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|
// ===========================================================================
// >>>>>>>>>>>>>>>>>>>>>>> COPYRIGHT NOTICE <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
// ---------------------------------------------------------------------------
// Copyright (c) 2015 by Lattice Semiconductor Corporation
// ALL RIGHTS RESERVED
// ------------------------------------------------------------------
//
// Permission:
//
// Lattice SG Pte. Ltd. grants permission to use this code
// pursuant to the terms of the Lattice Reference Design License Agreement.
//
//
// Disclaimer:
//
// This VHDL or Verilog source code is intended as a design reference
// which illustrates how these types of functions can be implemented.
// It is the user's responsibility to verify their design for
// consistency and functionality through the use of formal
// verification methods. Lattice provides no warranty
// regarding the use or functionality of this code.
//
// ---------------------------------------------------------------------------
//
// Lattice SG Pte. Ltd.
// 101 Thomson Road, United Square #07-02
// Singapore 307591
//
//
// TEL: 1-800-Lattice (USA and Canada)
// +65-6631-2000 (Singapore)
// +1-503-268-8001 (other locations)
//
// web: http://www.latticesemi.com/
// email: techsupport@latticesemi.com
//
// ---------------------------------------------------------------------------
//
// =============================================================================
// FILE DETAILS
// Project : SLL - Soft Loss Of Lock(LOL) Logic
// File : sll_core.v
// Title : Top-level file for SLL
// Dependencies : 1.
// : 2.
// Description :
// =============================================================================
// REVISION HISTORY
// Version : 1.0
// Author(s) : AV
// Mod. Date : March 2, 2015
// Changes Made : Initial Creation
// =============================================================================
// REVISION HISTORY
// Version : 1.1
// Author(s) : AV
// Mod. Date : June 8, 2015
// Changes Made : Following updates were made
// : 1. Changed all the PLOL status logic and FSM to run
// : on sli_refclk.
// : 2. Added the HB logic for presence of tx_pclk
// : 3. Changed the lparam assignment scheme for
// : simulation purposes.
// =============================================================================
// REVISION HISTORY
// Version : 1.2
// Author(s) : AV
// Mod. Date : June 24, 2015
// Changes Made : Updated the gearing logic for SDI dynamic rate change
// =============================================================================
// REVISION HISTORY
// Version : 1.3
// Author(s) : AV
// Mod. Date : July 14, 2015
// Changes Made : Added the logic for dynamic rate change in CPRI
// =============================================================================
// REVISION HISTORY
// Version : 1.4
// Author(s) : AV
// Mod. Date : August 21, 2015
// Changes Made : Added the logic for dynamic rate change of 5G CPRI &
// PCIe.
// =============================================================================
// REVISION HISTORY
// Version : 1.5
// Author(s) : ES/EB
// Mod. Date : March 21, 2017
// Changes Made : 1. Added pdiff_sync signal to syncrhonize pcount_diff
// : to sli_refclk.
// : 2. Updated terminal count logic for PCIe 5G
// : 3. Modified checking of pcount_diff in SLL state
// : machine to cover actual count
// : (from 16-bits to 22-bits)
// =============================================================================
// REVISION HISTORY
// Version : 1.6
// Author(s) : ES
// Mod. Date : April 19, 2017
// Changes Made : 1. Added registered lock and unlock signal from
// pdiff_sync to totally decouple pcount_diff from
// SLL state machine.
// : 2. Modified LPCLK_TC_4 to 1:1 clock ratio when CPRI
// is operating @ 4.9125Gbps data rate.
