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//////////////////////////////////////////////////////////////////////
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//// ////
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//// Versatile library, clock and reset ////
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//// ////
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//// Description ////
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//// Logic related to clock and reset ////
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//// ////
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//// ////
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//// To Do: ////
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//// - add more different registers ////
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//// ////
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//// Author(s): ////
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//// - Michael Unneback, unneback@opencores.org ////
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//// ORSoC AB ////
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//// ////
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//////////////////////////////////////////////////////////////////////
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//// ////
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//// Copyright (C) 2010 Authors and OPENCORES.ORG ////
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//// ////
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//// This source file may be used and distributed without ////
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//// restriction provided that this copyright statement is not ////
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//// removed from the file and that any derivative work contains ////
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//// the original copyright notice and the associated disclaimer. ////
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//// ////
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//// This source file is free software; you can redistribute it ////
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//// and/or modify it under the terms of the GNU Lesser General ////
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//// Public License as published by the Free Software Foundation; ////
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//// either version 2.1 of the License, or (at your option) any ////
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//// later version. ////
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//// ////
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//// This source is distributed in the hope that it will be ////
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//// useful, but WITHOUT ANY WARRANTY; without even the implied ////
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//// warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR ////
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//// PURPOSE. See the GNU Lesser General Public License for more ////
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//// details. ////
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//// ////
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//// You should have received a copy of the GNU Lesser General ////
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//// Public License along with this source; if not, download it ////
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//// from http://www.opencores.org/lgpl.shtml ////
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//// ////
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//////////////////////////////////////////////////////////////////////
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48 |
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`ifdef ACTEL
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`ifdef GBUF
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`timescale 1 ns/100 ps
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3 |
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// Global buffer
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// usage:
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4 |
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// use to enable global buffers for high fan out signals such as clock and reset
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// Version: 8.4 8.4.0.33
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module gbuf(GL,CLK);
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output GL;
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input CLK;
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wire GND;
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GND GND_1_net(.Y(GND));
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CLKDLY Inst1(.CLK(CLK), .GL(GL), .DLYGL0(GND), .DLYGL1(GND),
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.DLYGL2(GND), .DLYGL3(GND), .DLYGL4(GND)) /* synthesis black_box */;
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endmodule
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`timescale 1 ns/1 ns
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`define MODULE gbuf
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module `BASE`MODULE ( i, o);
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`undef MODULE
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input i;
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output o;
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//E2_ifdef SIM_GBUF
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assign o=i;
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//E2_else
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gbuf gbuf_i0 ( .CLK(i), .GL(o));
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//E2_endif
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endmodule
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40 |
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`endif
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33 |
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3 |
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`else
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33 |
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40 |
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`ifdef ALTERA
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`ifdef GBUF
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//altera
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`define MODULE gbuf
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module `BASE`MODULE ( i, o);
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`undef MODULE
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input i;
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output o;
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assign o = i;
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endmodule
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`endif
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3 |
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`else
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40 |
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`ifdef GBUF
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4 |
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`timescale 1 ns/100 ps
