mirror of
https://github.com/Klagarge/Cursor.git
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1364 lines
61 KiB
VHDL
1364 lines
61 KiB
VHDL
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-----------------------------------------------------------------------------------------
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--
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-- File Name: MT48LC16M16A2.VHD
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-- Version: 0.0g
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-- Date: June 29th, 2000
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-- Model: Behavioral
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-- Simulator: Model Technology (PC version 5.3 PE)
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--
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-- Dependencies: None
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--
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-- Author: Son P. Huynh
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-- Email: sphuynh@micron.com
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-- Phone: (208) 368-3825
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-- Company: Micron Technology, Inc.
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-- Part Number: MT48LC16M16A2 (4Mb x 16 x 4 Banks)
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--
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-- Description: Micron 256Mb SDRAM
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--
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-- Limitation: - Doesn't check for 4096-cycle refresh --'
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--
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-- Note: - Set simulator resolution to "ps" accuracy
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--
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-- Disclaimer: THESE DESIGNS ARE PROVIDED "AS IS" WITH NO WARRANTY
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-- WHATSOEVER AND MICRON SPECIFICALLY DISCLAIMS ANY
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-- IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR
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-- A PARTICULAR PURPOSE, OR AGAINST INFRINGEMENT.
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--
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-- Copyright (c) 1998 Micron Semiconductor Products, Inc.
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-- All rights researved
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--
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-- Rev Author Phone Date Changes
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-- ---- ---------------------------- ---------- -------------------------------------
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-- 0.0g Son Huynh 208-368-3825 06/29/2000 Add Load/Dump memory array
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-- Micron Technology Inc. Modify tWR + tRAS timing check
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--
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-- 0.0f Son Huynh 208-368-3825 07/08/1999 Fix tWR = 1 Clk + 7.5 ns (Auto)
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-- Micron Technology Inc. Fix tWR = 15 ns (Manual)
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-- Fix tRP (Autoprecharge to AutoRefresh)
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--
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-- 0.0c Son P. Huynh 208-368-3825 04/08/1999 Fix tWR + tRP in Write with AP
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-- Micron Technology Inc. Fix tRC check in Load Mode Register
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--
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-- 0.0b Son P. Huynh 208-368-3825 01/06/1998 Derive from 64Mb SDRAM model
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-- Micron Technology Inc.
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--
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-----------------------------------------------------------------------------------------
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--LIBRARY STD;
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-- use std.textio.all;
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--LIBRARY IEEE;
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-- USE IEEE.STD_LOGIC_1164.ALL;
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--LIBRARY WORK;
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-- USE WORK.MTI_PKG.ALL;
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LIBRARY memory_test;
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USE memory_test.mti_pkg.all;
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--library grlib;
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--use grlib.stdlib.all;
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--library gaisler;
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--use gaisler.sim.all;
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--ENTITY mt48lc16m16a2 IS
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-- GENERIC (
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-- -- Timing Parameters for -75 (PC133) and CAS Latency = 2
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-- tAC : TIME := 6.0 ns;
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-- tHZ : TIME := 7.0 ns;
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-- tOH : TIME := 2.7 ns;
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-- tMRD : INTEGER := 2; -- 2 Clk Cycles
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-- tRAS : TIME := 44.0 ns;
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-- tRC : TIME := 66.0 ns;
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-- tRCD : TIME := 20.0 ns;
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-- tRP : TIME := 20.0 ns;
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-- tRRD : TIME := 15.0 ns;
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-- tWRa : TIME := 7.5 ns; -- A2 Version - Auto precharge mode only (1 Clk + 7.5 ns)
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-- tWRp : TIME := 15.0 ns; -- A2 Version - Precharge mode only (15 ns)
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--
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-- tAH : TIME := 0.8 ns;
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-- tAS : TIME := 1.5 ns;
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-- tCH : TIME := 2.5 ns;
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-- tCL : TIME := 2.5 ns;
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-- tCK : TIME := 10.0 ns;
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-- tDH : TIME := 0.8 ns;
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-- tDS : TIME := 1.5 ns;
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-- tCKH : TIME := 0.8 ns;
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-- tCKS : TIME := 1.5 ns;
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-- tCMH : TIME := 0.8 ns;
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-- tCMS : TIME := 1.5 ns;
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--
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-- addr_bits : INTEGER := 13;
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-- data_bits : INTEGER := 16;
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-- col_bits : INTEGER := 9;
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-- index : INTEGER := 0;
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-- fname : string := "sdram.srec" -- File to read from
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-- );
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-- PORT (
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-- Dq : INOUT STD_LOGIC_VECTOR (data_bits - 1 DOWNTO 0) := (OTHERS => 'Z');
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-- Addr : IN STD_LOGIC_VECTOR (addr_bits - 1 DOWNTO 0) := (OTHERS => '0');
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-- Ba : IN STD_LOGIC_VECTOR := "00";
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-- Clk : IN STD_LOGIC := '0';
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-- Cke : IN STD_LOGIC := '1';
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-- Cs_n : IN STD_LOGIC := '1';
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-- Ras_n : IN STD_LOGIC := '1';
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-- Cas_n : IN STD_LOGIC := '1';
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-- We_n : IN STD_LOGIC := '1';
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-- Dqm : IN STD_LOGIC_VECTOR (1 DOWNTO 0) := "00"
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-- );
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--END mt48lc16m16a2;
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ARCHITECTURE sim OF sdram_mt48lc16m16a2 IS
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TYPE State IS (ACT, A_REF, BST, LMR, NOP, PRECH, READ, READ_A, WRITE, WRITE_A, LOAD_FILE, DUMP_FILE);
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TYPE Array4xI IS ARRAY (3 DOWNTO 0) OF INTEGER;
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TYPE Array4xT IS ARRAY (3 DOWNTO 0) OF TIME;
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TYPE Array4xB IS ARRAY (3 DOWNTO 0) OF BIT;
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TYPE Array4x2BV IS ARRAY (3 DOWNTO 0) OF BIT_VECTOR (1 DOWNTO 0);
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TYPE Array4xCBV IS ARRAY (4 DOWNTO 0) OF BIT_VECTOR (Col_bits - 1 DOWNTO 0);
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TYPE Array_state IS ARRAY (4 DOWNTO 0) OF State;
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SIGNAL Operation : State := NOP;
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SIGNAL Mode_reg : BIT_VECTOR (addr_bits - 1 DOWNTO 0) := (OTHERS => '0');
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SIGNAL Active_enable, Aref_enable, Burst_term : BIT := '0';
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SIGNAL Mode_reg_enable, Prech_enable, Read_enable, Write_enable : BIT := '0';
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SIGNAL Burst_length_1, Burst_length_2, Burst_length_4, Burst_length_8 : BIT := '0';
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SIGNAL Cas_latency_2, Cas_latency_3 : BIT := '0';
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SIGNAL Ras_in, Cas_in, We_in : BIT := '0';
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SIGNAL Write_burst_mode : BIT := '0';
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SIGNAL RAS_clk, Sys_clk, CkeZ : BIT := '0';
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-- Checking internal wires
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SIGNAL Pre_chk : BIT_VECTOR (3 DOWNTO 0) := "0000";
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SIGNAL Act_chk : BIT_VECTOR (3 DOWNTO 0) := "0000";
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SIGNAL Dq_in_chk, Dq_out_chk : BIT := '0';
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SIGNAL Bank_chk : BIT_VECTOR (1 DOWNTO 0) := "00";
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SIGNAL Row_chk : BIT_VECTOR (addr_bits - 1 DOWNTO 0) := (OTHERS => '0');
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SIGNAL Col_chk : BIT_VECTOR (col_bits - 1 DOWNTO 0) := (OTHERS => '0');
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BEGIN
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-- CS# Decode
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WITH Cs_n SELECT
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Cas_in <= TO_BIT (Cas_n, '1') WHEN '0',
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'1' WHEN '1',
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'1' WHEN OTHERS;
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WITH Cs_n SELECT
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Ras_in <= TO_BIT (Ras_n, '1') WHEN '0',
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'1' WHEN '1',
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'1' WHEN OTHERS;
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WITH Cs_n SELECT
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We_in <= TO_BIT (We_n, '1') WHEN '0',
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'1' WHEN '1',
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'1' WHEN OTHERS;
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-- Commands Decode
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Active_enable <= NOT(Ras_in) AND Cas_in AND We_in;
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Aref_enable <= NOT(Ras_in) AND NOT(Cas_in) AND We_in;
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Burst_term <= Ras_in AND Cas_in AND NOT(We_in);
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Mode_reg_enable <= NOT(Ras_in) AND NOT(Cas_in) AND NOT(We_in);
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Prech_enable <= NOT(Ras_in) AND Cas_in AND NOT(We_in);
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Read_enable <= Ras_in AND NOT(Cas_in) AND We_in;
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Write_enable <= Ras_in AND NOT(Cas_in) AND NOT(We_in);
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-- Burst Length Decode
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Burst_length_1 <= NOT(Mode_reg(2)) AND NOT(Mode_reg(1)) AND NOT(Mode_reg(0));
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Burst_length_2 <= NOT(Mode_reg(2)) AND NOT(Mode_reg(1)) AND Mode_reg(0);
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Burst_length_4 <= NOT(Mode_reg(2)) AND Mode_reg(1) AND NOT(Mode_reg(0));
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Burst_length_8 <= NOT(Mode_reg(2)) AND Mode_reg(1) AND Mode_reg(0);
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-- CAS Latency Decode
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Cas_latency_2 <= NOT(Mode_reg(6)) AND Mode_reg(5) AND NOT(Mode_reg(4));
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Cas_latency_3 <= NOT(Mode_reg(6)) AND Mode_reg(5) AND Mode_reg(4);
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-- Write Burst Mode
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Write_burst_mode <= Mode_reg(9);
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-- RAS Clock for checking tWR and tRP
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PROCESS
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variable Clk0, Clk1 : integer := 0;
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begin
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RAS_clk <= '1';
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wait for 0.5 ns;
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RAS_clk <= '0';
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wait for 0.5 ns;
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if Clk0 > 100 or Clk1 > 100 then
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wait;
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else
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if Clk = '1' and Cke = '1' then
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Clk0 := 0;
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Clk1 := Clk1 + 1;
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elsif Clk = '0' and Cke = '1' then
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Clk0 := Clk0 + 1;
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Clk1 := 0;
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end if;
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end if;
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END PROCESS;
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-- System Clock
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int_clk : PROCESS (Clk)
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begin
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IF Clk'LAST_VALUE = '0' AND Clk = '1' THEN --'
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CkeZ <= TO_BIT(Cke, '1');
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END IF;
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Sys_clk <= CkeZ AND TO_BIT(Clk, '0');
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END PROCESS;
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state_register : PROCESS
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-- NOTE: The extra bits in RAM_TYPE is for checking memory access. A logic 1 means
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-- the location is in use. This will be checked when doing memory DUMP.
