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memc3_infrastructure.vhd
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memc3_infrastructure.vhd
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--*****************************************************************************
-- (c) Copyright 2009 Xilinx, Inc. All rights reserved.
--
-- This file contains confidential and proprietary information
-- of Xilinx, Inc. and is protected under U.S. and
-- international copyright and other intellectual property
-- laws.
--
-- DISCLAIMER
-- This disclaimer is not a license and does not grant any
-- rights to the materials distributed herewith. Except as
-- otherwise provided in a valid license issued to you by
-- Xilinx, and to the maximum extent permitted by applicable
-- law: (1) THESE MATERIALS ARE MADE AVAILABLE "AS IS" AND
-- WITH ALL FAULTS, AND XILINX HEREBY DISCLAIMS ALL WARRANTIES
-- AND CONDITIONS, EXPRESS, IMPLIED, OR STATUTORY, INCLUDING
-- BUT NOT LIMITED TO WARRANTIES OF MERCHANTABILITY, NON-
-- INFRINGEMENT, OR FITNESS FOR ANY PARTICULAR PURPOSE; and
-- (2) Xilinx shall not be liable (whether in contract or tort,
-- including negligence, or under any other theory of
-- liability) for any loss or damage of any kind or nature
-- related to, arising under or in connection with these
-- materials, including for any direct, or any indirect,
-- special, incidental, or consequential loss or damage
-- (including loss of data, profits, goodwill, or any type of
-- loss or damage suffered as a result of any action brought
-- by a third party) even if such damage or loss was
-- reasonably foreseeable or Xilinx had been advised of the
-- possibility of the same.
--
-- CRITICAL APPLICATIONS
-- Xilinx products are not designed or intended to be fail-
-- safe, or for use in any application requiring fail-safe
-- performance, such as life-support or safety devices or
-- systems, Class III medical devices, nuclear facilities,
-- applications related to the deployment of airbags, or any
-- other applications that could lead to death, personal
-- injury, or severe property or environmental damage
-- (individually and collectively, "Critical
-- Applications"). Customer assumes the sole risk and
-- liability of any use of Xilinx products in Critical
-- Applications, subject only to applicable laws and
-- regulations governing limitations on product liability.
--
-- THIS COPYRIGHT NOTICE AND DISCLAIMER MUST BE RETAINED AS
-- PART OF THIS FILE AT ALL TIMES.
--
--*****************************************************************************
-- ____ ____
-- / /\/ /
-- /___/ \ / Vendor : Xilinx
-- \ \ \/ Version : 3.91
-- \ \ Application : MIG
-- / / Filename : memc3_infrastructure.vhd
-- /___/ /\ Date Last Modified : $Date: 2011/06/02 07:16:56 $
-- \ \ / \ Date Created : Jul 03 2009
-- \___\/\___\
--
--Device : Spartan-6
--Design Name : DDR/DDR2/DDR3/LPDDR
--Purpose : Clock generation/distribution and reset synchronization
--Reference :
--Revision History :
--*****************************************************************************
library ieee;
use ieee.std_logic_1164.all;
library unisim;
use unisim.vcomponents.all;
entity memc3_infrastructure is
generic
(
C_INCLK_PERIOD : integer := 2500;
C_RST_ACT_LOW : integer := 1;
C_INPUT_CLK_TYPE : string := "DIFFERENTIAL";
C_CLKOUT0_DIVIDE : integer := 1;
C_CLKOUT1_DIVIDE : integer := 1;
C_CLKOUT2_DIVIDE : integer := 16;