// =============================================================================
`timescale 1ns/10ps
module sgmii2sll_core (
//Reset and Clock inputs
sli_rst, //Active high asynchronous reset input
sli_refclk, //Refclk input to the Tx PLL
sli_pclk, //Tx pclk output from the PCS
//Control inputs
sli_div2_rate, //Divide by 2 control; 0 - Full rate; 1 - Half rate
sli_div11_rate, //Divide by 11 control; 0 - Full rate; 1 - Div by 11
sli_gear_mode, //Gear mode control for PCS; 0 - 8/10; 1- 16/20
sli_cpri_mode, //Mode of operation specific to CPRI protocol
sli_pcie_mode, //Mode of operation specific to PCIe mode (2.5G or 5G)
//LOL Output
slo_plol //Tx PLL Loss of Lock output to the user logic
);
// Inputs
input sli_rst;
input sli_refclk;
input sli_pclk;
input sli_div2_rate;
input sli_div11_rate;
input sli_gear_mode;
input [2:0] sli_cpri_mode;
input sli_pcie_mode;
// Outputs
output slo_plol;
// Parameters
parameter PPROTOCOL = "PCIE"; //Protocol selected by the User
parameter PLOL_SETTING = 0; //PLL LOL setting. Possible values are 0,1,2,3
parameter PDYN_RATE_CTRL = "DISABLED"; //PCS Dynamic Rate control
parameter PPCIE_MAX_RATE = "2.5"; //PCIe max data rate
parameter PDIFF_VAL_LOCK = 20; //Differential count value for Lock
parameter PDIFF_VAL_UNLOCK = 39; //Differential count value for Unlock
parameter PPCLK_TC = 65535; //Terminal count value for counter running on sli_pclk
parameter PDIFF_DIV11_VAL_LOCK = 3; //Differential count value for Lock for SDI Div11
parameter PDIFF_DIV11_VAL_UNLOCK = 3; //Differential count value for Unlock for SDI Div11
parameter PPCLK_DIV11_TC = 2383; //Terminal count value (SDI Div11) for counter running on sli_pclk
// Local Parameters
localparam [1:0] LPLL_LOSS_ST = 2'b00; //PLL Loss state
localparam [1:0] LPLL_PRELOSS_ST = 2'b01; //PLL Pre-Loss state
localparam [1:0] LPLL_PRELOCK_ST = 2'b10; //PLL Pre-Lock state
localparam [1:0] LPLL_LOCK_ST = 2'b11; //PLL Lock state
`ifdef RSL_SIM_MODE
localparam [15:0] LRCLK_TC = 16'd63; //Terminal count value for counter running on sli_refclk
`else
localparam [15:0] LRCLK_TC = 16'd65535; //Terminal count value for counter running on sli_refclk
`endif
localparam [15:0] LRCLK_TC_PUL_WIDTH = 16'd50; //Pulse width for the Refclk terminal count pulse
localparam [7:0] LHB_WAIT_CNT = 8'd255; //Wait count for the Heartbeat signal
// Local Parameters related to the CPRI dynamic modes
// Terminal count values for the four CPRI modes
localparam LPCLK_TC_0 = 32768;
localparam LPCLK_TC_1 = 65536;
localparam LPCLK_TC_2 = 131072;
localparam LPCLK_TC_3 = 163840;
localparam LPCLK_TC_4 = 65536;
// Lock values count values for the four CPRI modes and four PLOL settings (4x5)
// CPRI rate mode 0 CPRI rate mode 1 CPRI rate mode 2 CPRI rate mode 3 CPRI rate mode 4
localparam LPDIFF_LOCK_00 = 9; localparam LPDIFF_LOCK_10 = 19; localparam LPDIFF_LOCK_20 = 39; localparam LPDIFF_LOCK_30 = 49; localparam LPDIFF_LOCK_40 = 19;
localparam LPDIFF_LOCK_01 = 9; localparam LPDIFF_LOCK_11 = 19; localparam LPDIFF_LOCK_21 = 39; localparam LPDIFF_LOCK_31 = 49; localparam LPDIFF_LOCK_41 = 19;
localparam LPDIFF_LOCK_02 = 49; localparam LPDIFF_LOCK_12 = 98; localparam LPDIFF_LOCK_22 = 196; localparam LPDIFF_LOCK_32 = 245; localparam LPDIFF_LOCK_42 = 98;
localparam LPDIFF_LOCK_03 = 131; localparam LPDIFF_LOCK_13 = 262; localparam LPDIFF_LOCK_23 = 524; localparam LPDIFF_LOCK_33 = 655; localparam LPDIFF_LOCK_43 = 262;
// Unlock values count values for the four CPRI modes and four PLOL settings (4x5)