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TYPE ram_type IS ARRAY (2**col_bits - 1 DOWNTO 0) OF BIT_VECTOR (data_bits DOWNTO 0);
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TYPE ram_pntr IS ACCESS ram_type;
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TYPE ram_stor IS ARRAY (2**addr_bits - 1 DOWNTO 0) OF ram_pntr;
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VARIABLE Bank0 : ram_stor;
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VARIABLE Bank1 : ram_stor;
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VARIABLE Bank2 : ram_stor;
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VARIABLE Bank3 : ram_stor;
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VARIABLE Row_index, Col_index : INTEGER := 0;
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VARIABLE Dq_temp : BIT_VECTOR (data_bits DOWNTO 0) := (OTHERS => '0');
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VARIABLE Col_addr : Array4xCBV;
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VARIABLE Bank_addr : Array4x2BV;
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VARIABLE Dqm_reg0, Dqm_reg1 : BIT_VECTOR (1 DOWNTO 0) := "00";
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VARIABLE Bank, Previous_bank : BIT_VECTOR (1 DOWNTO 0) := "00";
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VARIABLE B0_row_addr, B1_row_addr, B2_row_addr, B3_row_addr : BIT_VECTOR (addr_bits - 1 DOWNTO 0) := (OTHERS => '0');
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VARIABLE Col_brst : BIT_VECTOR (col_bits - 1 DOWNTO 0) := (OTHERS => '0');
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VARIABLE Row : BIT_VECTOR (addr_bits - 1 DOWNTO 0) := (OTHERS => '0');
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VARIABLE Col : BIT_VECTOR (col_bits - 1 DOWNTO 0) := (OTHERS => '0');
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VARIABLE Burst_counter : INTEGER := 0;
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VARIABLE Command : Array_state;
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VARIABLE Bank_precharge : Array4x2BV;
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VARIABLE A10_precharge : Array4xB := ('0' & '0' & '0' & '0');
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VARIABLE Auto_precharge : Array4xB := ('0' & '0' & '0' & '0');
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VARIABLE Read_precharge : Array4xB := ('0' & '0' & '0' & '0');
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VARIABLE Write_precharge : Array4xB := ('0' & '0' & '0' & '0');
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VARIABLE RW_interrupt_read : Array4xB := ('0' & '0' & '0' & '0');
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VARIABLE RW_interrupt_write : Array4xB := ('0' & '0' & '0' & '0');
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VARIABLE RW_interrupt_bank : BIT_VECTOR (1 DOWNTO 0) := "00";
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VARIABLE Count_time : Array4xT := (0 ns & 0 ns & 0 ns & 0 ns);
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VARIABLE Count_precharge : Array4xI := (0 & 0 & 0 & 0);
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VARIABLE Data_in_enable, Data_out_enable : BIT := '0';
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VARIABLE Pc_b0, Pc_b1, Pc_b2, Pc_b3 : BIT := '0';
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VARIABLE Act_b0, Act_b1, Act_b2, Act_b3 : BIT := '0';
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-- Timing Check
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VARIABLE MRD_chk : INTEGER := 0;
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VARIABLE WR_counter : Array4xI := (0 & 0 & 0 & 0);
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VARIABLE WR_time : Array4xT := (0 ns & 0 ns & 0 ns & 0 ns);
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VARIABLE WR_chkp : Array4xT := (0 ns & 0 ns & 0 ns & 0 ns);
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VARIABLE RC_chk, RRD_chk : TIME := 0 ns;
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VARIABLE RAS_chk0, RAS_chk1, RAS_chk2, RAS_chk3 : TIME := 0 ns;
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VARIABLE RCD_chk0, RCD_chk1, RCD_chk2, RCD_chk3 : TIME := 0 ns;
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VARIABLE RP_chk0, RP_chk1, RP_chk2, RP_chk3 : TIME := 0 ns;
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-- Load and Dumb variables
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FILE file_load : TEXT open read_mode is fname; -- Data load
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FILE file_dump : TEXT open write_mode is "dumpdata.txt"; -- Data dump
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VARIABLE bank_load : bit_vector ( 1 DOWNTO 0);
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VARIABLE rows_load : BIT_VECTOR (12 DOWNTO 0);
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VARIABLE cols_load : BIT_VECTOR ( 8 DOWNTO 0);
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VARIABLE data_load : BIT_VECTOR (15 DOWNTO 0);
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VARIABLE i, j : INTEGER;
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VARIABLE good_load : BOOLEAN;
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VARIABLE l : LINE;
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variable load : std_logic := '1';
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variable dump : std_logic := '0';
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variable ch : character;
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variable rectype : bit_vector(3 downto 0);
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variable recaddr : bit_vector(31 downto 0);
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variable reclen : bit_vector(7 downto 0);
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variable recdata : bit_vector(0 to 16*8-1);
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-- Initialize empty rows
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PROCEDURE Init_mem (Bank : bit_vector (1 DOWNTO 0); Row_index : INTEGER) IS
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VARIABLE i, j : INTEGER := 0;
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BEGIN
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IF Bank = "00" THEN
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IF Bank0 (Row_index) = NULL THEN -- Check to see if row empty
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Bank0 (Row_index) := NEW ram_type; -- Open new row for access
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FOR i IN (2**col_bits - 1) DOWNTO 0 LOOP -- Filled row with zeros
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FOR j IN (data_bits) DOWNTO 0 LOOP
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Bank0 (Row_index) (i) (j) := '0';
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END LOOP;
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END LOOP;
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END IF;
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ELSIF Bank = "01" THEN
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IF Bank1 (Row_index) = NULL THEN
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Bank1 (Row_index) := NEW ram_type;
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FOR i IN (2**col_bits - 1) DOWNTO 0 LOOP
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FOR j IN (data_bits) DOWNTO 0 LOOP
