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infrastructure.v
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infrastructure.v
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//*****************************************************************************
// (c) Copyright 2010 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 : %version
// \ \ Application : MIG
// / / Filename : infrastructure.v
// /___/ /\ Date Last Modified : $Date: 2011/06/02 07:17:09 $
// \ \ / \ Date Created : Mon Mar 2 2009
// \___\/\___\
//
//Device : Spartan-6
//Design Name : DDR/DDR2/DDR3/LPDDR
//Purpose : Clock generation/distribution and reset synchronization
//Reference :
//Revision History :
//*****************************************************************************
`timescale 1ns/1ps
module infrastructure #
(
parameter C_INCLK_PERIOD = 2500,
parameter C_RST_ACT_LOW = 1,
parameter C_INPUT_CLK_TYPE = "DIFFERENTIAL",
parameter C_CLKOUT0_DIVIDE = 1,
parameter C_CLKOUT1_DIVIDE = 1,
parameter C_CLKOUT2_DIVIDE = 16,
parameter C_CLKOUT3_DIVIDE = 8,
parameter C_CLKFBOUT_MULT = 2,
parameter C_DIVCLK_DIVIDE = 1
)
(
input sys_clk_p,
input sys_clk_n,
input sys_clk,
input sys_rst_i,
output clk0,
output rst0,
output async_rst,
output sysclk_2x,
output sysclk_2x_180,
output mcb_drp_clk,
output pll_ce_0,
output pll_ce_90,
output pll_lock
);
// # 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)
localparam RST_SYNC_NUM = 25;
localparam CLK_PERIOD_NS = C_INCLK_PERIOD / 1000.0;
localparam CLK_PERIOD_INT = C_INCLK_PERIOD/1000;
wire clk_2x_0;
wire clk_2x_180;
wire clk0_bufg;
wire clk0_bufg_in;
wire mcb_drp_clk_bufg_in;
wire clkfbout_clkfbin;
wire locked;
reg [RST_SYNC_NUM-1:0] rst0_sync_r /* synthesis syn_maxfan = 10 */;
wire rst_tmp;
reg powerup_pll_locked;
reg syn_clk0_powerup_pll_locked;
wire sys_rst;
wire bufpll_mcb_locked;
(* KEEP = "TRUE" *) wire sys_clk_ibufg;
assign sys_rst = C_RST_ACT_LOW ? ~sys_rst_i: sys_rst_i;
assign clk0 = clk0_bufg;
assign pll_lock = bufpll_mcb_locked;
generate
if (C_INPUT_CLK_TYPE == "DIFFERENTIAL") begin: diff_input_clk
//***********************************************************************
// Differential input clock input buffers
//***********************************************************************
IBUFGDS #
(
.DIFF_TERM ("TRUE")
)
u_ibufg_sys_clk
(
.I (sys_clk_p),
.IB (sys_clk_n),
.O (sys_clk_ibufg)
);
end else if (C_INPUT_CLK_TYPE == "SINGLE_ENDED") begin: se_input_clk
//***********************************************************************
// SINGLE_ENDED input clock input buffers
//***********************************************************************
IBUFG u_ibufg_sys_clk
(
.I (sys_clk),
.O (sys_clk_ibufg)
);
end
endgenerate
//***************************************************************************
// Global clock generation and distribution
//***************************************************************************
PLL_ADV #
(
.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 (0.010000)
)
u_pll_adv
(
.CLKFBIN (clkfbout_clkfbin),
.CLKINSEL (1'b1),
.CLKIN1 (sys_clk_ibufg),
.CLKIN2 (1'b0),
.DADDR (5'b0),
.DCLK (1'b0),
.DEN (1'b0),
.DI (16'b0),
.DWE (1'b0),
.REL (1'b0),
.RST (sys_rst),
.CLKFBDCM (),
.CLKFBOUT (clkfbout_clkfbin),
.CLKOUTDCM0 (),
.CLKOUTDCM1 (),
.CLKOUTDCM2 (),
.CLKOUTDCM3 (),
.CLKOUTDCM4 (),
.CLKOUTDCM5 (),
.CLKOUT0 (clk_2x_0),
.CLKOUT1 (clk_2x_180),
.CLKOUT2 (clk0_bufg_in),
.CLKOUT3 (mcb_drp_clk_bufg_in),
.CLKOUT4 (),
.CLKOUT5 (),
.DO (),
.DRDY (),
.LOCKED (locked)
);
BUFG U_BUFG_CLK0
(
.O (clk0_bufg),
.I (clk0_bufg_in)
);
BUFGCE U_BUFG_CLK1
(
.O (mcb_drp_clk),
.I (mcb_drp_clk_bufg_in),
.CE (locked)
);
always @(posedge mcb_drp_clk , posedge sys_rst)
if(sys_rst)
powerup_pll_locked <= 1'b0;
else if (bufpll_mcb_locked)
powerup_pll_locked <= 1'b1;
always @(posedge clk0_bufg , posedge sys_rst)
if(sys_rst)
syn_clk0_powerup_pll_locked <= 1'b0;
else if (bufpll_mcb_locked)
syn_clk0_powerup_pll_locked <= 1'b1;
//***************************************************************************
// 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_IN has been asserted -
// PLL deasserts LOCKED as soon as SYS_RST_IN 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.
//***************************************************************************
assign async_rst = sys_rst | ~powerup_pll_locked;
// synthesis attribute max_fanout of rst0_sync_r is 10
assign rst_tmp = sys_rst | ~syn_clk0_powerup_pll_locked;
always @(posedge clk0_bufg or posedge rst_tmp)
if (rst_tmp)
rst0_sync_r <= {RST_SYNC_NUM{1'b1}};
else
// logical left shift by one (pads with 0)
rst0_sync_r <= rst0_sync_r << 1;
assign rst0 = rst0_sync_r[RST_SYNC_NUM-1];
BUFPLL_MCB BUFPLL_MCB1
( .IOCLK0 (sysclk_2x),
.IOCLK1 (sysclk_2x_180),
.LOCKED (locked),
.GCLK (mcb_drp_clk),
.SERDESSTROBE0 (pll_ce_0),
.SERDESSTROBE1 (pll_ce_90),
.PLLIN0 (clk_2x_0),
.PLLIN1 (clk_2x_180),
.LOCK (bufpll_mcb_locked)
);
endmodule