1); nmos (DQ29 , DQ29_zd , 1); nmos (DQ28 , DQ28_zd , 1); nmos (DQ27 , DQ27_zd , 1); nmos (DQ26 , DQ26_zd , 1); nmos (DQ25 , DQ25_zd , 1); nmos (DQ24 , DQ24_zd , 1); nmos (DQ23 , DQ23_zd , 1); nmos (DQ22 , DQ22_zd , 1); nmos (DQ21 , DQ21_zd , 1); nmos (DQ20 , DQ20_zd , 1); nmos (DQ19 , DQ19_zd , 1); nmos (DQ18 , DQ18_zd , 1); nmos (DQ17 , DQ17_zd , 1); nmos (DQ16 , DQ16_zd , 1); nmos (DQ15 , DQ15_zd , 1); nmos (DQ14 , DQ14_zd , 1); nmos (DQ13 , DQ13_zd , 1); nmos (DQ12 , DQ12_zd , 1); nmos (DQ11 , DQ11_zd , 1); nmos (DQ10 , DQ10_zd , 1); nmos (DQ9 , DQ9_zd , 1); nmos (DQ8 , DQ8_zd , 1); nmos (DQ7 , DQ7_zd , 1); nmos (DQ6 , DQ6_zd , 1); nmos (DQ5 , DQ5_zd , 1); nmos (DQ4 , DQ4_zd , 1); nmos (DQ3 , DQ3_zd , 1); nmos (DQ2 , DQ2_zd , 1); nmos (DQ1 , DQ1_zd , 1); nmos (DQ0 , DQ0_zd , 1); wire deg; wire chip_act; assign chip_act = chip_en; wire chip_act_deg; assign chip_act_deg = chip_act && deg; wire cas_latency1; wire cas_latency2; wire cas_latency3; assign cas_latency1 = CAS_Lat && ~CAS_Lat2; assign cas_latency2 = ~CAS_Lat && CAS_Lat2; assign cas_latency3 = CAS_Lat && CAS_Lat2; specify // tipd delays: interconnect path delays, mapped to input port delays. // In Verilog it is not necessary to declare any tipd delay variables, // they can be taken from SDF file // With all the other delays real delays would be taken from SDF file // tpd delays specparam tpd_CLK_DQ1 = 1; specparam tpd_CLK_DQ2 = 1; specparam tpd_CLK_DQ3 = 1; // tpw values: pulse widths specparam tpw_CLK_posedge = 1; specparam tpw_CLK_negedge = 1; // tsetup values: setup times specparam tsetup_DQ0_CLK = 1; // tDS // thold values: hold times specparam thold_DQ0_CLK = 1; // tDH // tperiod_min: minimum clock period = 1/max freq specparam tperiod_CLK_cl0_eq_1_posedge = 1; //tCK specparam tperiod_CLK_cl1_eq_1_posedge = 1; specparam tperiod_CLK_cl2_eq_1_posedge = 1; // tdevice values: values for internal delays specparam tdevice_REF = 15625 ; specparam tdevice_TRASmin = 42; specparam tdevice_TRASmax = 120000; /////////////////////////////////////////////////////////////////////// // Input Port Delays don't require Verilog description /////////////////////////////////////////////////////////////////////// // Path delays // /////////////////////////////////////////////////////////////////////// if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ0) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ1) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ2) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ3) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ4) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ5) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ6) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ7) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ8) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ9) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ10) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ11) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ12) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ13) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ14) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ15) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ16) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ17) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ18) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ19) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ20) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ21) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ22) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ23) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ24) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ25) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ26) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ27) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ28) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ29) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ30) = tpd_CLK_DQ1; if (CAS_Lat && ~CAS_Lat2) (CLK *> DQ31) = tpd_CLK_DQ1; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ0) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ1) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ2) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ3) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ4) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ5) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ6) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ7) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ8) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ9) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ10) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ11) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ12) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ13) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ14) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ15) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ16) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ17) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ18) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ19) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ20) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ21) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ22) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ23) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ24) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ25) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ26) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ27) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ28) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ29) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ30) = tpd_CLK_DQ2; if (~CAS_Lat && CAS_Lat2) (CLK *> DQ31) = tpd_CLK_DQ2; if (CAS_Lat && CAS_Lat2) (CLK *> DQ0) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ1) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ2) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ3) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ4) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ5) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ6) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ7) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ8) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ9) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ10) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ11) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ12) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ13) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ14) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ15) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ16) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ17) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ18) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ19) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ20) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ21) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ22) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ23) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ24) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ25) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ26) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ27) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ28) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ29) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ30) = tpd_CLK_DQ3; if (CAS_Lat && CAS_Lat2) (CLK *> DQ31) = tpd_CLK_DQ3; //////////////////////////////////////////////////////////////////////// // Timing Check Section //////////////////////////////////////////////////////////////////////// $setup (BA0 , posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (BA1 , posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQM0, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQM1, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQM2, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQM3, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (CKE , posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (WENeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (CSNeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (CASNeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (RASNeg, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (DQ0 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ1 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ2 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ3 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ4 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ5 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ6 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ7 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ8 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ9 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ10 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ11 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ12 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ13 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ14 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ15 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ16 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ17 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ18 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ19 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ20 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ21 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ22 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ23 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ24 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ25 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ26 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ27 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ28 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ29 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ30 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (DQ31 ,posedge CLK &&& chip_act_deg, tsetup_DQ0_CLK, Viol); $setup (A0, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A1, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A2, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A3, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A4, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A5, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A6, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A7, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A8, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A9, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A10, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $setup (A11, posedge CLK &&& chip_act, tsetup_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, BA0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, BA1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, DQM0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, DQM1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, DQM2, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, DQM3, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, CKE , thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, CASNeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, RASNeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, WENeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, CSNeg, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A2, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A3, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A4, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A5, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A6, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A7, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A8, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A9, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A10, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act, A11, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ0, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ1, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ2, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ3, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ4, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ5, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ6, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ7, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ8, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ9, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ10, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ11, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ12, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ13, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ14, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ15, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ16, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ17, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ18, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ19, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ20, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ21, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ22, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ23, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ24, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ25, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ26, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ27, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ28, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ29, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ30, thold_DQ0_CLK, Viol); $hold (posedge CLK &&& chip_act_deg, DQ31, thold_DQ0_CLK, Viol); $width (posedge CLK &&& chip_act, tpw_CLK_posedge); $width (negedge CLK &&& chip_act, tpw_CLK_negedge); $period (posedge CLK &&& cas_latency1, tperiod_CLK_cl0_eq_1_posedge); $period (posedge CLK &&& cas_latency2, tperiod_CLK_cl1_eq_1_posedge); $period (posedge CLK &&& cas_latency3, tperiod_CLK_cl2_eq_1_posedge); endspecify task generate_out ; output [31:0] DataDrive; input Bank; integer Bank; integer location; begin location = Bank * depth * 4 + Loc; DataDrive[7:0] = 8'bx; if (Mem[location] > -1) DataDrive[7:0] = Mem[location]; DataDrive[15:8] = 8'bx; if (Mem[location+1] > -1) DataDrive[15:8] = Mem[location+1]; DataDrive[23:16] = 8'bx; if (Mem[location+2] > -1) DataDrive[23:16] = Mem[location+2]; DataDrive[31:24] = 8'bx; if (Mem[location+3] > -1) DataDrive[31:24] = Mem[location+3]; end endtask task MemWrite; input Bank; integer Bank; integer location; begin location = Bank * depth * 4 + Loc; if (~DQM0_ipd) begin Mem[location] = -1; if (~Viol) Mem[location] = DQIn[7:0]; end if (~DQM1_ipd) begin Mem[location+1] = -1; if (~Viol) Mem[location+1] = DQIn[15:8]; end if (~DQM2_ipd) begin Mem[location+2] = -1; if (~Viol) Mem[location+2] = DQIn[23:16]; end if (~DQM3_ipd) begin Mem[location+3] = -1; if (~Viol) Mem[location+3] = DQIn[31:24]; end end endtask task BurstIncProc; input Bank; integer Bank; begin BurstInc[Bank] = 0; if (Burst_Bits == 1) BurstInc[Bank] = A[0:0]; if (Burst_Bits == 2) BurstInc[Bank] = A[1:0]; if (Burst_Bits == 3) BurstInc[Bank] = A[2:0]; if (Burst_Bits == 7) BurstInc[Bank] = A[6:0]; end endtask task NextStateAuto; input Bank; input state; integer Bank; reg [4:0] state; begin if (~A[10]) statebank[Bank] = state; else if (A[10]) if (state == write) statebank[Bank] = write_auto_pre; else statebank[Bank] = read_auto_pre; end endtask ////////////////////////////////////////////////////////////////////////// // Main Behavior Block // ////////////////////////////////////////////////////////////////////////// // chech when data is generated from model to avoid setup/hold check in // those occasion reg deq; always @(DQIn, DQOut) begin if (DQIn==DQOut) deq=1'b1; else deq=1'b0; end assign deg=deq; // initialize burst sequences initial begin intab[0] = 0; intab[1] = 1; intab[2] = 2; intab[3] = 3; intab[4] = 4; intab[5] = 5; intab[6] = 6; intab[7] = 7; intab[8] = 1; intab[9] = 0; intab[10] = 3; intab[11] = 2; intab[12] = 5; intab[13] = 4; intab[14] = 7; intab[15] = 6; intab[16] = 2; intab[17] = 3; intab[18] = 0; intab[19] = 1; intab[20] = 6; intab[21] = 7; intab[22] = 4; intab[23] = 5; intab[24] = 3; intab[25] = 2; intab[26] = 1; intab[27] = 0; intab[28] = 7; intab[29] = 6; intab[30] = 5; intab[31] = 4; intab[32] = 4; intab[33] = 5; intab[34] = 6; intab[35] = 7; intab[36] = 0; intab[37] = 1; intab[38] = 2; intab[39] = 3; intab[40] = 5; intab[41] = 4; intab[42] = 7; intab[43] = 6; intab[44] = 1; intab[45] = 0; intab[46] = 3; intab[47] = 2; intab[48] = 6; intab[49] = 7; intab[50] = 4; intab[51] = 5; intab[52] = 2; intab[53] = 3; intab[54] = 0; intab[55] = 1; intab[56] = 7; intab[57] = 6; intab[58] = 5; intab[59] = 4; intab[60] = 3; intab[61] = 2; intab[62] = 1; intab[63] = 0; end // initialize memory and load preload files if any initial begin: InitMemory integer i; for (i=0; i<=((hi_bank+1)*depth*4 - 1); i=i+1) begin Mem[i] = -1; end // Memory preload file // mt48lc4m32b2.mem file // @bbbbbb - <bbbbbb> stands for address within memory, // dd - <dd> is word to be written at Mem(bbbbbb++) // (bbbbbb is incremented at every load) if (UserPreload && !(mem_file_name == "none")) $readmemh(mem_file_name,Mem); end //Power Up time 100 us; initial begin PoweredUp = 1'b0; statebank[0] = pwron; statebank[1] = pwron; statebank[2] = pwron; statebank[3] = pwron; #100000 PoweredUp = 1'b1; end always @(posedge wrt_in) begin:TWRrise #tdevice_TWR wrt_out = wrt_in; end always @(negedge wrt_in) begin:TWRfall #1 wrt_out = wrt_in; end always @(posedge ras_in[0]) begin:TRASrise0 ras_out[0] <= #tdevice_TRASmin ras_in[0]; end always @(negedge ras_in[0]) begin:TRASfall0 ras_out[0] <= #tdevice_TRASmax ras_in[0]; end always @(posedge ras_in[1]) begin:TRASrise1 ras_out[1] <= #tdevice_TRASmin ras_in[1]; end always @(negedge ras_in[1]) begin:TRASfall1 ras_out[1] <= #tdevice_TRASmax ras_in[1]; end always @(posedge ras_in[2]) begin:TRASrise2 ras_out[2] <= #tdevice_TRASmin ras_in[2]; end always @(negedge ras_in[2]) begin:TRASfall2 ras_out[2] <= #tdevice_TRASmax ras_in[2]; end always @(posedge ras_in[3]) begin:TRASrise3 ras_out[3] <= #tdevice_TRASmin ras_in[3]; end always @(negedge ras_in[3]) begin:TRASfall3 ras_out[3] <= #tdevice_TRASmax ras_in[3]; end always @(posedge rcdt_in[0]) begin:TRCDrise0 rcdt_out[0] <= #5 1'b1; end always @(negedge rcdt_in[0]) begin:TRCDfall0 rcdt_out[0] <= #tdevice_TRCD 1'b0; end always @(posedge rcdt_in[1]) begin:TRCDrise1 rcdt_out[1] <= #5 1'b1; end always @(negedge rcdt_in[1]) begin:TRCDfall1 rcdt_out[1] <= #tdevice_TRCD 1'b0; end always @(posedge rcdt_in[2]) begin:TRCDrise2 rcdt_out[2] <= #5 1'b1; end always @(negedge rcdt_in[2]) begin:TRCDfall2 rcdt_out[2] <= #tdevice_TRCD 1'b0; end always @(posedge rcdt_in[3]) begin:TRCDrise3 rcdt_out[3] <= #5 1'b1; end always @(negedge rcdt_in[3]) begin:TRCDfall3 rcdt_out[3] <= #tdevice_TRCD 1'b0; end ///////////////////////////////////////////////////////////////////////// // Functional Section ///////////////////////////////////////////////////////////////////////// always @(posedge CLK) begin if ($time > Next_Ref && PoweredUp && Ref_Cnt > 0) begin Ref_Cnt = Ref_Cnt - 1; Next_Ref = $time + tdevice_REF; end if (CKEreg) begin if (~CSNeg_ipd) chip_en = 1; else chip_en = 0; end if (CKEreg && ~CSNeg_ipd) begin if (DQM0_ipd == 1'bx) $display(" Unusable value for DQM0 "); if (DQM1_ipd == 1'bx) $display(" Unusable value for DQM1 "); if (DQM2_ipd == 1'bx) $display(" Unusable value for DQM2 "); if (DQM3_ipd == 1'bx) $display(" Unusable value for DQM3 "); if (WENeg_ipd == 1'bx) $display(" Unusable value for WENeg "); if (RASNeg_ipd == 1'bx) $display(" Unusable value for RASNeg "); if (CASNeg_ipd == 1'bx) $display(" Unusable value for CASNeg "); // Command Decode if (RASNeg_ipd && CASNeg_ipd && WENeg_ipd) command = nop; else if (~RASNeg_ipd && CASNeg_ipd && WENeg_ipd) command = act; else if (RASNeg_ipd && ~CASNeg_ipd && WENeg_ipd) command = rd; else if (RASNeg_ipd && ~CASNeg_ipd && ~WENeg_ipd) command = writ; else if (RASNeg_ipd && CASNeg_ipd && ~WENeg_ipd) command = bst; else if (~RASNeg_ipd && CASNeg_ipd && ~WENeg_ipd) command = pre; else if (~RASNeg_ipd && ~CASNeg_ipd && WENeg_ipd) command = ref; else if (~RASNeg_ipd && ~CASNeg_ipd && ~WENeg_ipd) command = mrs; // PowerUp Check if (~(PoweredUp) && command != nop) begin $display (" Incorrect power up. Command issued before "); $display (" power up complete. "); end // Bank Decode if (~BA0_ipd && ~BA1_ipd) cur_bank = 0; else if (BA0_ipd && ~BA1_ipd) cur_bank = 1; else if (~BA0_ipd && BA1_ipd) cur_bank = 2; else if (BA0_ipd && BA1_ipd) cur_bank = 3; else begin $display ("Could not decode bank selection - results"); $display ("may be incorrect."); end end // The Big State Machine if (CKEreg) begin if (CSNeg_ipd == 1'bx) $display ("Unusable value for CSNeg"); if (CSNeg_ipd) command = nop; // DQM pipeline DQM0_reg2 = DQM0_reg1; DQM0_reg1 = DQM0_reg0; DQM0_reg0 = DQM0_ipd; DQM1_reg2 = DQM1_reg1; DQM1_reg1 = DQM1_reg0; DQM1_reg0 = DQM1_ipd; DQM2_reg2 = DQM2_reg1; DQM2_reg1 = DQM2_reg0; DQM2_reg0 = DQM2_ipd; DQM3_reg2 = DQM3_reg1; DQM3_reg1 = DQM3_reg0; DQM3_reg0 = DQM3_ipd; // by default data drive is Z, might get over written in one // of the passes below DataDrive = 32'bz; for (bank = 0; bank <= hi_bank; bank = bank + 1) begin case (statebank[bank]) pwron : begin if (~DQM0_ipd) begin $display ("DQM0 must be held high during"); $display ("initialization."); end if (~DQM1_ipd) begin $display ("DQM1 must be held high during"); $display ("initialization."); end if (~DQM2_ipd) begin $display ("DQM2 must be held high during"); $display ("initialization."); end if (~DQM3_ipd) begin $display ("DQM3 must be held high during"); $display ("initialization."); end if (~PoweredUp) begin if (command != nop) $display ("Only NOPs allowed during power up."); DataDrive = 32'bz; end else if (command == pre && (cur_bank == bank || A[10])) begin statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end end precharge : begin if (cur_bank == bank) // It is only an error if this bank is selected if (command != nop && command != pre) begin $display ("Illegal command received "); $display ("during precharge.",$time); end end idle : begin if (command == nop || command == bst || command == pre || cur_bank != bank) begin end else if (command == mrs) begin if (statebank[0] == idle && statebank[1] == idle && statebank[2] == idle && statebank[3] == idle) begin ModeReg = A; statebank[bank] = mode_set; end end else if (command == ref) begin if (statebank[0] == idle && statebank[1] == idle && statebank[2] == idle && statebank[3] == idle) if (CKE) begin statebank[bank] = auto_refresh; statebank[bank] <= #tdevice_TRCAR idle; end else begin statebank[0] = self_refresh; statebank[1] = self_refresh; statebank[2] = self_refresh; statebank[3] = self_refresh; end end else if (command == act) begin statebank[bank] = bank_act; ras_in[bank] = 1'b1; ras_in [bank] <= #70 1'b0; rct_in = 1'b1; rct_in <= #1 1'b0; rcdt_in[bank] = 1'b1; rcdt_in[bank] <= #1 1'b0; MemAddr[bank][19:8] = A; // latch row addr end else $display ("Illegal command received in idle state.",$time); end mode_set : begin if (ModeReg[7] != 0 || ModeReg[8] != 0) $display ("Illegal operating mode set."); if (command != nop) begin $display ("Illegal command received during mode"); $display ("set.",$time); end // read burst length if (ModeReg[2:0] == 3'b000) begin BurstLen = 1; Burst_Bits = 0; end else if (ModeReg[2:0] == 3'b001) begin BurstLen = 2; Burst_Bits = 1; end else if (ModeReg[2:0] == 3'b010) begin BurstLen = 4; Burst_Bits = 2; end else if (ModeReg[2:0] == 3'b011) begin BurstLen = 8; Burst_Bits = 3; end else if (ModeReg[2:0] == 3'b111) begin BurstLen = 256; Burst_Bits = 7; end else $display ("Invalid