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Bank1 (Row_index) (i) (j) := '0';
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END LOOP;
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END LOOP;
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END IF;
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ELSIF Bank = "10" THEN
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IF Bank2 (Row_index) = NULL THEN
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Bank2 (Row_index) := NEW ram_type;
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FOR i IN (2**col_bits - 1) DOWNTO 0 LOOP
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FOR j IN (data_bits) DOWNTO 0 LOOP
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Bank2 (Row_index) (i) (j) := '0';
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END LOOP;
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END LOOP;
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END IF;
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ELSIF Bank = "11" THEN
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IF Bank3 (Row_index) = NULL THEN
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Bank3 (Row_index) := NEW ram_type;
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FOR i IN (2**col_bits - 1) DOWNTO 0 LOOP
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FOR j IN (data_bits) DOWNTO 0 LOOP
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Bank3 (Row_index) (i) (j) := '0';
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END LOOP;
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END LOOP;
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||
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END IF;
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||
|
END IF;
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||
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END;
|
||
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|
||
|
-- Burst Counter
|
||
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PROCEDURE Burst_decode IS
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||
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VARIABLE Col_int : INTEGER := 0;
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||
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VARIABLE Col_vec, Col_temp : BIT_VECTOR (col_bits - 1 DOWNTO 0) := (OTHERS => '0');
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||
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BEGIN
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||
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-- Advance Burst Counter
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||
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Burst_counter := Burst_counter + 1;
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||
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|
||
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-- Burst Type
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||
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IF Mode_reg (3) = '0' THEN
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Col_int := TO_INTEGER(Col);
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Col_int := Col_int + 1;
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||
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TO_BITVECTOR (Col_int, Col_temp);
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ELSIF Mode_reg (3) = '1' THEN
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TO_BITVECTOR (Burst_counter, Col_vec);
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||
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Col_temp (2) := Col_vec (2) XOR Col_brst (2);
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||
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Col_temp (1) := Col_vec (1) XOR Col_brst (1);
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||
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Col_temp (0) := Col_vec (0) XOR Col_brst (0);
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END IF;
|
||
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|
||
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-- Burst Length
|
||
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IF Burst_length_2 = '1' THEN
|
||
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Col (0) := Col_temp (0);
|
||
|
ELSIF Burst_length_4 = '1' THEN
|
||
|
Col (1 DOWNTO 0) := Col_temp (1 DOWNTO 0);
|
||
|
ELSIF Burst_length_8 = '1' THEN
|
||
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Col (2 DOWNTO 0) := Col_temp (2 DOWNTO 0);
|
||
|
ELSE
|
||
|
Col := Col_temp;
|
||
|
END IF;
|
||
|
|
||
|
-- Burst Read Single Write
|
||
|
IF Write_burst_mode = '1' AND Data_in_enable = '1' THEN
|
||
|
Data_in_enable := '0';
|
||
|
END IF;
|
||
|
|
||
|
-- Data counter
|
||
|
IF Burst_length_1 = '1' THEN
|
||
|
IF Burst_counter >= 1 THEN
|
||
|
IF Data_in_enable = '1' THEN
|
||
|
Data_in_enable := '0';
|
||
|
ELSIF Data_out_enable = '1' THEN
|
||
|
Data_out_enable := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
ELSIF Burst_length_2 = '1' THEN
|
||
|
IF Burst_counter >= 2 THEN
|
||
|
IF Data_in_enable = '1' THEN
|
||
|
Data_in_enable := '0';
|
||
|
ELSIF Data_out_enable = '1' THEN
|
||
|
Data_out_enable := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
ELSIF Burst_length_4 = '1' THEN
|
||
|
IF Burst_counter >= 4 THEN
|
||
|
IF Data_in_enable = '1' THEN
|
||
|
Data_in_enable := '0';
|
||
|
ELSIF Data_out_enable = '1' THEN
|
||
|
Data_out_enable := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
ELSIF Burst_length_8 = '1' THEN
|
||
|
IF Burst_counter >= 8 THEN
|
||
|
IF Data_in_enable = '1' THEN
|
||
|
Data_in_enable := '0';
|
||
|
ELSIF Data_out_enable = '1' THEN
|
||
|
Data_out_enable := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
END IF;
|
||
|
END;
|
||
|
|
||
|
BEGIN
|
||
|
WAIT ON Sys_clk, RAS_clk;
|
||
|
IF Sys_clk'event AND Sys_clk = '1' AND Load = '0' AND Dump = '0' THEN --'
|
||
|
-- Internal Command Pipeline
|
||
|
Command(0) := Command(1);
|
||
|
Command(1) := Command(2);
|
||
|
Command(2) := Command(3);
|
||
|
Command(3) := NOP;
|
||
|
|
||
|
Col_addr(0) := Col_addr(1);
|
||
|
Col_addr(1) := Col_addr(2);
|
||
|
Col_addr(2) := Col_addr(3);
|
||
|
Col_addr(3) := (OTHERS => '0');
|
||
|
|
||
|
Bank_addr(0) := Bank_addr(1);
|
||
|
Bank_addr(1) := Bank_addr(2);
|
||
|
Bank_addr(2) := Bank_addr(3);
|
||
|
Bank_addr(3) := "00";
|
||
|
|
||
|
Bank_precharge(0) := Bank_precharge(1);
|
||
|
Bank_precharge(1) := Bank_precharge(2);
|
||
|
Bank_precharge(2) := Bank_precharge(3);
|
||
|
Bank_precharge(3) := "00";
|
||
|
|
||
|
A10_precharge(0) := A10_precharge(1);
|
||
|
A10_precharge(1) := A10_precharge(2);
|
||
|
A10_precharge(2) := A10_precharge(3);
|
||
|
A10_precharge(3) := '0';
|
||
|
|
||
|
-- Operation Decode (Optional for showing current command on posedge clock / debug feature)
|
||
|
IF Active_enable = '1' THEN
|
||
|
Operation <= ACT;
|
||
|
ELSIF Aref_enable = '1' THEN
|
||
|
Operation <= A_REF;
|
||
|
ELSIF Burst_term = '1' THEN
|
||
|
Operation <= BST;
|
||
|
ELSIF Mode_reg_enable = '1' THEN
|
||
|
Operation <= LMR;
|
||
|
ELSIF Prech_enable = '1' THEN
|
||
|
Operation <= PRECH;
|
||
|
ELSIF Read_enable = '1' THEN
|
||
|
IF Addr(10) = '0' THEN
|
||
|
Operation <= READ;
|
||
|
ELSE
|
||
|
Operation <= READ_A;
|
||
|
END IF;
|
||
|
ELSIF Write_enable = '1' THEN
|
||
|
IF Addr(10) = '0' THEN
|
||
|
Operation <= WRITE;
|
||
|
ELSE