C_CLKOUT3_DIVIDE : integer := 8;
C_CLKFBOUT_MULT : integer := 2;
C_DIVCLK_DIVIDE : integer := 1
);
port
(
sys_clk_p : in std_logic;
sys_clk_n : in std_logic;
sys_clk : in std_logic;
sys_rst_i : in std_logic;
clk0 : out std_logic;
rst0 : out std_logic;
async_rst : out std_logic;
sysclk_2x : out std_logic;
sysclk_2x_180 : out std_logic;
mcb_drp_clk : out std_logic;
pll_ce_0 : out std_logic;
pll_ce_90 : out std_logic;
pll_lock : out std_logic
);
end entity;
architecture syn of memc3_infrastructure is
-- # of clock cycles to delay deassertion of reset. Needs to be a fairly
-- high number not so much for metastability protection, but to give time
-- for reset (i.e. stable clock cycles) to propagate through all state
-- machines and to all control signals (i.e. not all control signals have
-- resets, instead they rely on base state logic being reset, and the effect
-- of that reset propagating through the logic). Need this because we may not
-- be getting stable clock cycles while reset asserted (i.e. since reset
-- depends on PLL/DCM lock status)
constant RST_SYNC_NUM : integer := 25;
constant CLK_PERIOD_NS : real := (real(C_INCLK_PERIOD)) / 1000.0;
constant CLK_PERIOD_INT : integer := C_INCLK_PERIOD/1000;
signal clk_2x_0 : std_logic;
signal clk_2x_180 : std_logic;
signal clk0_bufg : std_logic;
signal clk0_bufg_in : std_logic;
signal mcb_drp_clk_bufg_in : std_logic;
signal clkfbout_clkfbin : std_logic;
signal rst_tmp : std_logic;
signal sys_clk_ibufg : std_logic;
signal sys_rst : std_logic;
signal rst0_sync_r : std_logic_vector(RST_SYNC_NUM-1 downto 0);
signal powerup_pll_locked : std_logic;
signal syn_clk0_powerup_pll_locked : std_logic;
signal locked : std_logic;
signal bufpll_mcb_locked : std_logic;
signal mcb_drp_clk_sig : std_logic;
attribute max_fanout : string;
attribute syn_maxfan : integer;
attribute KEEP : string;
attribute max_fanout of rst0_sync_r : signal is "10";
attribute syn_maxfan of rst0_sync_r : signal is 10;
attribute KEEP of sys_clk_ibufg : signal is "TRUE";
begin
sys_rst <= not(sys_rst_i) when (C_RST_ACT_LOW /= 0) else sys_rst_i;
clk0 <= clk0_bufg;
pll_lock <= bufpll_mcb_locked;
mcb_drp_clk <= mcb_drp_clk_sig;
diff_input_clk : if(C_INPUT_CLK_TYPE = "DIFFERENTIAL") generate
--***********************************************************************
-- Differential input clock input buffers
--***********************************************************************
u_ibufg_sys_clk : IBUFGDS
generic map (
DIFF_TERM => TRUE
)
port map (
I => sys_clk_p,
IB => sys_clk_n,
O => sys_clk_ibufg
);
end generate;
se_input_clk : if(C_INPUT_CLK_TYPE = "SINGLE_ENDED") generate
--***********************************************************************
-- SINGLE_ENDED input clock input buffers
--***********************************************************************
u_ibufg_sys_clk : IBUFG
port map (
I => sys_clk,
O => sys_clk_ibufg
);
end generate;
--***************************************************************************
-- Global clock generation and distribution
--***************************************************************************
u_pll_adv : PLL_ADV
generic map
(
BANDWIDTH => "OPTIMIZED",
CLKIN1_PERIOD => CLK_PERIOD_NS,
CLKIN2_PERIOD => CLK_PERIOD_NS,
CLKOUT0_DIVIDE => C_CLKOUT0_DIVIDE,
CLKOUT1_DIVIDE => C_CLKOUT1_DIVIDE,
CLKOUT2_DIVIDE => C_CLKOUT2_DIVIDE,
CLKOUT3_DIVIDE => C_CLKOUT3_DIVIDE,
CLKOUT4_DIVIDE => 1,
CLKOUT5_DIVIDE => 1,
CLKOUT0_PHASE => 0.000,