// CPRI rate mode 0 CPRI rate mode 1 CPRI rate mode 2 CPRI rate mode 3 CPRI rate mode 4
localparam LPDIFF_UNLOCK_00 = 19; localparam LPDIFF_UNLOCK_10 = 39; localparam LPDIFF_UNLOCK_20 = 78; localparam LPDIFF_UNLOCK_30 = 98; localparam LPDIFF_UNLOCK_40 = 39;
localparam LPDIFF_UNLOCK_01 = 65; localparam LPDIFF_UNLOCK_11 = 131; localparam LPDIFF_UNLOCK_21 = 262; localparam LPDIFF_UNLOCK_31 = 327; localparam LPDIFF_UNLOCK_41 = 131;
localparam LPDIFF_UNLOCK_02 = 72; localparam LPDIFF_UNLOCK_12 = 144; localparam LPDIFF_UNLOCK_22 = 288; localparam LPDIFF_UNLOCK_32 = 360; localparam LPDIFF_UNLOCK_42 = 144;
localparam LPDIFF_UNLOCK_03 = 196; localparam LPDIFF_UNLOCK_13 = 393; localparam LPDIFF_UNLOCK_23 = 786; localparam LPDIFF_UNLOCK_33 = 983; localparam LPDIFF_UNLOCK_43 = 393;
// Input and Output reg and wire declarations
wire sli_rst;
wire sli_refclk;
wire sli_pclk;
wire sli_div2_rate;
wire sli_div11_rate;
wire sli_gear_mode;
wire [2:0] sli_cpri_mode;
wire sli_pcie_mode;
wire slo_plol;
//-------------- Internal signals reg and wire declarations --------------------
//Signals running on sli_refclk
reg [15:0] rcount; //16-bit Counter
reg rtc_pul; //Terminal count pulse
reg rtc_pul_p1; //Terminal count pulse pipeline
reg rtc_ctrl; //Terminal count pulse control
reg [7:0] rhb_wait_cnt; //Heartbeat wait counter
//Heatbeat synchronization and pipeline registers
wire rhb_sync;
reg rhb_sync_p2;
reg rhb_sync_p1;
//Pipeling registers for dynamic control mode
wire rgear;
wire rdiv2;
wire rdiv11;
reg rgear_p1;
reg rdiv2_p1;
reg rdiv11_p1;
reg rstat_pclk; //Pclk presence/absence status
reg [21:0] rcount_tc; //Tx_pclk terminal count register
reg [15:0] rdiff_comp_lock; //Differential comparison value for Lock
reg [15:0] rdiff_comp_unlock; //Differential compariosn value for Unlock
wire rpcie_mode; //PCIe mode signal synchronized to refclk
reg rpcie_mode_p1; //PCIe mode pipeline register
wire rcpri_mod_ch_sync; //CPRI mode change synchronized to refclk
reg rcpri_mod_ch_p1; //CPRI mode change pipeline register
reg rcpri_mod_ch_p2; //CPRI mode change pipeline register
reg rcpri_mod_ch_st; //CPRI mode change status
reg [1:0] sll_state; //Current-state register for LOL FSM
reg pll_lock; //PLL Lock signal
//Signals running on sli_pclk
//Synchronization and pipeline registers
wire ppul_sync;
reg ppul_sync_p1;
reg ppul_sync_p2;
reg ppul_sync_p3;
wire pdiff_sync;
reg pdiff_sync_p1;
reg [21:0] pcount; //22-bit counter
reg [21:0] pcount_diff; //Differential value between Tx_pclk counter and theoritical value
//Heartbeat counter and heartbeat signal running on pclk
reg [2:0] phb_cnt;
reg phb;
//CPRI dynamic mode releated signals
reg [2:0] pcpri_mode;
reg pcpri_mod_ch;
//Assignment scheme changed mainly for simulation purpose
wire [15:0] LRCLK_TC_w;
assign LRCLK_TC_w = LRCLK_TC;
reg unlock;
reg lock;
//Heartbeat synchronization
sync # (.PDATA_RST_VAL(0)) phb_sync_inst (
.clk (sli_refclk),
.rst (sli_rst),
.data_in (phb),
.data_out(rhb_sync)
);
//Terminal count pulse synchronization
sync # (.PDATA_RST_VAL(0)) rtc_sync_inst (
.clk (sli_pclk),
.rst (sli_rst),
.data_in (rtc_pul),
.data_out(ppul_sync)
);
//Differential value logic update synchronization
sync # (.PDATA_RST_VAL(0)) pdiff_sync_inst (
.clk (sli_refclk),
.rst (sli_rst),
.data_in (ppul_sync),
.data_out(pdiff_sync)
);
//Gear mode synchronization
sync # (.PDATA_RST_VAL(0)) gear_sync_inst (
.clk (sli_refclk),
.rst (sli_rst),