|
||
|
Operation <= WRITE_A;
|
||
|
END IF;
|
||
|
ELSE
|
||
|
Operation <= NOP;
|
||
|
END IF;
|
||
|
|
||
|
-- Dqm pipeline for Read
|
||
|
Dqm_reg0 := Dqm_reg1;
|
||
|
Dqm_reg1 := TO_BITVECTOR(Dqm);
|
||
|
|
||
|
-- Read or Write with Auto Precharge Counter
|
||
|
IF Auto_precharge (0) = '1' THEN
|
||
|
Count_precharge (0) := Count_precharge (0) + 1;
|
||
|
END IF;
|
||
|
IF Auto_precharge (1) = '1' THEN
|
||
|
Count_precharge (1) := Count_precharge (1) + 1;
|
||
|
END IF;
|
||
|
IF Auto_precharge (2) = '1' THEN
|
||
|
Count_precharge (2) := Count_precharge (2) + 1;
|
||
|
END IF;
|
||
|
IF Auto_precharge (3) = '1' THEN
|
||
|
Count_precharge (3) := Count_precharge (3) + 1;
|
||
|
END IF;
|
||
|
|
||
|
-- Auto Precharge Timer for tWR
|
||
|
if (Burst_length_1 = '1' OR Write_burst_mode = '1') then
|
||
|
if (Count_precharge(0) = 1) then
|
||
|
Count_time(0) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(1) = 1) then
|
||
|
Count_time(1) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(2) = 1) then
|
||
|
Count_time(2) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(3) = 1) then
|
||
|
Count_time(3) := NOW;
|
||
|
end if;
|
||
|
elsif (Burst_length_2 = '1') then
|
||
|
if (Count_precharge(0) = 2) then
|
||
|
Count_time(0) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(1) = 2) then
|
||
|
Count_time(1) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(2) = 2) then
|
||
|
Count_time(2) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(3) = 2) then
|
||
|
Count_time(3) := NOW;
|
||
|
end if;
|
||
|
elsif (Burst_length_4 = '1') then
|
||
|
if (Count_precharge(0) = 4) then
|
||
|
Count_time(0) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(1) = 4) then
|
||
|
Count_time(1) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(2) = 4) then
|
||
|
Count_time(2) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(3) = 4) then
|
||
|
Count_time(3) := NOW;
|
||
|
end if;
|
||
|
elsif (Burst_length_8 = '1') then
|
||
|
if (Count_precharge(0) = 8) then
|
||
|
Count_time(0) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(1) = 8) then
|
||
|
Count_time(1) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(2) = 8) then
|
||
|
Count_time(2) := NOW;
|
||
|
end if;
|
||
|
if (Count_precharge(3) = 8) then
|
||
|
Count_time(3) := NOW;
|
||
|
end if;
|
||
|
end if;
|
||
|
|
||
|
-- tMRD Counter
|
||
|
MRD_chk := MRD_chk + 1;
|
||
|
|
||
|
-- tWR Counter
|
||
|
WR_counter(0) := WR_counter(0) + 1;
|
||
|
WR_counter(1) := WR_counter(1) + 1;
|
||
|
WR_counter(2) := WR_counter(2) + 1;
|
||
|
WR_counter(3) := WR_counter(3) + 1;
|
||
|
|
||
|
|
||
|
-- Auto Refresh
|
||
|
IF Aref_enable = '1' THEN
|
||
|
-- Auto Refresh to Auto Refresh
|
||
|
ASSERT (NOW - RC_chk >= tRC)
|
||
|
REPORT "tRC violation during Auto Refresh"
|
||
|
SEVERITY WARNING;
|
||
|
-- Precharge to Auto Refresh
|
||
|
ASSERT (NOW - RP_chk0 >= tRP OR NOW - RP_chk1 >= tRP OR NOW - RP_chk2 >= tRP OR NOW - RP_chk3 >= tRP)
|
||
|
REPORT "tRP violation during Auto Refresh"
|
||
|
SEVERITY WARNING;
|
||
|
-- All banks must be idle before refresh
|
||
|
IF (Pc_b3 ='0' OR Pc_b2 = '0' OR Pc_b1 ='0' OR Pc_b0 = '0') THEN
|
||
|
ASSERT (FALSE)
|
||
|
REPORT "All banks must be Precharge before Auto Refresh"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
-- Record current tRC time
|
||
|
RC_chk := NOW;
|
||
|
END IF;
|
||
|
|
||
|
-- Load Mode Register
|
||
|
IF Mode_reg_enable = '1' THEN
|
||
|
Mode_reg <= TO_BITVECTOR (Addr);
|
||
|
IF (Pc_b3 ='0' OR Pc_b2 = '0' OR Pc_b1 ='0' OR Pc_b0 = '0') THEN
|
||
|
ASSERT (FALSE)
|
||
|
REPORT "All bank must be Precharge before Load Mode Register"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
-- REF to LMR
|
||
|
ASSERT (NOW - RC_chk >= tRC)
|
||
|
REPORT "tRC violation during Load Mode Register"
|
||
|
SEVERITY WARNING;
|
||
|
-- LMR to LMR
|
||
|
ASSERT (MRD_chk >= tMRD)
|
||
|
REPORT "tMRD violation during Load Mode Register"
|
||
|
SEVERITY WARNING;
|
||
|
-- Record current tMRD time
|
||
|
MRD_chk := 0;
|
||
|
END IF;
|
||
|
|
||
|
-- Active Block (latch Bank and Row Address)
|
||
|
IF Active_enable = '1' THEN
|
||
|
IF Ba = "00" AND Pc_b0 = '1' THEN
|
||
|
Act_b0 := '1';
|
||
|
Pc_b0 := '0';
|
||
|
B0_row_addr := TO_BITVECTOR (Addr);
|
||
|
RCD_chk0 := NOW;
|
||
|
RAS_chk0 := NOW;
|
||
|
-- Precharge to Active Bank 0
|
||
|
ASSERT (NOW - RP_chk0 >= tRP)
|
||
|
REPORT "tRP violation during Activate Bank 0"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "01" AND Pc_b1 = '1' THEN
|
||
|
Act_b1 := '1';
|
||
|
Pc_b1 := '0';
|
||
|
B1_row_addr := TO_BITVECTOR (Addr);
|
||
|
RCD_chk1 := NOW;
|
||
|
RAS_chk1 := NOW;
|
||
|
-- Precharge to Active Bank 1
|
||
|
ASSERT (NOW - RP_chk1 >= tRP)
|
||
|
REPORT "tRP violation during Activate Bank 1"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "10" AND Pc_b2 = '1' THEN
|
||
|
Act_b2 := '1';
|
||
|
Pc_b2 := '0';
|
||
|
B2_row_addr := TO_BITVECTOR (Addr);
|
||
|
RCD_chk2 := NOW;
|
||
|
RAS_chk2 := NOW;
|
||
|
-- Precharge to Active Bank 2
|
||
|
ASSERT (NOW - RP_chk2 >= tRP)
|
||
|
REPORT "tRP violation during Activate Bank 2"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "11" AND Pc_b3 = '1' THEN
|
||
|
Act_b3 := '1';
|
||
|
Pc_b3 := '0';
|
||
|
B3_row_addr := TO_BITVECTOR (Addr);
|
||
|
RCD_chk3 := NOW;
|
||
|
RAS_chk3 := NOW;
|
||
|
-- Precharge to Active Bank 3
|
||
|
ASSERT (NOW - RP_chk3 >= tRP)
|
||
|
REPORT "tRP violation during Activate Bank 3"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "00" AND Pc_b0 = '0' THEN
|
||
|
ASSERT (FALSE)
|
||
|
REPORT "Bank 0 is not Precharged"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "01" AND Pc_b1 = '0' THEN
|
||
|
ASSERT (FALSE)
|
||
|
REPORT "Bank 1 is not Precharged"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "10" AND Pc_b2 = '0' THEN
|
||
|
ASSERT (FALSE)
|
||
|
REPORT "Bank 2 is not Precharged"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "11" AND Pc_b3 = '0' THEN
|
||
|
ASSERT (FALSE)
|
||
|
REPORT "Bank 3 is not Precharged"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
-- Active Bank A to Active Bank B
|
||
|
IF ((Previous_bank /= TO_BITVECTOR (Ba)) AND (NOW - RRD_chk < tRRD)) THEN
|
||
|
ASSERT (FALSE)
|
||
|
REPORT "tRRD violation during Activate"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
-- LMR to ACT
|
||
|
ASSERT (MRD_chk >= tMRD)
|
||
|
REPORT "tMRD violation during Activate"
|
||
|
SEVERITY WARNING;
|
||
|
-- AutoRefresh to Activate
|
||
|
ASSERT (NOW - RC_chk >= tRC)
|
||
|
REPORT "tRC violation during Activate"
|
||
|
SEVERITY WARNING;
|
||
|
-- Record variable for checking violation
|
||
|
RRD_chk := NOW;
|
||
|
Previous_bank := TO_BITVECTOR (Ba);
|
||
|
END IF;
|
||
|
|
||
|
-- Precharge Block
|
||
|
IF Prech_enable = '1' THEN
|
||
|
IF Addr(10) = '1' THEN
|
||
|
Pc_b0 := '1';
|
||
|
Pc_b1 := '1';
|
||
|
Pc_b2 := '1';
|
||
|
Pc_b3 := '1';
|
||
|
Act_b0 := '0';
|
||
|
Act_b1 := '0';
|
||
|
Act_b2 := '0';
|
||
|
Act_b3 := '0';
|
||
|
RP_chk0 := NOW;
|
||
|
RP_chk1 := NOW;
|
||
|
RP_chk2 := NOW;
|
||
|
RP_chk3 := NOW;
|
||
|
-- Activate to Precharge all banks
|
||
|
ASSERT ((NOW - RAS_chk0 >= tRAS) OR (NOW - RAS_chk1 >= tRAS))
|
||
|
REPORT "tRAS violation during Precharge all banks"
|
||
|
SEVERITY WARNING;
|
||
|
-- tWR violation check for Write
|
||
|
IF ((NOW - WR_chkp(0) < tWRp) OR (NOW - WR_chkp(1) < tWRp) OR
|
||
|
(NOW - WR_chkp(2) < tWRp) OR (NOW - WR_chkp(3) < tWRp)) THEN
|
||
|
ASSERT (FALSE)
|
||
|
REPORT "tWR violation during Precharge ALL banks"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