CLKOUT1_PHASE => 180.000,
CLKOUT2_PHASE => 0.000,
CLKOUT3_PHASE => 0.000,
CLKOUT4_PHASE => 0.000,
CLKOUT5_PHASE => 0.000,
CLKOUT0_DUTY_CYCLE => 0.500,
CLKOUT1_DUTY_CYCLE => 0.500,
CLKOUT2_DUTY_CYCLE => 0.500,
CLKOUT3_DUTY_CYCLE => 0.500,
CLKOUT4_DUTY_CYCLE => 0.500,
CLKOUT5_DUTY_CYCLE => 0.500,
SIM_DEVICE => "SPARTAN6",
COMPENSATION => "INTERNAL",
DIVCLK_DIVIDE => C_DIVCLK_DIVIDE,
CLKFBOUT_MULT => C_CLKFBOUT_MULT,
CLKFBOUT_PHASE => 0.0,
REF_JITTER => 0.005000
)
port map
(
CLKFBIN => clkfbout_clkfbin,
CLKINSEL => '1',
CLKIN1 => sys_clk_ibufg,
CLKIN2 => '0',
DADDR => (others => '0'),
DCLK => '0',
DEN => '0',
DI => (others => '0'),
DWE => '0',
REL => '0',
RST => sys_rst,
CLKFBDCM => open,
CLKFBOUT => clkfbout_clkfbin,
CLKOUTDCM0 => open,
CLKOUTDCM1 => open,
CLKOUTDCM2 => open,
CLKOUTDCM3 => open,
CLKOUTDCM4 => open,
CLKOUTDCM5 => open,
CLKOUT0 => clk_2x_0,
CLKOUT1 => clk_2x_180,
CLKOUT2 => clk0_bufg_in,
CLKOUT3 => mcb_drp_clk_bufg_in,
CLKOUT4 => open,
CLKOUT5 => open,
DO => open,
DRDY => open,
LOCKED => locked
);
U_BUFG_CLK0 : BUFG
port map
(
O => clk0_bufg,
I => clk0_bufg_in
);
--U_BUFG_CLK1 : BUFG
-- port map (
-- O => mcb_drp_clk_sig,
-- I => mcb_drp_clk_bufg_in
-- );
U_BUFG_CLK1 : BUFGCE
port map (
O => mcb_drp_clk_sig,
I => mcb_drp_clk_bufg_in,
CE => locked
);
process (mcb_drp_clk_sig, sys_rst)
begin
if(sys_rst = '1') then
powerup_pll_locked <= '0';
elsif (mcb_drp_clk_sig'event and mcb_drp_clk_sig = '1') then
if (bufpll_mcb_locked = '1') then
powerup_pll_locked <= '1';
end if;
end if;
end process;
process (clk0_bufg, sys_rst)
begin
if(sys_rst = '1') then
syn_clk0_powerup_pll_locked <= '0';
elsif (clk0_bufg'event and clk0_bufg = '1') then
if (bufpll_mcb_locked = '1') then
syn_clk0_powerup_pll_locked <= '1';
end if;
end if;
end process;
--***************************************************************************
-- Reset synchronization
-- NOTES:
-- 1. shut down the whole operation if the PLL hasn't yet locked (and
-- by inference, this means that external sys_rst has been asserted -
-- PLL deasserts LOCKED as soon as sys_rst asserted)
-- 2. asynchronously assert reset. This was we can assert reset even if
-- there is no clock (needed for things like 3-stating output buffers).
-- reset deassertion is synchronous.
-- 3. asynchronous reset only look at pll_lock from PLL during power up. After
-- power up and pll_lock is asserted, the powerup_pll_locked will be asserted
-- forever until sys_rst is asserted again. PLL will lose lock when FPGA
-- enters suspend mode. We don't want reset to MCB get
-- asserted in the application that needs suspend feature.
--***************************************************************************
async_rst <= sys_rst or not(powerup_pll_locked);
-- async_rst <= rst_tmp;
rst_tmp <= sys_rst or not(syn_clk0_powerup_pll_locked);
-- rst_tmp <= sys_rst or not(powerup_pll_locked);
process (clk0_bufg, rst_tmp)
begin
if (rst_tmp = '1') then
rst0_sync_r <= (others => '1');
elsif (rising_edge(clk0_bufg)) then
rst0_sync_r <= rst0_sync_r(RST_SYNC_NUM-2 downto 0) & '0'; -- logical left shift by one (pads with 0)
end if;
end process;
rst0 <= rst0_sync_r(RST_SYNC_NUM-1);
BUFPLL_MCB_INST : BUFPLL_MCB
port map
( IOCLK0 => sysclk_2x,
IOCLK1 => sysclk_2x_180,
LOCKED => locked,
GCLK => mcb_drp_clk_sig,
SERDESSTROBE0 => pll_ce_0,
SERDESSTROBE1 => pll_ce_90,
PLLIN0 => clk_2x_0,
PLLIN1 => clk_2x_180,
LOCK => bufpll_mcb_locked
);
end architecture syn;