.data_in (sli_gear_mode),
.data_out(rgear)
);
//Div2 synchronization
sync # (.PDATA_RST_VAL(0)) div2_sync_inst (
.clk (sli_refclk),
.rst (sli_rst),
.data_in (sli_div2_rate),
.data_out(rdiv2)
);
//Div11 synchronization
sync # (.PDATA_RST_VAL(0)) div11_sync_inst (
.clk (sli_refclk),
.rst (sli_rst),
.data_in (sli_div11_rate),
.data_out(rdiv11)
);
//CPRI mode change synchronization
sync # (.PDATA_RST_VAL(0)) cpri_mod_sync_inst (
.clk (sli_refclk),
.rst (sli_rst),
.data_in (pcpri_mod_ch),
.data_out(rcpri_mod_ch_sync)
);
//PCIe mode change synchronization
sync # (.PDATA_RST_VAL(0)) pcie_mod_sync_inst (
.clk (sli_refclk),
.rst (sli_rst),
.data_in (sli_pcie_mode),
.data_out(rpcie_mode)
);
// =============================================================================
// Synchronized Lock/Unlock signals
// =============================================================================
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
unlock <= 1'b0;
lock <= 1'b0;
pdiff_sync_p1 <= 1'b0;
end
else begin
pdiff_sync_p1 <= pdiff_sync;
if (unlock) begin
unlock <= ~pdiff_sync && pdiff_sync_p1 ? 1'b0 : unlock;
end
else begin
unlock <= pdiff_sync ? (pcount_diff[21:0] > {6'd0, rdiff_comp_unlock}) : 1'b0;
end
if (lock) begin
lock <= ~pdiff_sync && pdiff_sync_p1 ? 1'b0 : lock;
end
else begin
lock <= pdiff_sync ? (pcount_diff[21:0] <= {6'd0, rdiff_comp_lock}) : 1'b0;
end
end
end
// =============================================================================
// Refclk Counter, pulse generation logic and Heartbeat monitor logic
// =============================================================================
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
rcount <= 16'd0;
rtc_pul <= 1'b0;
rtc_ctrl <= 1'b0;
rtc_pul_p1 <= 1'b0;
end
else begin
//Counter logic
if ((rgear_p1^rgear == 1'b1) || (rdiv2_p1^rdiv2 == 1'b1) || (rdiv11_p1^rdiv11 == 1'b1) || (rcpri_mod_ch_p1^rcpri_mod_ch_p2 == 1'b1) || (rpcie_mode_p1^rpcie_mode == 1'b1)) begin
if (rtc_ctrl == 1'b1) begin
rcount <= LRCLK_TC_PUL_WIDTH;
end
end
else begin
if (rcount != LRCLK_TC_w) begin
rcount <= rcount + 1;
end
else begin
rcount <= 16'd0;
end
end
//Pulse control logic
if (rcount == LRCLK_TC_w - 1) begin
rtc_ctrl <= 1'b1;
end
//Pulse Generation logic
if (rtc_ctrl == 1'b1) begin
if ((rcount == LRCLK_TC_w) || (rcount < LRCLK_TC_PUL_WIDTH)) begin
rtc_pul <= 1'b1;
end
else begin
rtc_pul <= 1'b0;
end
end
rtc_pul_p1 <= rtc_pul;
end
end
// =============================================================================
// Heartbeat synchronization & monitor logic and Dynamic mode pipeline logic
// =============================================================================
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
rhb_sync_p1 <= 1'b0;
rhb_sync_p2 <= 1'b0;
rhb_wait_cnt <= 8'd0;
rstat_pclk <= 1'b0;
rgear_p1 <= 1'b0;
rdiv2_p1 <= 1'b0;
rdiv11_p1 <= 1'b0;
rcpri_mod_ch_p1 <= 1'b0;
rcpri_mod_ch_p2 <= 1'b0;
rcpri_mod_ch_st <= 1'b0;
rpcie_mode_p1 <= 1'b0;
end
else begin
//Pipeline stages for the Heartbeat
rhb_sync_p1 <= rhb_sync;
rhb_sync_p2 <= rhb_sync_p1;
//Pipeline stages of the Dynamic rate control signals
rgear_p1 <= rgear;
rdiv2_p1 <= rdiv2;
rdiv11_p1 <= rdiv11;
//Pipeline stage for PCIe mode
rpcie_mode_p1 <= rpcie_mode;
//Pipeline stage for CPRI mode change
rcpri_mod_ch_p1 <= rcpri_mod_ch_sync;
rcpri_mod_ch_p2 <= rcpri_mod_ch_p1;
//CPRI mode change status logic
if (rcpri_mod_ch_p1^rcpri_mod_ch_sync == 1'b1) begin
rcpri_mod_ch_st <= 1'b1;
end
//Heartbeat wait counter and monitor logic