ELSIF Addr(10) = '0' THEN
|
||
|
IF Ba = "00" THEN
|
||
|
Pc_b0 := '1';
|
||
|
Act_b0 := '0';
|
||
|
RP_chk0 := NOW;
|
||
|
-- Activate to Precharge bank 0
|
||
|
ASSERT (NOW - RAS_chk0 >= tRAS)
|
||
|
REPORT "tRAS violation during Precharge bank 0"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "01" THEN
|
||
|
Pc_b1 := '1';
|
||
|
Act_b1 := '0';
|
||
|
RP_chk1 := NOW;
|
||
|
-- Activate to Precharge bank 1
|
||
|
ASSERT (NOW - RAS_chk1 >= tRAS)
|
||
|
REPORT "tRAS violation during Precharge bank 1"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "10" THEN
|
||
|
Pc_b2 := '1';
|
||
|
Act_b2 := '0';
|
||
|
RP_chk2 := NOW;
|
||
|
-- Activate to Precharge bank 2
|
||
|
ASSERT (NOW - RAS_chk2 >= tRAS)
|
||
|
REPORT "tRAS violation during Precharge bank 2"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "11" THEN
|
||
|
Pc_b3 := '1';
|
||
|
Act_b3 := '0';
|
||
|
RP_chk3 := NOW;
|
||
|
-- Activate to Precharge bank 3
|
||
|
ASSERT (NOW - RAS_chk3 >= tRAS)
|
||
|
REPORT "tRAS violation during Precharge bank 3"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
-- tWR violation check for Write
|
||
|
ASSERT (NOW - WR_chkp(TO_INTEGER(Ba)) >= tWRp)
|
||
|
REPORT "tWR violation during Precharge"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
-- Terminate a Write Immediately (if same bank or all banks)
|
||
|
IF (Data_in_enable = '1' AND (Bank = TO_BITVECTOR(Ba) OR Addr(10) = '1')) THEN
|
||
|
Data_in_enable := '0';
|
||
|
END IF;
|
||
|
-- Precharge Command Pipeline for READ
|
||
|
IF CAS_latency_3 = '1' THEN
|
||
|
Command(2) := PRECH;
|
||
|
Bank_precharge(2) := TO_BITVECTOR (Ba);
|
||
|
A10_precharge(2) := TO_BIT(Addr(10));
|
||
|
ELSIF CAS_latency_2 = '1' THEN
|
||
|
Command(1) := PRECH;
|
||
|
Bank_precharge(1) := TO_BITVECTOR (Ba);
|
||
|
A10_precharge(1) := TO_BIT(Addr(10));
|
||
|
END IF;
|
||
|
END IF;
|
||
|
|
||
|
-- Burst Terminate
|
||
|
IF Burst_term = '1' THEN
|
||
|
-- Terminate a Write immediately
|
||
|
IF Data_in_enable = '1' THEN
|
||
|
Data_in_enable := '0';
|
||
|
END IF;
|
||
|
-- Terminate a Read depend on CAS Latency
|
||
|
IF CAS_latency_3 = '1' THEN
|
||
|
Command(2) := BST;
|
||
|
ELSIF CAS_latency_2 = '1' THEN
|
||
|
Command(1) := BST;
|
||
|
END IF;
|
||
|
END IF;
|
||
|
|
||
|
-- Read, Write, Column Latch
|
||
|
IF Read_enable = '1' OR Write_enable = '1' THEN
|
||
|
-- Check to see if bank is open (ACT) for Read or Write
|
||
|
IF ((Ba="00" AND Pc_b0='1') OR (Ba="01" AND Pc_b1='1') OR (Ba="10" AND Pc_b2='1') OR (Ba="11" AND Pc_b3='1')) THEN
|
||
|
ASSERT (FALSE)
|
||
|
REPORT "Cannot Read or Write - Bank is not Activated"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
-- Activate to Read or Write
|
||
|
IF Ba = "00" THEN
|
||
|
ASSERT (NOW - RCD_chk0 >= tRCD)
|
||
|
REPORT "tRCD violation during Read or Write to Bank 0"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "01" THEN
|
||
|
ASSERT (NOW - RCD_chk1 >= tRCD)
|
||
|
REPORT "tRCD violation during Read or Write to Bank 1"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "10" THEN
|
||
|
ASSERT (NOW - RCD_chk2 >= tRCD)
|
||
|
REPORT "tRCD violation during Read or Write to Bank 2"
|
||
|
SEVERITY WARNING;
|
||
|
ELSIF Ba = "11" THEN
|
||
|
ASSERT (NOW - RCD_chk3 >= tRCD)
|
||
|
REPORT "tRCD violation during Read or Write to Bank 3"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
|
||
|
-- Read Command
|
||
|
IF Read_enable = '1' THEN
|
||
|
-- CAS Latency Pipeline
|
||
|
IF Cas_latency_3 = '1' THEN
|
||
|
IF Addr(10) = '1' THEN
|
||
|
Command(2) := READ_A;
|
||
|
ELSE
|
||
|
Command(2) := READ;
|
||
|
END IF;
|
||
|
Col_addr (2) := TO_BITVECTOR (Addr(col_bits - 1 DOWNTO 0));
|
||
|
Bank_addr (2) := TO_BITVECTOR (Ba);
|
||
|
ELSIF Cas_latency_2 = '1' THEN
|
||
|
IF Addr(10) = '1' THEN
|
||
|
Command(1) := READ_A;
|
||
|
ELSE
|
||
|
Command(1) := READ;
|
||
|
END IF;
|
||
|
Col_addr (1) := TO_BITVECTOR (Addr(col_bits - 1 DOWNTO 0));
|
||
|
Bank_addr (1) := TO_BITVECTOR (Ba);
|
||
|
END IF;
|
||
|
|
||
|
-- Read intterupt a Write (terminate Write immediately)
|
||
|
IF Data_in_enable = '1' THEN
|
||
|
Data_in_enable := '0';
|
||
|
END IF;
|
||
|
|
||
|
-- Write Command
|
||
|
ELSIF Write_enable = '1' THEN
|
||
|
IF Addr(10) = '1' THEN
|
||
|
Command(0) := WRITE_A;
|
||
|
ELSE
|
||
|
Command(0) := WRITE;
|
||
|
END IF;
|
||
|
Col_addr (0) := TO_BITVECTOR (Addr(col_bits - 1 DOWNTO 0));
|
||
|
Bank_addr (0) := TO_BITVECTOR (Ba);
|
||
|
|
||
|
-- Write intterupt a Write (terminate Write immediately)
|
||
|
IF Data_in_enable = '1' THEN
|
||
|
Data_in_enable := '0';
|
||
|
END IF;
|
||
|
|
||
|
-- Write interrupt a Read (terminate Read immediately)
|
||
|
IF Data_out_enable = '1' THEN
|
||
|
Data_out_enable := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
|
||
|
-- Interrupt a Write with Auto Precharge
|
||
|
IF Auto_precharge(TO_INTEGER(RW_Interrupt_Bank)) = '1' AND Write_precharge(TO_INTEGER(RW_Interrupt_Bank)) = '1' THEN
|
||
|
RW_interrupt_write(TO_INTEGER(RW_Interrupt_Bank)) := '1';
|
||
|
END IF;
|
||
|
|
||
|
-- Interrupt a Read with Auto Precharge
|
||
|
IF Auto_precharge(TO_INTEGER(RW_Interrupt_Bank)) = '1' AND Read_precharge(TO_INTEGER(RW_Interrupt_Bank)) = '1' THEN
|
||
|
RW_interrupt_read(TO_INTEGER(RW_Interrupt_Bank)) := '1';
|
||
|
END IF;
|
||
|
|
||
|
-- Read or Write with Auto Precharge
|
||
|
IF Addr(10) = '1' THEN
|
||
|
Auto_precharge (TO_INTEGER(Ba)) := '1';
|
||
|
Count_precharge (TO_INTEGER(Ba)) := 0;
|
||
|
RW_Interrupt_Bank := TO_BitVector(Ba);
|
||
|
IF Read_enable = '1' THEN
|
||
|
Read_precharge (TO_INTEGER(Ba)) := '1';
|
||
|
ELSIF Write_enable = '1' THEN
|
||
|
Write_precharge (TO_INTEGER(Ba)) := '1';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
END IF;
|
||
|
|
||
|
-- Read with AutoPrecharge Calculation
|
||
|
-- The device start internal precharge when:
|
||
|
-- 1. BL/2 cycles after command
|
||
|
-- and 2. Meet tRAS requirement
|
||
|
-- or 3. Interrupt by a Read or Write (with or without Auto Precharge)
|
||
|
IF ((Auto_precharge(0) = '1') AND (Read_precharge(0) = '1')) THEN
|
||
|
IF (((NOW - RAS_chk0 >= tRAS) AND
|
||
|
((Burst_length_1 = '1' AND Count_precharge(0) >= 1) OR
|
||
|
(Burst_length_2 = '1' AND Count_precharge(0) >= 2) OR
|
||
|
(Burst_length_4 = '1' AND Count_precharge(0) >= 4) OR
|
||
|
(Burst_length_8 = '1' AND Count_precharge(0) >= 8))) OR
|
||
|
(RW_interrupt_read(0) = '1')) THEN
|
||
|
Pc_b0 := '1';
|
||
|
Act_b0 := '0';
|
||
|
RP_chk0 := NOW;
|
||
|
Auto_precharge(0) := '0';
|
||
|
Read_precharge(0) := '0';
|
||
|
RW_interrupt_read(0) := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
IF ((Auto_precharge(1) = '1') AND (Read_precharge(1) = '1')) THEN
|
||
|
IF (((NOW - RAS_chk1 >= tRAS) AND
|
||
|
((Burst_length_1 = '1' AND Count_precharge(1) >= 1) OR
|
||
|
(Burst_length_2 = '1' AND Count_precharge(1) >= 2) OR
|
||
|
(Burst_length_4 = '1' AND Count_precharge(1) >= 4) OR
|
||
|
(Burst_length_8 = '1' AND Count_precharge(1) >= 8))) OR
|
||
|
(RW_interrupt_read(1) = '1')) THEN
|
||
|
Pc_b1 := '1';
|
||
|
Act_b1 := '0';
|
||
|
RP_chk1 := NOW;
|
||
|
Auto_precharge(1) := '0';
|
||
|
Read_precharge(1) := '0';
|
||
|
RW_interrupt_read(1) := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
IF ((Auto_precharge(2) = '1') AND (Read_precharge(2) = '1')) THEN
|
||
|
IF (((NOW - RAS_chk2 >= tRAS) AND
|
||
|
((Burst_length_1 = '1' AND Count_precharge(2) >= 1) OR
|
||
|
(Burst_length_2 = '1' AND Count_precharge(2) >= 2) OR
|
||
|
(Burst_length_4 = '1' AND Count_precharge(2) >= 4) OR
|
||
|
(Burst_length_8 = '1' AND Count_precharge(2) >= 8))) OR