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40 |
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`define MODULE
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module `BASE`MODULE ( i, o);
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`undef MODULE
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input i;
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output o;
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assign o = i;
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endmodule
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40 |
unneback |
`endif
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3 |
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`endif // ALTERA
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`endif //ACTEL
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40 |
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`ifdef SYNC_RST
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// sync reset
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// input active lo async reset, normally from external reset generator and/or switch
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// output active high global reset sync with two DFFs
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`timescale 1 ns/100 ps
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`define MODULE sync_rst
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module `BASE`MODULE ( rst_n_i, rst_o, clk);
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`undef MODULE
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input rst_n_i, clk;
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output rst_o;
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reg [1:0] tmp;
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always @ (posedge clk or negedge rst_n_i)
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if (!rst_n_i)
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tmp <= 2'b11;
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else
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tmp <= {1'b0,tmp[1]};
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`define MODULE gbuf
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`BASE`MODULE buf_i0( .i(tmp[0]), .o(rst_o));
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`undef MODULE
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endmodule
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`endif
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40 |
unneback |
`ifdef PLL
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// vl_pll
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`ifdef ACTEL
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///////////////////////////////////////////////////////////////////////////////
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`timescale 1 ps/1 ps
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`define MODULE pll
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module `BASE`MODULE ( clk_i, rst_n_i, lock, clk_o, rst_o);
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`undef MODULE
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parameter index = 0;
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parameter number_of_clk = 1;
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parameter period_time_0 = 20000;
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parameter period_time_1 = 20000;
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parameter period_time_2 = 20000;
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parameter lock_delay = 2000000;
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input clk_i, rst_n_i;
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output lock;
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output reg [0:number_of_clk-1] clk_o;
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output [0:number_of_clk-1] rst_o;
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//E2_ifdef SIM_PLL
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always
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#((period_time_0)/2) clk_o[0] <= (!rst_n_i) ? 0 : ~clk_o[0];
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generate if (number_of_clk > 1)
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always
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#((period_time_1)/2) clk_o[1] <= (!rst_n_i) ? 0 : ~clk_o[1];
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endgenerate
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generate if (number_of_clk > 2)
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always
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#((period_time_2)/2) clk_o[2] <= (!rst_n_i) ? 0 : ~clk_o[2];
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endgenerate
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3 |
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genvar i;
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generate for (i=0;i<number_of_clk;i=i+1) begin: clock
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vl_sync_rst rst_i0 ( .rst_n_i(rst_n_i | lock), .rst_o(rst_o[i]), .clk(clk_o[i]));
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end
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endgenerate
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assign #lock_delay lock = rst_n_i;
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3 |
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endmodule
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//E2_else
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generate if (number_of_clk==1 & index==0) begin
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pll0 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]));
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end
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endgenerate // index==0
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generate if (number_of_clk==1 & index==1) begin
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pll1 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]));
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end
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endgenerate // index==1
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generate if (number_of_clk==1 & index==2) begin
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pll2 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]));
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end
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endgenerate // index==2
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generate if (number_of_clk==1 & index==3) begin
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pll3 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]));
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end
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endgenerate // index==0
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generate if (number_of_clk==2 & index==0) begin
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pll0 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]), .GLB(clk_o[1]));
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end
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endgenerate // index==0
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generate if (number_of_clk==2 & index==1) begin
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pll1 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]), .GLB(clk_o[1]));