if (rtc_ctrl == 1'b1) begin
if (rhb_sync_p1 == 1'b1 && rhb_sync_p2 == 1'b0) begin
rhb_wait_cnt <= 8'd0;
rstat_pclk <= 1'b1;
end
else if (rhb_wait_cnt == LHB_WAIT_CNT) begin
rhb_wait_cnt <= 8'd0;
rstat_pclk <= 1'b0;
end
else begin
rhb_wait_cnt <= rhb_wait_cnt + 1;
end
end
end
end
// =============================================================================
// Pipleline registers for the TC pulse and CPRI mode change logic
// =============================================================================
always @(posedge sli_pclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
ppul_sync_p1 <= 1'b0;
ppul_sync_p2 <= 1'b0;
ppul_sync_p3 <= 1'b0;
pcpri_mode <= 3'b0;
pcpri_mod_ch <= 1'b0;
end
else begin
ppul_sync_p1 <= ppul_sync;
ppul_sync_p2 <= ppul_sync_p1;
ppul_sync_p3 <= ppul_sync_p2;
//CPRI mode change logic
pcpri_mode <= sli_cpri_mode;
if (pcpri_mode != sli_cpri_mode) begin
pcpri_mod_ch <= ~pcpri_mod_ch;
end
end
end
// =============================================================================
// Terminal count logic
// =============================================================================
//For SDI protocol with Dynamic rate control enabled
generate
if ((PDYN_RATE_CTRL == "ENABLED") && (PPROTOCOL == "SDI")) begin
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
rcount_tc <= 22'd0;
rdiff_comp_lock <= 16'd0;
rdiff_comp_unlock <= 16'd0;
end
else begin
//Terminal count logic
//Div by 11 is enabled
if (rdiv11 == 1'b1) begin
//Gear mode is 16/20
if (rgear == 1'b1) begin
rcount_tc <= PPCLK_DIV11_TC;
rdiff_comp_lock <= PDIFF_DIV11_VAL_LOCK;
rdiff_comp_unlock <= PDIFF_DIV11_VAL_UNLOCK;
end
else begin
rcount_tc <= {PPCLK_DIV11_TC[20:0], 1'b0};
rdiff_comp_lock <= {PDIFF_DIV11_VAL_LOCK[14:0], 1'b0};
rdiff_comp_unlock <= {PDIFF_DIV11_VAL_UNLOCK[14:0], 1'b0};
end
end
//Div by 2 is enabled
else if (rdiv2 == 1'b1) begin
//Gear mode is 16/20
if (rgear == 1'b1) begin
rcount_tc <= {1'b0,PPCLK_TC[21:1]};
rdiff_comp_lock <= {1'b0,PDIFF_VAL_LOCK[15:1]};
rdiff_comp_unlock <= {1'b0,PDIFF_VAL_UNLOCK[15:1]};
end
else begin
rcount_tc <= PPCLK_TC;
rdiff_comp_lock <= PDIFF_VAL_LOCK;
rdiff_comp_unlock <= PDIFF_VAL_UNLOCK;
end
end
//Both div by 11 and div by 2 are disabled
else begin
//Gear mode is 16/20
if (rgear == 1'b1) begin
rcount_tc <= PPCLK_TC;
rdiff_comp_lock <= PDIFF_VAL_LOCK;
rdiff_comp_unlock <= PDIFF_VAL_UNLOCK;
end
else begin
rcount_tc <= {PPCLK_TC[20:0],1'b0};
rdiff_comp_lock <= {PDIFF_VAL_LOCK[14:0],1'b0};
rdiff_comp_unlock <= {PDIFF_VAL_UNLOCK[14:0],1'b0};
end
end
end
end
end
endgenerate
//For G8B10B protocol with Dynamic rate control enabled
generate
if ((PDYN_RATE_CTRL == "ENABLED") && (PPROTOCOL == "G8B10B")) begin
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
rcount_tc <= 22'd0;
rdiff_comp_lock <= 16'd0;
rdiff_comp_unlock <= 16'd0;
end
else begin
//Terminal count logic
//Div by 2 is enabled
if (rdiv2 == 1'b1) begin
rcount_tc <= {1'b0,PPCLK_TC[21:1]};
rdiff_comp_lock <= {1'b0,PDIFF_VAL_LOCK[15:1]};
rdiff_comp_unlock <= {1'b0,PDIFF_VAL_UNLOCK[15:1]};
end
else begin
rcount_tc <= PPCLK_TC;
rdiff_comp_lock <= PDIFF_VAL_LOCK;
rdiff_comp_unlock <= PDIFF_VAL_UNLOCK;
end
end
end
end
endgenerate
//For CPRI protocol with Dynamic rate control is disabled
generate
if ((PDYN_RATE_CTRL == "DISABLED") && (PPROTOCOL == "CPRI")) begin
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
rcount_tc <= 22'd0;
rdiff_comp_lock <= 16'd0;
rdiff_comp_unlock <= 16'd0;
end