|
||
|
(RW_interrupt_read(2) = '1')) THEN
|
||
|
Pc_b2 := '1';
|
||
|
Act_b2 := '0';
|
||
|
RP_chk2 := NOW;
|
||
|
Auto_precharge(2) := '0';
|
||
|
Read_precharge(2) := '0';
|
||
|
RW_interrupt_read(2) := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
IF ((Auto_precharge(3) = '1') AND (Read_precharge(3) = '1')) THEN
|
||
|
IF (((NOW - RAS_chk3 >= tRAS) AND
|
||
|
((Burst_length_1 = '1' AND Count_precharge(3) >= 1) OR
|
||
|
(Burst_length_2 = '1' AND Count_precharge(3) >= 2) OR
|
||
|
(Burst_length_4 = '1' AND Count_precharge(3) >= 4) OR
|
||
|
(Burst_length_8 = '1' AND Count_precharge(3) >= 8))) OR
|
||
|
(RW_interrupt_read(3) = '1')) THEN
|
||
|
Pc_b3 := '1';
|
||
|
Act_b3 := '0';
|
||
|
RP_chk3 := NOW;
|
||
|
Auto_precharge(3) := '0';
|
||
|
Read_precharge(3) := '0';
|
||
|
RW_interrupt_read(3) := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
|
||
|
-- Internal Precharge or Bst
|
||
|
IF Command(0) = PRECH THEN -- PRECH terminate a read if same bank or all banks
|
||
|
IF Bank_precharge(0) = Bank OR A10_precharge(0) = '1' THEN
|
||
|
IF Data_out_enable = '1' THEN
|
||
|
Data_out_enable := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
ELSIF Command(0) = BST THEN -- BST terminate a read regardless of bank
|
||
|
IF Data_out_enable = '1' THEN
|
||
|
Data_out_enable := '0';
|
||
|
END IF;
|
||
|
END IF;
|
||
|
|
||
|
IF Data_out_enable = '0' THEN
|
||
|
Dq <= TRANSPORT (OTHERS => 'Z') AFTER tOH;
|
||
|
END IF;
|
||
|
|
||
|
-- Detect Read or Write Command
|
||
|
IF Command(0) = READ OR Command(0) = READ_A THEN
|
||
|
Bank := Bank_addr (0);
|
||
|
Col := Col_addr (0);
|
||
|
Col_brst := Col_addr (0);
|
||
|
IF Bank_addr (0) = "00" THEN
|
||
|
Row := B0_row_addr;
|
||
|
ELSIF Bank_addr (0) = "01" THEN
|
||
|
Row := B1_row_addr;
|
||
|
ELSIF Bank_addr (0) = "10" THEN
|
||
|
Row := B2_row_addr;
|
||
|
ELSE
|
||
|
Row := B3_row_addr;
|
||
|
END IF;
|
||
|
Burst_counter := 0;
|
||
|
Data_in_enable := '0';
|
||
|
Data_out_enable := '1';
|
||
|
ELSIF Command(0) = WRITE OR Command(0) = WRITE_A THEN
|
||
|
Bank := Bank_addr(0);
|
||
|
Col := Col_addr(0);
|
||
|
Col_brst := Col_addr(0);
|
||
|
IF Bank_addr (0) = "00" THEN
|
||
|
Row := B0_row_addr;
|
||
|
ELSIF Bank_addr (0) = "01" THEN
|
||
|
Row := B1_row_addr;
|
||
|
ELSIF Bank_addr (0) = "10" THEN
|
||
|
Row := B2_row_addr;
|
||
|
ELSE
|
||
|
Row := B3_row_addr;
|
||
|
END IF;
|
||
|
Burst_counter := 0;
|
||
|
Data_in_enable := '1';
|
||
|
Data_out_enable := '0';
|
||
|
END IF;
|
||
|
|
||
|
-- DQ (Driver / Receiver)
|
||
|
Row_index := TO_INTEGER (Row);
|
||
|
Col_index := TO_INTEGER (Col);
|
||
|
IF Data_in_enable = '1' THEN
|
||
|
IF Dqm /= "11" THEN
|
||
|
Init_mem (Bank, Row_index);
|
||
|
IF Bank = "00" THEN
|
||
|
Dq_temp := Bank0 (Row_index) (Col_index);
|
||
|
IF Dqm = "01" THEN
|
||
|
Dq_temp (15 DOWNTO 8) := TO_BITVECTOR (Dq (15 DOWNTO 8));
|
||
|
ELSIF Dqm = "10" THEN
|
||
|
Dq_temp (7 DOWNTO 0) := TO_BITVECTOR (Dq (7 DOWNTO 0));
|
||
|
ELSE
|
||
|
Dq_temp (15 DOWNTO 0) := TO_BITVECTOR (Dq (15 DOWNTO 0));
|
||
|
END IF;
|
||
|
Bank0 (Row_index) (Col_index) := ('1' & Dq_temp(data_bits - 1 DOWNTO 0));
|
||
|
ELSIF Bank = "01" THEN
|
||
|
Dq_temp := Bank1 (Row_index) (Col_index);
|
||
|
IF Dqm = "01" THEN
|
||
|
Dq_temp (15 DOWNTO 8) := TO_BITVECTOR (Dq (15 DOWNTO 8));
|
||
|
ELSIF Dqm = "10" THEN
|
||
|
Dq_temp (7 DOWNTO 0) := TO_BITVECTOR (Dq (7 DOWNTO 0));
|
||
|
ELSE
|
||
|
Dq_temp (15 DOWNTO 0) := TO_BITVECTOR (Dq (15 DOWNTO 0));
|
||
|
END IF;
|
||
|
Bank1 (Row_index) (Col_index) := ('1' & Dq_temp(data_bits - 1 DOWNTO 0));
|
||
|
ELSIF Bank = "10" THEN
|
||
|
Dq_temp := Bank2 (Row_index) (Col_index);
|
||
|
IF Dqm = "01" THEN
|
||
|
Dq_temp (15 DOWNTO 8) := TO_BITVECTOR (Dq (15 DOWNTO 8));
|
||
|
ELSIF Dqm = "10" THEN
|
||
|
Dq_temp (7 DOWNTO 0) := TO_BITVECTOR (Dq (7 DOWNTO 0));
|
||
|
ELSE
|
||
|
Dq_temp (15 DOWNTO 0) := TO_BITVECTOR (Dq (15 DOWNTO 0));
|
||
|
END IF;
|
||
|
Bank2 (Row_index) (Col_index) := ('1' & Dq_temp(data_bits - 1 DOWNTO 0));
|
||
|
ELSIF Bank = "11" THEN
|
||
|
Dq_temp := Bank3 (Row_index) (Col_index);
|
||
|
IF Dqm = "01" THEN
|
||
|
Dq_temp (15 DOWNTO 8) := TO_BITVECTOR (Dq (15 DOWNTO 8));
|
||
|
ELSIF Dqm = "10" THEN
|
||
|
Dq_temp (7 DOWNTO 0) := TO_BITVECTOR (Dq (7 DOWNTO 0));
|
||
|
ELSE
|
||
|
Dq_temp (15 DOWNTO 0) := TO_BITVECTOR (Dq (15 DOWNTO 0));
|
||
|
END IF;
|
||
|
Bank3 (Row_index) (Col_index) := ('1' & Dq_temp(data_bits - 1 DOWNTO 0));
|
||
|
END IF;
|
||
|
WR_chkp(TO_INTEGER(Bank)) := NOW;
|
||
|
WR_counter(TO_INTEGER(Bank)) := 0;
|
||
|
END IF;
|
||
|
Burst_decode;
|
||
|
ELSIF Data_out_enable = '1' THEN
|
||
|
IF Dqm_reg0 /= "11" THEN
|
||
|
Init_mem (Bank, Row_index);
|
||
|
IF Bank = "00" THEN
|
||
|
Dq_temp := Bank0 (Row_index) (Col_index);
|
||
|
IF Dqm_reg0 = "00" THEN
|
||
|
Dq (15 DOWNTO 0) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (15 DOWNTO 0)) AFTER tAC;
|
||
|
ELSIF Dqm_reg0 = "01" THEN
|
||
|
Dq (15 DOWNTO 8) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (15 DOWNTO 8)) AFTER tAC;
|
||
|
Dq (7 DOWNTO 0) <= TRANSPORT (OTHERS => 'Z') AFTER tAC;
|
||
|
ELSIF Dqm_reg0 = "10" THEN
|
||
|
Dq (15 DOWNTO 8) <= TRANSPORT (OTHERS => 'Z') AFTER tAC;
|
||
|
Dq (7 DOWNTO 0) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (7 DOWNTO 0)) AFTER tAC;
|
||
|
END IF;
|
||
|
ELSIF Bank = "01" THEN
|
||
|
Dq_temp := Bank1 (Row_index) (Col_index);
|
||
|
IF Dqm_reg0 = "00" THEN
|
||
|
Dq (15 DOWNTO 0) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (15 DOWNTO 0)) AFTER tAC;
|
||
|
ELSIF Dqm_reg0 = "01" THEN
|
||
|
Dq (15 DOWNTO 8) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (15 DOWNTO 8)) AFTER tAC;
|
||
|
Dq (7 DOWNTO 0) <= TRANSPORT (OTHERS => 'Z') AFTER tAC;
|
||
|
ELSIF Dqm_reg0 = "10" THEN
|
||
|
Dq (15 DOWNTO 8) <= TRANSPORT (OTHERS => 'Z') AFTER tAC;
|
||
|
Dq (7 DOWNTO 0) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (7 DOWNTO 0)) AFTER tAC;
|
||
|
END IF;
|
||
|
ELSIF Bank = "10" THEN
|
||
|
Dq_temp := Bank2 (Row_index) (Col_index);
|
||
|
IF Dqm_reg0 = "00" THEN
|
||
|
Dq (15 DOWNTO 0) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (15 DOWNTO 0)) AFTER tAC;
|
||
|
ELSIF Dqm_reg0 = "01" THEN
|
||
|
Dq (15 DOWNTO 8) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (15 DOWNTO 8)) AFTER tAC;
|
||
|
Dq (7 DOWNTO 0) <= TRANSPORT (OTHERS => 'Z') AFTER tAC;
|
||
|
ELSIF Dqm_reg0 = "10" THEN
|
||
|
Dq (15 DOWNTO 8) <= TRANSPORT (OTHERS => 'Z') AFTER tAC;
|
||
|
Dq (7 DOWNTO 0) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (7 DOWNTO 0)) AFTER tAC;
|
||
|
END IF;
|
||
|
ELSIF Bank = "11" THEN
|
||
|
Dq_temp := Bank3 (Row_index) (Col_index);
|
||
|
IF Dqm_reg0 = "00" THEN
|
||
|
Dq (15 DOWNTO 0) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (15 DOWNTO 0)) AFTER tAC;
|
||
|
ELSIF Dqm_reg0 = "01" THEN
|
||
|
Dq (15 DOWNTO 8) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (15 DOWNTO 8)) AFTER tAC;
|
||
|
Dq (7 DOWNTO 0) <= TRANSPORT (OTHERS => 'Z') AFTER tAC;
|
||
|
ELSIF Dqm_reg0 = "10" THEN
|
||
|
Dq (15 DOWNTO 8) <= TRANSPORT (OTHERS => 'Z') AFTER tAC;
|
||
|
Dq (7 DOWNTO 0) <= TRANSPORT TO_STDLOGICVECTOR (Dq_temp (7 DOWNTO 0)) AFTER tAC;
|
||
|
END IF;
|
||
|
END IF;
|
||
|
ELSE
|
||
|
Dq <= TRANSPORT (OTHERS => 'Z') AFTER tHZ;
|
||
|
END IF;
|
||
|
Burst_decode;
|
||
|
END IF;
|
||
|
ELSIF Sys_clk'event AND Sys_clk = '1' AND Load = '1' AND Dump = '0' THEN --'
|
||
|
Operation <= LOAD_FILE;
|
||
|
load := '0';
|
||
|
-- ASSERT (FALSE) REPORT "Reading memory array from file. This operation may take several minutes. Please wait..."