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end
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endgenerate // index==1
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generate if (number_of_clk==2 & index==2) begin
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pll2 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]), .GLB(clk_o[1]));
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end
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endgenerate // index==2
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generate if (number_of_clk==2 & index==3) begin
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pll3 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]), .GLB(clk_o[1]));
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end
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endgenerate // index==0
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generate if (number_of_clk==3 & index==0) begin
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pll0 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]), .GLB(clk_o[1]), .GLC(clk_o[2]));
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end
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endgenerate // index==0
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generate if (number_of_clk==3 & index==1) begin
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pll1 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]), .GLB(clk_o[1]), .GLC(clk_o[2]));
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end
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endgenerate // index==1
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generate if (number_of_clk==3 & index==2) begin
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pll2 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]), .GLB(clk_o[1]), .GLC(clk_o[2]));
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end
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endgenerate // index==2
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generate if (number_of_clk==3 & index==3) begin
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pll3 pll_i0 (.POWERDOWN(1'b1), .CLKA(clk_i), .LOCK(lock), .GLA(clk_o[0]), .GLB(clk_o[1]), .GLC(clk_o[2]));
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end
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endgenerate // index==0
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genvar i;
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generate for (i=0;i<number_of_clk;i=i+1) begin: clock
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40 |
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`define MODULE sync_rst
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`BASE`MODULE rst_i0 ( .rst_n_i(rst_n_i | lock), .rst_o(rst_o), .clk(clk_o[i]));
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`undef MODULE
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end
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endgenerate
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endmodule
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//E2_endif
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///////////////////////////////////////////////////////////////////////////////
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3 |
unneback |
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`else
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///////////////////////////////////////////////////////////////////////////////
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3 |
unneback |
`ifdef ALTERA
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32 |
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`timescale 1 ps/1 ps
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40 |
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`define MODULE pll
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module `BASE`MODULE ( clk_i, rst_n_i, lock, clk_o, rst_o);
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`undef MODULE
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| 241 |
32 |
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parameter index = 0;
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parameter number_of_clk = 1;
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| 243 |
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parameter period_time_0 = 20000;
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parameter period_time_1 = 20000;
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parameter period_time_2 = 20000;
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parameter period_time_3 = 20000;
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parameter period_time_4 = 20000;
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parameter lock_delay = 2000000;
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| 249 |
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input clk_i, rst_n_i;
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output lock;
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| 251 |
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output reg [0:number_of_clk-1] clk_o;
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| 252 |
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output [0:number_of_clk-1] rst_o;
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//E2_ifdef SIM_PLL
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always
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#((period_time_0)/2) clk_o[0] <= (!rst_n_i) ? 0 : ~clk_o[0];
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| 259 |
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generate if (number_of_clk > 1)
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always
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| 261 |
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#((period_time_1)/2) clk_o[1] <= (!rst_n_i) ? 0 : ~clk_o[1];
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endgenerate
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| 263 |
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| 264 |
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generate if (number_of_clk > 2)
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always
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| 266 |
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#((period_time_2)/2) clk_o[2] <= (!rst_n_i) ? 0 : ~clk_o[2];
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endgenerate
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| 268 |
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| 269 |
33 |
unneback |
generate if (number_of_clk > 3)
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| 270 |
32 |
unneback |
always
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| 271 |
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#((period_time_3)/2) clk_o[3] <= (!rst_n_i) ? 0 : ~clk_o[3];
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| 272 |
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endgenerate
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| 273 |
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| 274 |
33 |
unneback |
generate if (number_of_clk > 4)
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| 275 |
32 |
unneback |
always
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| 276 |
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#((period_time_4)/2) clk_o[4] <= (!rst_n_i) ? 0 : ~clk_o[4];