else begin
//Terminal count logic for CPRI protocol
//Only if there is a change in the rate mode from the default
if (rcpri_mod_ch_st == 1'b1) begin
if (rcpri_mod_ch_p1^rcpri_mod_ch_p2 == 1'b1) begin
case(sli_cpri_mode)
3'd0 : begin //For 0.6Gbps
rcount_tc <= LPCLK_TC_0;
case(PLOL_SETTING)
'd0 : begin
rdiff_comp_lock <= LPDIFF_LOCK_00;
rdiff_comp_unlock <= LPDIFF_UNLOCK_00;
end
'd1 : begin
rdiff_comp_lock <= LPDIFF_LOCK_01;
rdiff_comp_unlock <= LPDIFF_UNLOCK_01;
end
'd2 : begin
rdiff_comp_lock <= LPDIFF_LOCK_02;
rdiff_comp_unlock <= LPDIFF_UNLOCK_02;
end
'd3 : begin
rdiff_comp_lock <= LPDIFF_LOCK_03;
rdiff_comp_unlock <= LPDIFF_UNLOCK_03;
end
default : begin
rdiff_comp_lock <= LPDIFF_LOCK_00;
rdiff_comp_unlock <= LPDIFF_UNLOCK_00;
end
endcase
end
3'd1 : begin //For 1.2Gbps
rcount_tc <= LPCLK_TC_1;
case(PLOL_SETTING)
'd0 : begin
rdiff_comp_lock <= LPDIFF_LOCK_10;
rdiff_comp_unlock <= LPDIFF_UNLOCK_10;
end
'd1 : begin
rdiff_comp_lock <= LPDIFF_LOCK_11;
rdiff_comp_unlock <= LPDIFF_UNLOCK_11;
end
'd2 : begin
rdiff_comp_lock <= LPDIFF_LOCK_12;
rdiff_comp_unlock <= LPDIFF_UNLOCK_12;
end
'd3 : begin
rdiff_comp_lock <= LPDIFF_LOCK_13;
rdiff_comp_unlock <= LPDIFF_UNLOCK_13;
end
default : begin
rdiff_comp_lock <= LPDIFF_LOCK_10;
rdiff_comp_unlock <= LPDIFF_UNLOCK_10;
end
endcase
end
3'd2 : begin //For 2.4Gbps
rcount_tc <= LPCLK_TC_2;
case(PLOL_SETTING)
'd0 : begin
rdiff_comp_lock <= LPDIFF_LOCK_20;
rdiff_comp_unlock <= LPDIFF_UNLOCK_20;
end
'd1 : begin
rdiff_comp_lock <= LPDIFF_LOCK_21;
rdiff_comp_unlock <= LPDIFF_UNLOCK_21;
end
'd2 : begin
rdiff_comp_lock <= LPDIFF_LOCK_22;
rdiff_comp_unlock <= LPDIFF_UNLOCK_22;
end
'd3 : begin
rdiff_comp_lock <= LPDIFF_LOCK_23;
rdiff_comp_unlock <= LPDIFF_UNLOCK_23;
end
default : begin
rdiff_comp_lock <= LPDIFF_LOCK_20;
rdiff_comp_unlock <= LPDIFF_UNLOCK_20;
end
endcase
end
3'd3 : begin //For 3.07Gbps
rcount_tc <= LPCLK_TC_3;
case(PLOL_SETTING)
'd0 : begin
rdiff_comp_lock <= LPDIFF_LOCK_30;
rdiff_comp_unlock <= LPDIFF_UNLOCK_30;
end
'd1 : begin
rdiff_comp_lock <= LPDIFF_LOCK_31;
rdiff_comp_unlock <= LPDIFF_UNLOCK_31;
end
'd2 : begin
rdiff_comp_lock <= LPDIFF_LOCK_32;
rdiff_comp_unlock <= LPDIFF_UNLOCK_32;
end
'd3 : begin
rdiff_comp_lock <= LPDIFF_LOCK_33;
rdiff_comp_unlock <= LPDIFF_UNLOCK_33;
end
endcase
end
3'd4 : begin //For 4.9125bps
rcount_tc <= LPCLK_TC_4;
case(PLOL_SETTING)
'd0 : begin
rdiff_comp_lock <= LPDIFF_LOCK_40;
rdiff_comp_unlock <= LPDIFF_UNLOCK_40;
end
'd1 : begin
rdiff_comp_lock <= LPDIFF_LOCK_41;
rdiff_comp_unlock <= LPDIFF_UNLOCK_41;
end
'd2 : begin
rdiff_comp_lock <= LPDIFF_LOCK_42;
rdiff_comp_unlock <= LPDIFF_UNLOCK_42;
end
'd3 : begin
rdiff_comp_lock <= LPDIFF_LOCK_43;
rdiff_comp_unlock <= LPDIFF_UNLOCK_43;
end
default : begin
rdiff_comp_lock <= LPDIFF_LOCK_40;
rdiff_comp_unlock <= LPDIFF_UNLOCK_40;
end
endcase
end
default : begin
rcount_tc <= LPCLK_TC_0;
rdiff_comp_lock <= LPDIFF_LOCK_00;
rdiff_comp_unlock <= LPDIFF_UNLOCK_00;
end
endcase
end
end
else begin
//If there is no change in the CPRI rate mode from default
rcount_tc <= PPCLK_TC;
rdiff_comp_lock <= PDIFF_VAL_LOCK;
rdiff_comp_unlock <= PDIFF_VAL_UNLOCK;
end
end
end
end
endgenerate
//For PCIe protocol with Dynamic rate control disabled
generate
if ((PDYN_RATE_CTRL == "DISABLED") && (PPROTOCOL == "PCIE")) begin
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
rcount_tc <= 22'd0;
rdiff_comp_lock <= 16'd0;
rdiff_comp_unlock <= 16'd0;
end
else begin
//Terminal count logic