|
||
|
-- SEVERITY NOTE;
|
||
|
WHILE NOT endfile(file_load) LOOP
|
||
|
readline(file_load, l);
|
||
|
read(l, ch);
|
||
|
if (ch /= 'S') or (ch /= 's') then
|
||
|
hexread(l, rectype);
|
||
|
hexread(l, reclen);
|
||
|
recaddr := (others => '0');
|
||
|
case rectype is
|
||
|
when "0001" =>
|
||
|
hexread(l, recaddr(15 downto 0));
|
||
|
when "0010" =>
|
||
|
hexread(l, recaddr(23 downto 0));
|
||
|
when "0011" =>
|
||
|
hexread(l, recaddr);
|
||
|
recaddr(31 downto 24) := (others => '0');
|
||
|
when others => next;
|
||
|
end case;
|
||
|
if true then
|
||
|
hexread(l, recdata);
|
||
|
Bank_Load := recaddr(25 downto 24);
|
||
|
Rows_Load := recaddr(23 downto 11);
|
||
|
Cols_Load := recaddr(10 downto 2);
|
||
|
Init_Mem (Bank_Load, To_Integer(Rows_Load));
|
||
|
|
||
|
IF Bank_Load = "00" THEN
|
||
|
for i in 0 to 3 loop
|
||
|
Bank0 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := ('1' & recdata(i*32+index to i*32+index+15));
|
||
|
end loop;
|
||
|
ELSIF Bank_Load = "01" THEN
|
||
|
for i in 0 to 3 loop
|
||
|
Bank1 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := ('1' & recdata(i*32+index to i*32+index+15));
|
||
|
end loop;
|
||
|
ELSIF Bank_Load = "10" THEN
|
||
|
for i in 0 to 3 loop
|
||
|
Bank2 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := ('1' & recdata(i*32+index to i*32+index+15));
|
||
|
end loop;
|
||
|
ELSIF Bank_Load = "11" THEN
|
||
|
for i in 0 to 3 loop
|
||
|
Bank3 (To_Integer(Rows_Load)) (To_Integer(Cols_Load)+i) := ('1' & recdata(i*32+index to i*32+index+15));
|
||
|
end loop;
|
||
|
END IF;
|
||
|
|
||
|
END IF;
|
||
|
END IF;
|
||
|
END LOOP;
|
||
|
ELSIF Sys_clk'event AND Sys_clk = '1' AND Load = '0' AND Dump = '1' THEN --'
|
||
|
Operation <= DUMP_FILE;
|
||
|
ASSERT (FALSE) REPORT "Writing memory array to file. This operation may take several minutes. Please wait..."
|
||
|
SEVERITY NOTE;
|
||
|
WRITE (l, string'("# Micron Technology, Inc. (FILE DUMP / MEMORY DUMP)")); --'
|
||
|
WRITELINE (file_dump, l);
|
||
|
WRITE (l, string'("# BA ROWS COLS DQ")); --'
|
||
|
WRITELINE (file_dump, l);
|
||
|
WRITE (l, string'("# -- ------------- --------- ----------------")); --'
|
||
|
WRITELINE (file_dump, l);
|
||
|
-- Dumping Bank 0
|
||
|
FOR i IN 0 TO 2**addr_bits -1 LOOP
|
||
|
-- Check if ROW is NULL
|
||
|
IF Bank0 (i) /= NULL THEN
|
||
|
For j IN 0 TO 2**col_bits - 1 LOOP
|
||
|
-- Check if COL is NULL
|
||
|
NEXT WHEN Bank0 (i) (j) (data_bits) = '0';
|
||
|
WRITE (l, string'("00"), right, 4); --'
|
||
|
WRITE (l, To_BitVector(Conv_Std_Logic_Vector(i, addr_bits)), right, addr_bits+1);
|
||
|
WRITE (l, To_BitVector(Conv_std_Logic_Vector(j, col_bits)), right, col_bits+1);
|
||
|
WRITE (l, Bank0 (i) (j) (data_bits -1 DOWNTO 0), right, data_bits+1);
|
||
|
WRITELINE (file_dump, l);
|
||
|
END LOOP;
|
||
|
END IF;
|
||
|
END LOOP;
|
||
|
-- Dumping Bank 1
|
||
|
FOR i IN 0 TO 2**addr_bits -1 LOOP
|
||
|
-- Check if ROW is NULL
|
||
|
IF Bank1 (i) /= NULL THEN
|
||
|
For j IN 0 TO 2**col_bits - 1 LOOP
|
||
|
-- Check if COL is NULL
|
||
|
NEXT WHEN Bank1 (i) (j) (data_bits) = '0';
|
||
|
WRITE (l, string'("01"), right, 4); --'
|
||
|
WRITE (l, To_BitVector(Conv_Std_Logic_Vector(i, addr_bits)), right, addr_bits+1);
|
||
|
WRITE (l, To_BitVector(Conv_std_Logic_Vector(j, col_bits)), right, col_bits+1);
|
||
|
WRITE (l, Bank1 (i) (j) (data_bits -1 DOWNTO 0), right, data_bits+1);
|
||
|
WRITELINE (file_dump, l);
|
||
|
END LOOP;
|
||
|
END IF;
|
||
|
END LOOP;
|
||
|
-- Dumping Bank 2
|
||
|
FOR i IN 0 TO 2**addr_bits -1 LOOP
|
||
|
-- Check if ROW is NULL
|
||
|
IF Bank2 (i) /= NULL THEN
|
||
|
For j IN 0 TO 2**col_bits - 1 LOOP
|
||
|
-- Check if COL is NULL
|
||
|
NEXT WHEN Bank2 (i) (j) (data_bits) = '0';
|
||
|
WRITE (l, string'("10"), right, 4); --'
|
||
|
WRITE (l, To_BitVector(Conv_Std_Logic_Vector(i, addr_bits)), right, addr_bits+1);
|
||
|
WRITE (l, To_BitVector(Conv_std_Logic_Vector(j, col_bits)), right, col_bits+1);
|
||
|
WRITE (l, Bank2 (i) (j) (data_bits -1 DOWNTO 0), right, data_bits+1);
|
||
|
WRITELINE (file_dump, l);
|
||
|
END LOOP;
|
||
|
END IF;
|
||
|
END LOOP;
|
||
|
-- Dumping Bank 3
|
||
|
FOR i IN 0 TO 2**addr_bits -1 LOOP
|
||
|
-- Check if ROW is NULL
|
||
|
IF Bank3 (i) /= NULL THEN
|
||
|
For j IN 0 TO 2**col_bits - 1 LOOP
|
||
|
-- Check if COL is NULL
|
||
|
NEXT WHEN Bank3 (i) (j) (data_bits) = '0';
|
||
|
WRITE (l, string'("11"), right, 4); --'
|
||
|
WRITE (l, To_BitVector(Conv_Std_Logic_Vector(i, addr_bits)), right, addr_bits+1);
|
||
|
WRITE (l, To_BitVector(Conv_std_Logic_Vector(j, col_bits)), right, col_bits+1);
|
||
|
WRITE (l, Bank3 (i) (j) (data_bits -1 DOWNTO 0), right, data_bits+1);
|
||
|
WRITELINE (file_dump, l);
|
||
|
END LOOP;
|
||
|
END IF;
|
||
|
END LOOP;
|
||
|
END IF;
|
||
|
|
||
|
-- Write with AutoPrecharge Calculation
|
||
|
-- The device start internal precharge when:
|
||
|
-- 1. tWR cycles after command
|
||
|
-- and 2. Meet tRAS requirement
|
||
|
-- or 3. Interrupt by a Read or Write (with or without Auto Precharge)
|
||
|
IF ((Auto_precharge(0) = '1') AND (Write_precharge(0) = '1')) THEN
|
||
|
IF (((NOW - RAS_chk0 >= tRAS) AND
|
||
|
(((Burst_length_1 = '1' OR Write_burst_mode = '1' ) AND Count_precharge(0) >= 1 AND NOW - Count_time(0) >= tWRa) OR
|
||
|
(Burst_length_2 = '1' AND Count_precharge(0) >= 2 AND NOW - Count_time(0) >= tWRa) OR
|
||
|
(Burst_length_4 = '1' AND Count_precharge(0) >= 4 AND NOW - Count_time(0) >= tWRa) OR
|
||
|
(Burst_length_8 = '1' AND Count_precharge(0) >= 8 AND NOW - Count_time(0) >= tWRa))) OR
|
||
|
(RW_interrupt_write(0) = '1' AND WR_counter(0) >= 1 AND NOW - WR_time(0) >= tWRa)) THEN
|
||
|
Auto_precharge(0) := '0';
|
||
|
Write_precharge(0) := '0';
|
||
|
RW_interrupt_write(0) := '0';
|
||
|
Pc_b0 := '1';
|
||
|
Act_b0 := '0';
|
||
|
RP_chk0 := NOW;
|
||
|
ASSERT FALSE REPORT "Start Internal Precharge Bank 0" SEVERITY NOTE;
|
||
|
END IF;
|
||
|
END IF;
|
||
|
IF ((Auto_precharge(1) = '1') AND (Write_precharge(1) = '1')) THEN
|
||
|
IF (((NOW - RAS_chk1 >= tRAS) AND
|
||
|
(((Burst_length_1 = '1' OR Write_burst_mode = '1' ) AND Count_precharge(1) >= 1 AND NOW - Count_time(1) >= tWRa) OR
|
||
|
(Burst_length_2 = '1' AND Count_precharge(1) >= 2 AND NOW - Count_time(1) >= tWRa) OR