burst length specified."); // read burst type if (~ModeReg[3]) Burst = sequential; else if (ModeReg[3]) Burst = interleave; else $display ("Invalid burst type specified."); // read CAS latency if (ModeReg[6:4] == 3'b001) begin CAS_Lat = 1'b1; CAS_Lat2 = 1'b0; end else if (ModeReg[6:4] == 3'b010) begin CAS_Lat = 1'b0; CAS_Lat2 = 1'b1; end else if (ModeReg[6:4] == 3'b011) begin CAS_Lat = 1'b1; CAS_Lat2 = 1'b1; end else $display ("CAS Latency set incorrecty"); // write burst mode if (~ModeReg[9]) WB = programmed; else if (ModeReg[9]) WB = single; else $display ("Invalid burst type specified."); statebank[bank] = idle; end auto_refresh : begin if (Ref_Cnt < 4096) Ref_Cnt = Ref_Cnt + 1; if (command != nop) begin $display ("Illegal command received during"); $display ("auto_refresh.",$time); end end bank_act : begin if (command == pre && (cur_bank == bank || A[10])) begin if (~ras_out[bank]) begin $display ("precharge command does not meet tRAS"); $display ("time", $time); end statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else if (command == nop || command == bst || cur_bank != bank) begin end else if (command == rd) begin if (rcdt_out[bank]) begin $display ("read command received too soon"); $display ("after active",$time); end if (A[10] == 1'bx) begin $display ("A(10) = X during read command."); $display ("Next state unknown."); end MemAddr[bank][7:0] = 8'b0;// clr old addr // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; BurstIncProc(bank); StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive,bank); BurstCnt[bank] = 1; NextStateAuto(bank, read); bank_tmp = bank; end else if (command == writ) begin if (rcdt_out[bank]) begin $display ("write command received too soon"); $display ("after active",$time); end if (A[10] == 1'bx) begin $display ("A(10) = X during write command."); $display ("Next state unknown."); end MemAddr[bank][7:0] = 8'b0; // clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = 1'b1; wrt_in = 1'b1; NextStateAuto(bank, write); written = 1'b1; end else if (cur_bank == bank || command == mrs) begin $display ("Illegal command received in"); $display ("active state",$time); end end write : begin if (command == bst) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; end else if (command == rd) if (cur_bank == bank) begin MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank, read); end else statebank[bank] = bank_act; else if (command == writ) if (cur_bank == bank) begin MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = 1'b1; wrt_in = 1'b1; if (A[10]) statebank[bank] = write_auto_pre; end else statebank[bank] = bank_act; else if (command == pre && (cur_bank == bank || A[10])) begin if (~ras_out[bank]) begin $display ("precharge command does not meet tRAS time",$time); end if (~DQM0_ipd) begin $display ("DQM0 should be held high, data is"); $display ("lost.",$time); end if (~DQM1_ipd) begin $display ("DQM1 should be held high, data is"); $display ("lost.",$time); end if (~DQM2_ipd) begin $display ("DQM2 should be held high, data is"); $display ("lost.",$time); end if (~DQM2_ipd) begin $display ("DQM2 should be held high, data is"); $display ("lost.",$time); end wrt_in = 1'b0; statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else if (command == nop || cur_bank != bank) if (BurstCnt[bank] == BurstLen || WB == single) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]*8 + BurstCnt[bank]]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = BurstCnt[bank] + 1; wrt_in = 1'b1; end else if (cur_bank == bank) $display ("Illegal command received in write state",$time); end read : begin if (command == bst) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; end else if (command == rd) if (cur_bank == bank) begin MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = 1'b1; NextStateAuto(bank, read); end else statebank[bank] = bank_act; else if (command == writ) if (cur_bank == bank) begin if (rcdt_out[bank]) begin $display ("write command received too soon after active",$time); end if (A[10] == 1'bx) begin $display ("A(10) = X during write command."); $display ("Next state unknown."); end MemAddr[bank][7:0] = 8'b0;// clr old addr BurstIncProc(bank); // latch col addr if (Burst_Bits == 0) MemAddr[bank][7:0] = A[7:0]; if (Burst_Bits == 1) MemAddr[bank][7:1] = A[7:1]; if (Burst_Bits == 2) MemAddr[bank][7:2] = A[7:2]; if (Burst_Bits == 3) MemAddr[bank][7:3] = A[7:3]; if (Burst_Bits == 7) MemAddr[bank][7:7] = A[7:7]; StartAddr[bank] = BurstInc[bank] % 8; BaseLoc[bank] = MemAddr[bank]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = 1'b1; wrt_in = 1'b1; NextStateAuto(bank,write); end else statebank[bank] = bank_act; else if (command == pre && (cur_bank == bank || A[10])) begin if (~ras_out[bank]) begin $display ("Precharge command does not meet tRAS time",$time); end statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else if (command == nop || cur_bank != bank) begin if (BurstCnt[bank] == BurstLen) begin statebank[bank] = bank_act; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]*8 + BurstCnt[bank]]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = BurstCnt[bank] + 1; end end else if (cur_bank == bank) $display ("Illegal command received in read state",$time); end write_auto_pre : begin if (command == nop || cur_bank != bank) if (BurstCnt[bank] == BurstLen || WB == single) begin statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]*8 + BurstCnt[bank]]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); MemWrite(bank); BurstCnt[bank] = BurstCnt[bank] + 1; wrt_in = 1'b1; end else $display ("Illegal command received in write state.",$time); end read_auto_pre : begin if (command == nop || (cur_bank != bank && command != rd && command != writ)) if (BurstCnt[bank] == BurstLen) begin statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; BurstCnt[bank] = 1'b0; ras_in[bank] = 1'b1; end else begin if (Burst == sequential) BurstInc[bank] = (BurstInc[bank]+1) % BurstLen; else BurstInc[bank] = intab[StartAddr[bank]*8 + BurstCnt[bank]]; Loc = 4*(BaseLoc[bank] + BurstInc[bank]); generate_out(DataDrive, bank); BurstCnt[bank] = BurstCnt[bank] + 1; end else if ((command == rd || command == writ) && cur_bank != bank) begin statebank[bank] = precharge; statebank[bank] <= #tdevice_TRP idle; end else $display ("Illegal command received in read state",$time); end endcase end // Check Refresh Status if (written && (Ref_Cnt == 0)) $display ("memory not refreshed (by ref_cnt)", $time); DataDrive3 = DataDrive2; DataDrive2 = DataDrive1; DataDrive1 = DataDrive; end // Latency adjustments and DQM read masking if (~DQM0_reg1) if (CAS_Lat && CAS_Lat2) DataDriveOut[7:0] = DataDrive3[7:0]; else if (~CAS_Lat && CAS_Lat2) DataDriveOut[7:0] = DataDrive2[7:0]; else DataDriveOut[7:0] = DataDrive1[7:0]; else DataDriveOut[7:0] = 8'bz; if (~DQM1_reg1) if (CAS_Lat && CAS_Lat2) DataDriveOut[15:8] = DataDrive3[15:8]; else if (~CAS_Lat && CAS_Lat2) DataDriveOut[15:8] = DataDrive2[15:8]; else DataDriveOut[15:8] = DataDrive1[15:8]; else DataDriveOut[15:8] = 8'bz; if (~DQM2_reg1) if (CAS_Lat && CAS_Lat2) DataDriveOut[23:16] = DataDrive3[23:16]; else if (~CAS_Lat && CAS_Lat2) DataDriveOut[23:16] = DataDrive2[23:16]; else DataDriveOut[23:16] = DataDrive1[23:16]; else DataDriveOut[23:16] = 8'bz; if (~DQM3_reg1) if (CAS_Lat && CAS_Lat2) DataDriveOut[31:24] = DataDrive3[31:24]; else if (~CAS_Lat && CAS_Lat2) DataDriveOut[31:24] = DataDrive2[31:24]; else DataDriveOut[31:24] = DataDrive1[31:24]; else DataDriveOut[31:24] = 8'bz; // The Powering-up State Machine if (~CKEreg && CKE_ipd) begin if (CSNeg_ipd == 1'bx) $display ("Unusable value for CSNeg"); if (CSNeg_ipd) command = nop; case (statebank[cur_bank]) write_suspend : begin statebank[cur_bank] = write; end read_suspend : begin statebank[cur_bank] = read; end self_refresh : begin statebank[0] <= #tdevice_TRP idle; statebank[1] <= #tdevice_TRP idle; statebank[2] <= #tdevice_TRP idle; statebank[3] <= #tdevice_TRP idle; Ref_Cnt = 4096; if (command != nop) begin $display ("Illegal command received during self"); $display ("refresh",$time); end end pwrdwn : begin statebank[0] = idle; statebank[1] = idle; statebank[2] = idle; statebank[3] = idle; end bank_act_pwrdwn : begin statebank[cur_bank] = bank_act; end endcase end // The Powering-down State Machine if (CKEreg && ~CKE_ipd) begin if (CSNeg_ipd == 1'bx) $display ("Unusable value for CSNeg"); if (CSNeg_ipd) command = nop; case (statebank[cur_bank]) idle : begin if (command == nop) begin statebank[0] = pwrdwn; statebank[1] = pwrdwn; statebank[2] = pwrdwn; statebank[3] = pwrdwn; end end write : begin statebank[cur_bank] = write_suspend; end read : begin statebank[cur_bank] = read_suspend; end bank_act : begin statebank[cur_bank] = bank_act_pwrdwn; end endcase end CKEreg = CKE_ipd; end always @(DataDriveOut) begin DQ_zd = DataDriveOut; end reg TRC_In , TRCAR_In; reg TRCD_In , TRP_In , TWR_In; wire TRC_Out, TRCAR_Out, TRCD_Out, TRP_Out, TWR_Out; BUFFER BUF_TRC (TRC_Out , TRC_In); BUFFER BUF_TRCAR (TRCAR_Out, TRCAR_In); BUFFER BUF_TRCD (TRCD_Out , TRCD_In); BUFFER BUF_TRP (TRP_Out , TRP_In); BUFFER BUF_TWR (TWR_Out , TWR_In); initial begin TRC_In = 1; TRCAR_In = 1; TRCD_In = 1'b1; TRP_In = 1; TWR_In = 1; end always @(posedge TRC_Out) begin tdevice_TRC = $time; end always @(posedge TRCAR_Out) begin tdevice_TRCAR = $time; end always @(posedge TRCD_Out) begin tdevice_TRCD = $time; end always @(posedge TRP_Out) begin tdevice_TRP = $time; end always @(posedge TWR_Out) begin tdevice_TWR = $time; end endmodule module BUFFER (OUT,IN); input IN; output OUT; buf (OUT, IN); endmodule
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