if (PPCIE_MAX_RATE == "2.5") begin
//2.5G mode is enabled
rcount_tc <= PPCLK_TC;
rdiff_comp_lock <= PDIFF_VAL_LOCK;
rdiff_comp_unlock <= PDIFF_VAL_UNLOCK;
end
else begin
//5G mode is enabled
if (rpcie_mode == 1'b1) begin
rcount_tc <= PPCLK_TC;
rdiff_comp_lock <= PDIFF_VAL_LOCK;
rdiff_comp_unlock <= PDIFF_VAL_UNLOCK;
end
else begin
//2.5G mode is enabled
rcount_tc <= {1'b0,PPCLK_TC[21:1]};
rdiff_comp_lock <= {1'b0,PDIFF_VAL_LOCK[15:1]};
rdiff_comp_unlock <= {1'b0,PDIFF_VAL_UNLOCK[15:1]};
end
end
end
end
end
endgenerate
//For all protocols other than CPRI & PCIe
generate
if ((PDYN_RATE_CTRL == "DISABLED") && ((PPROTOCOL != "CPRI") && (PPROTOCOL != "PCIE"))) begin
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
rcount_tc <= 22'd0;
rdiff_comp_lock <= 16'd0;
rdiff_comp_unlock <= 16'd0;
end
else begin
//Terminal count logic for all protocols other than CPRI & PCIe
rcount_tc <= PPCLK_TC;
rdiff_comp_lock <= PDIFF_VAL_LOCK;
rdiff_comp_unlock <= PDIFF_VAL_UNLOCK;
end
end
end
endgenerate
// =============================================================================
// Tx_pclk counter, Heartbeat and Differential value logic
// =============================================================================
always @(posedge sli_pclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
pcount <= 22'd0;
pcount_diff <= 22'd65535;
phb_cnt <= 3'd0;
phb <= 1'b0;
end
else begin
//Counter logic
if (ppul_sync_p1 == 1'b1 && ppul_sync_p2 == 1'b0) begin
pcount <= 22'd0;
end
else begin
pcount <= pcount + 1;
end
//Heartbeat logic
phb_cnt <= phb_cnt + 1;
if ((phb_cnt < 3'd4) && (phb_cnt >= 3'd0)) begin
phb <= 1'b1;
end
else begin
phb <= 1'b0;
end
//Differential value logic
if (ppul_sync_p1 == 1'b1 && ppul_sync_p2 == 1'b0) begin
pcount_diff <= rcount_tc + ~(pcount) + 1;
end
else if (ppul_sync_p2 == 1'b1 && ppul_sync_p3 == 1'b0) begin
if (pcount_diff[21] == 1'b1) begin
pcount_diff <= ~(pcount_diff) + 1;
end
end
end
end
// =============================================================================
// State transition logic for SLL FSM
// =============================================================================
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
sll_state <= LPLL_LOSS_ST;
end
else begin
//Reasons to declare an immediate loss - Absence of Tx_pclk, Dynamic rate change for SDI or CPRI
if ((rstat_pclk == 1'b0) || (rgear_p1^rgear == 1'b1) || (rdiv2_p1^rdiv2 == 1'b1) ||
(rdiv11_p1^rdiv11 == 1'b1) || (rcpri_mod_ch_p1^rcpri_mod_ch_p2 == 1'b1) || (rpcie_mode_p1^rpcie_mode == 1'b1)) begin
sll_state <= LPLL_LOSS_ST;
end
else begin
case(sll_state)
LPLL_LOSS_ST : begin
if (rtc_pul_p1 == 1'b1 && rtc_pul == 1'b0) begin
if (unlock) begin
sll_state <= LPLL_LOSS_ST;
end
else if (lock) begin
if (PLOL_SETTING == 2'd0) begin
sll_state <= LPLL_PRELOCK_ST;
end
else begin
sll_state <= LPLL_LOCK_ST;
end
end
end
end
LPLL_LOCK_ST : begin
if (rtc_pul_p1 == 1'b1 && rtc_pul == 1'b0) begin
if (lock) begin
sll_state <= LPLL_LOCK_ST;
end
else begin
if (PLOL_SETTING == 2'd0) begin
sll_state <= LPLL_LOSS_ST;
end
else begin
sll_state <= LPLL_PRELOSS_ST;
end
end
end
end
LPLL_PRELOCK_ST : begin
if (rtc_pul_p1 == 1'b1 && rtc_pul == 1'b0) begin
if (lock) begin
sll_state <= LPLL_LOCK_ST;
end
else begin
sll_state <= LPLL_PRELOSS_ST;
end
end
end
LPLL_PRELOSS_ST : begin
if (rtc_pul_p1 == 1'b1 && rtc_pul == 1'b0) begin
if (unlock) begin
sll_state <= LPLL_PRELOSS_ST;
end
else if (lock) begin
sll_state <= LPLL_LOCK_ST;
end
end
end
default: begin