|
||
|
(Burst_length_4 = '1' AND Count_precharge(1) >= 4 AND NOW - Count_time(1) >= tWRa) OR
|
||
|
(Burst_length_8 = '1' AND Count_precharge(1) >= 8 AND NOW - Count_time(1) >= tWRa))) OR
|
||
|
(RW_interrupt_write(1) = '1' AND WR_counter(1) >= 1 AND NOW - WR_time(1) >= tWRa)) THEN
|
||
|
Auto_precharge(1) := '0';
|
||
|
Write_precharge(1) := '0';
|
||
|
RW_interrupt_write(1) := '0';
|
||
|
Pc_b1 := '1';
|
||
|
Act_b1 := '0';
|
||
|
RP_chk1 := NOW;
|
||
|
END IF;
|
||
|
END IF;
|
||
|
IF ((Auto_precharge(2) = '1') AND (Write_precharge(2) = '1')) THEN
|
||
|
IF (((NOW - RAS_chk2 >= tRAS) AND
|
||
|
(((Burst_length_1 = '1' OR Write_burst_mode = '1' ) AND Count_precharge(2) >= 1 AND NOW - Count_time(2) >= tWRa) OR
|
||
|
(Burst_length_2 = '1' AND Count_precharge(2) >= 2 AND NOW - Count_time(2) >= tWRa) OR
|
||
|
(Burst_length_4 = '1' AND Count_precharge(2) >= 4 AND NOW - Count_time(2) >= tWRa) OR
|
||
|
(Burst_length_8 = '1' AND Count_precharge(2) >= 8 AND NOW - Count_time(2) >= tWRa))) OR
|
||
|
(RW_interrupt_write(2) = '1' AND WR_counter(2) >= 1 AND NOW - WR_time(2) >= tWRa)) THEN
|
||
|
Auto_precharge(2) := '0';
|
||
|
Write_precharge(2) := '0';
|
||
|
RW_interrupt_write(2) := '0';
|
||
|
Pc_b2 := '1';
|
||
|
Act_b2 := '0';
|
||
|
RP_chk2 := NOW;
|
||
|
END IF;
|
||
|
END IF;
|
||
|
IF ((Auto_precharge(3) = '1') AND (Write_precharge(3) = '1')) THEN
|
||
|
IF (((NOW - RAS_chk3 >= tRAS) AND
|
||
|
(((Burst_length_1 = '1' OR Write_burst_mode = '1' ) AND Count_precharge(3) >= 1 AND NOW - Count_time(3) >= tWRa) OR
|
||
|
(Burst_length_2 = '1' AND Count_precharge(3) >= 2 AND NOW - Count_time(3) >= tWRa) OR
|
||
|
(Burst_length_4 = '1' AND Count_precharge(3) >= 4 AND NOW - Count_time(3) >= tWRa) OR
|
||
|
(Burst_length_8 = '1' AND Count_precharge(3) >= 8 AND NOW - Count_time(3) >= tWRa))) OR
|
||
|
(RW_interrupt_write(0) = '1' AND WR_counter(0) >= 1 AND NOW - WR_time(3) >= tWRa)) THEN
|
||
|
Auto_precharge(3) := '0';
|
||
|
Write_precharge(3) := '0';
|
||
|
RW_interrupt_write(3) := '0';
|
||
|
Pc_b3 := '1';
|
||
|
Act_b3 := '0';
|
||
|
RP_chk3 := NOW;
|
||
|
END IF;
|
||
|
END IF;
|
||
|
|
||
|
-- Checking internal wires (Optional for debug purpose)
|
||
|
Pre_chk (0) <= Pc_b0;
|
||
|
Pre_chk (1) <= Pc_b1;
|
||
|
Pre_chk (2) <= Pc_b2;
|
||
|
Pre_chk (3) <= Pc_b3;
|
||
|
Act_chk (0) <= Act_b0;
|
||
|
Act_chk (1) <= Act_b1;
|
||
|
Act_chk (2) <= Act_b2;
|
||
|
Act_chk (3) <= Act_b3;
|
||
|
Dq_in_chk <= Data_in_enable;
|
||
|
Dq_out_chk <= Data_out_enable;
|
||
|
Bank_chk <= Bank;
|
||
|
Row_chk <= Row;
|
||
|
Col_chk <= Col;
|
||
|
END PROCESS;
|
||
|
|
||
|
|
||
|
-- Clock timing checks
|
||
|
-- Clock_check : PROCESS
|
||
|
-- VARIABLE Clk_low, Clk_high : TIME := 0 ns;
|
||
|
-- BEGIN
|
||
|
-- WAIT ON Clk;
|
||
|
-- IF (Clk = '1' AND NOW >= 10 ns) THEN
|
||
|
-- ASSERT (NOW - Clk_low >= tCL)
|
||
|
-- REPORT "tCL violation"
|
||
|
-- SEVERITY WARNING;
|
||
|
-- ASSERT (NOW - Clk_high >= tCK)
|
||
|
-- REPORT "tCK violation"
|
||
|
-- SEVERITY WARNING;
|
||
|
-- Clk_high := NOW;
|
||
|
-- ELSIF (Clk = '0' AND NOW /= 0 ns) THEN
|
||
|
-- ASSERT (NOW - Clk_high >= tCH)
|
||
|
-- REPORT "tCH violation"
|
||
|
-- SEVERITY WARNING;
|
||
|
-- Clk_low := NOW;
|
||
|
-- END IF;
|
||
|
-- END PROCESS;
|
||
|
|
||
|
-- Setup timing checks
|
||
|
Setup_check : PROCESS
|
||
|
BEGIN
|
||
|
wait;
|
||
|
WAIT ON Clk;
|
||
|
IF Clk = '1' THEN
|
||
|
ASSERT(Cke'LAST_EVENT >= tCKS) --'
|
||
|
REPORT "CKE Setup time violation -- tCKS"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Cs_n'LAST_EVENT >= tCMS) --'
|
||
|
REPORT "CS# Setup time violation -- tCMS"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Cas_n'LAST_EVENT >= tCMS) --'
|
||
|
REPORT "CAS# Setup time violation -- tCMS"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Ras_n'LAST_EVENT >= tCMS) --'
|
||
|
REPORT "RAS# Setup time violation -- tCMS"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(We_n'LAST_EVENT >= tCMS) --'
|
||
|
REPORT "WE# Setup time violation -- tCMS"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Dqm'LAST_EVENT >= tCMS) --'
|
||
|
REPORT "Dqm Setup time violation -- tCMS"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Addr'LAST_EVENT >= tAS) --'
|
||
|
REPORT "ADDR Setup time violation -- tAS"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Ba'LAST_EVENT >= tAS) --'
|
||
|
REPORT "BA Setup time violation -- tAS"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Dq'LAST_EVENT >= tDS) --'
|
||
|
REPORT "Dq Setup time violation -- tDS"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
END PROCESS;
|
||
|
|
||
|
-- Hold timing checks
|
||
|
Hold_check : PROCESS
|
||
|
BEGIN
|
||
|
wait;
|
||
|
WAIT ON Clk'DELAYED (tCKH), Clk'DELAYED (tCMH), Clk'DELAYED (tAH), Clk'DELAYED (tDH);
|
||
|
IF Clk'DELAYED (tCKH) = '1' THEN --'
|
||
|
ASSERT(Cke'LAST_EVENT > tCKH) --'
|
||
|
REPORT "CKE Hold time violation -- tCKH"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
IF Clk'DELAYED (tCMH) = '1' THEN --'
|
||
|
ASSERT(Cs_n'LAST_EVENT > tCMH) --'
|
||
|
REPORT "CS# Hold time violation -- tCMH"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Cas_n'LAST_EVENT > tCMH) --'
|
||
|
REPORT "CAS# Hold time violation -- tCMH"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Ras_n'LAST_EVENT > tCMH) --'
|
||
|
REPORT "RAS# Hold time violation -- tCMH"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(We_n'LAST_EVENT > tCMH) --'
|
||
|
REPORT "WE# Hold time violation -- tCMH"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Dqm'LAST_EVENT > tCMH) --'
|
||
|
REPORT "Dqm Hold time violation -- tCMH"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
IF Clk'DELAYED (tAH) = '1' THEN --'
|
||
|
ASSERT(Addr'LAST_EVENT > tAH) --'
|
||
|
REPORT "ADDR Hold time violation -- tAH"
|
||
|
SEVERITY WARNING;
|
||
|
ASSERT(Ba'LAST_EVENT > tAH) --'
|
||
|
REPORT "BA Hold time violation -- tAH"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
IF Clk'DELAYED (tDH) = '1' THEN --'
|
||
|
ASSERT(Dq'LAST_EVENT > tDH) --'
|
||
|
REPORT "Dq Hold time violation -- tDH"
|
||
|
SEVERITY WARNING;
|
||
|
END IF;
|
||
|
END PROCESS;
|
||
|
|
||
|
END ARCHITECTURE sim;
|
||
|
|