sll_state <= LPLL_LOSS_ST;
end
endcase
end
end
end
// =============================================================================
// Logic for Tx PLL Lock
// =============================================================================
always @(posedge sli_refclk or posedge sli_rst) begin
if (sli_rst == 1'b1) begin
pll_lock <= 1'b0;
end
else begin
case(sll_state)
LPLL_LOSS_ST : begin
pll_lock <= 1'b0;
end
LPLL_LOCK_ST : begin
pll_lock <= 1'b1;
end
LPLL_PRELOSS_ST : begin
pll_lock <= 1'b0;
end
default: begin
pll_lock <= 1'b0;
end
endcase
end
end
assign slo_plol = ~(pll_lock);
endmodule
// ===========================================================================
// >>>>>>>>>>>>>>>>>>>>>>> COPYRIGHT NOTICE <<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<<
// ---------------------------------------------------------------------------
// Copyright (c) 2015 by Lattice Semiconductor Corporation
// ALL RIGHTS RESERVED
// ------------------------------------------------------------------
//
// Permission:
//
// Lattice SG Pte. Ltd. grants permission to use this code
// pursuant to the terms of the Lattice Reference Design License Agreement.
//
//
// Disclaimer:
//
// This VHDL or Verilog source code is intended as a design reference
// which illustrates how these types of functions can be implemented.
// It is the user's responsibility to verify their design for
// consistency and functionality through the use of formal
// verification methods. Lattice provides no warranty
// regarding the use or functionality of this code.
//
// ---------------------------------------------------------------------------
//
// Lattice SG Pte. Ltd.
// 101 Thomson Road, United Square #07-02
// Singapore 307591
//
//
// TEL: 1-800-Lattice (USA and Canada)
// +65-6631-2000 (Singapore)
// +1-503-268-8001 (other locations)
//
// web: http://www.latticesemi.com/
// email: techsupport@latticesemi.com
//
// ---------------------------------------------------------------------------
//
// =============================================================================
// FILE DETAILS
// Project : Synchronizer Logic
// File : sync.v
// Title : Synchronizer module
// Description :
// =============================================================================
// REVISION HISTORY
// Version : 1.0
// Author(s) : AV
// Mod. Date : July 7, 2015
// Changes Made : Initial Creation
// -----------------------------------------------------------------------------
// Version : 1.1
// Author(s) : EB
// Mod. Date : March 21, 2017
// Changes Made :
// =============================================================================
`ifndef PCS_SYNC_MODULE
`define PCS_SYNC_MODULE
module sync (
clk,
rst,
data_in,
data_out
);
input clk; //Clock in which the async data needs to be synchronized to
input rst; //Active high reset
input data_in; //Asynchronous data
output data_out; //Synchronized data
parameter PDATA_RST_VAL = 0; //Reset value for the registers
reg data_p1;
reg data_p2;
// =============================================================================
// Synchronization logic
// =============================================================================
always @(posedge clk or posedge rst) begin
if (rst == 1'b1) begin
data_p1 <= PDATA_RST_VAL;
data_p2 <= PDATA_RST_VAL;
end
else begin
data_p1 <= data_in;
data_p2 <= data_p1;
end
end
assign data_out = data_p2;
endmodule
`endif
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