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| 277 |
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endgenerate
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| 278 |
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| 279 |
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genvar i;
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| 280 |
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generate for (i=0;i<number_of_clk;i=i+1) begin: clock
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| 281 |
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vl_sync_rst rst_i0 ( .rst_n_i(rst_n_i | lock), .rst_o(rst_o[i]), .clk(clk_o[i]));
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| 282 |
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end
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| 283 |
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endgenerate
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| 285 |
33 |
unneback |
//assign #lock_delay lock = rst_n_i;
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| 286 |
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assign lock = rst_n_i;
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| 287 |
32 |
unneback |
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| 288 |
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endmodule
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| 289 |
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//E2_else
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| 290 |
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| 291 |
33 |
unneback |
//E2_ifdef VL_PLL0
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| 292 |
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//E2_ifdef VL_PLL0_CLK1
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| 293 |
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pll0 pll0_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]));
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| 294 |
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//E2_endif
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| 295 |
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//E2_ifdef VL_PLL0_CLK2
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| 296 |
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pll0 pll0_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]));
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//E2_endif
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| 298 |
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//E2_ifdef VL_PLL0_CLK3
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| 299 |
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pll0 pll0_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]));
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| 300 |
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//E2_endif
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| 301 |
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//E2_ifdef VL_PLL0_CLK4
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| 302 |
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pll0 pll0_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]), .c3(clk_o[3]));
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| 303 |
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//E2_endif
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| 304 |
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//E2_ifdef VL_PLL0_CLK5
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| 305 |
|
|
pll0 pll0_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]), .c3(clk_o[3]), .c4(clk_o[4]));
|
| 306 |
|
|
//E2_endif
|
| 307 |
|
|
//E2_endif
|
| 308 |
32 |
unneback |
|
| 309 |
33 |
unneback |
//E2_ifdef VL_PLL1
|
| 310 |
|
|
//E2_ifdef VL_PLL1_CLK1
|
| 311 |
|
|
pll1 pll1_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]));
|
| 312 |
|
|
//E2_endif
|
| 313 |
|
|
//E2_ifdef VL_PLL1_CLK2
|
| 314 |
|
|
pll1 pll1_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]));
|
| 315 |
|
|
//E2_endif
|
| 316 |
|
|
//E2_ifdef VL_PLL1_CLK3
|
| 317 |
|
|
pll1 pll1_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]));
|
| 318 |
|
|
//E2_endif
|
| 319 |
|
|
//E2_ifdef VL_PLL1_CLK4
|
| 320 |
|
|
pll1 pll1_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]), .c3(clk_o[3]));
|
| 321 |
|
|
//E2_endif
|
| 322 |
|
|
//E2_ifdef VL_PLL1_CLK5
|
| 323 |
|
|
pll1 pll1_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]), .c3(clk_o[3]), .c4(clk_o[4]));
|
| 324 |
|
|
//E2_endif
|
| 325 |
|
|
//E2_endif
|
| 326 |
32 |
unneback |
|
| 327 |
33 |
unneback |
//E2_ifdef VL_PLL2
|
| 328 |
|
|
//E2_ifdef VL_PLL2_CLK1
|
| 329 |
|
|
pll2 pll2_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]));
|
| 330 |
|
|
//E2_endif
|
| 331 |
|
|
//E2_ifdef VL_PLL2_CLK2
|
| 332 |
|
|
pll2 pll2_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]));
|
| 333 |
|
|
//E2_endif
|
| 334 |
|
|
//E2_ifdef VL_PLL2_CLK3
|
| 335 |
|
|
pll2 pll2_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]));
|
| 336 |
|
|
//E2_endif
|
| 337 |
|
|
//E2_ifdef VL_PLL2_CLK4
|
| 338 |
|
|
pll2 pll2_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]), .c3(clk_o[3]));
|
| 339 |
|
|
//E2_endif
|
| 340 |
|
|
//E2_ifdef VL_PLL2_CLK5
|
| 341 |
|
|
pll2 pll2_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]), .c3(clk_o[3]), .c4(clk_o[4]));
|
| 342 |
|
|
//E2_endif
|
| 343 |
|
|
//E2_endif
|
| 344 |
32 |
unneback |
|
| 345 |
33 |
unneback |
//E2_ifdef VL_PLL3
|
| 346 |
|
|
//E2_ifdef VL_PLL3_CLK1
|
| 347 |
|
|
pll3 pll3_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]));
|
| 348 |
|
|
//E2_endif
|
| 349 |
|
|
//E2_ifdef VL_PLL3_CLK2
|
| 350 |
|
|
pll3 pll3_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]));
|
| 351 |
|
|
//E2_endif
|
| 352 |
|
|
//E2_ifdef VL_PLL3_CLK3
|
| 353 |
|
|
pll3 pll3_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]));
|
| 354 |
|
|
//E2_endif
|
| 355 |
|
|
//E2_ifdef VL_PLL3_CLK4
|
| 356 |
|
|
pll3 pll3_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]), .c3(clk_o[3]));
|
| 357 |
|
|
//E2_endif
|
| 358 |
|
|
//E2_ifdef VL_PLL3_CLK5
|
| 359 |
|
|
pll3 pll3_i0 (.areset(rst_n_i), .inclk0(clk_i), .locked(lock), .c0(clk_o[0]), .c1(clk_o[1]), .c2(clk_o[2]), .c3(clk_o[3]), .c4(clk_o[4]));
|
| 360 |
|
|
//E2_endif
|
| 361 |
|
|
//E2_endif
|
| 362 |
32 |
unneback |
|
| 363 |
|
|
genvar i;
|
| 364 |
|
|
generate for (i=0;i<number_of_clk;i=i+1) begin: clock
|
| 365 |
40 |
unneback |
`define MODULE sync_rst
|
| 366 |
|
|
`BASE`MODULE rst_i0 ( .rst_n_i(rst_n_i | lock), .rst_o(rst_o[i]), .clk(clk_o[i]));
|
| 367 |
|
|
`undef MODULE
|
| 368 |
32 |
unneback |
end
|
| 369 |
|
|
endgenerate
|
| 370 |
|
|
endmodule
|
| 371 |
|
|
//E2_endif
|
| 372 |
|
|
///////////////////////////////////////////////////////////////////////////////
|
| 373 |
|
|
|
| 374 |
3 |
unneback |
`else
|
| 375 |
|
|
|
| 376 |
|
|
// generic PLL
|
| 377 |
17 |
unneback |
`timescale 1 ps/1 ps
|
| 378 |
40 |
unneback |
`define MODULE pll
|
| 379 |
|
|
module `BASE`MODULE ( clk_i, rst_n_i, lock, clk_o, rst_o);
|
| 380 |
|
|
`undef MODULE
|
| 381 |
3 |
unneback |
parameter index = 0;
|
| 382 |
4 |
unneback |
parameter number_of_clk = 1;
|
| 383 |
139 |
unneback |
parameter period_time = 20000;
|
| 384 |
|
|
parameter clk0_mult_by = 1;
|
| 385 |
|
|
parameter clk0_div_by = 1;
|
| 386 |
|
|
parameter clk1_mult_by = 1;
|
| 387 |
|
|
parameter clk1_div_by = 1;
|
| 388 |
|
|
parameter clk2_mult_by = 1;
|
| 389 |
|
|
parameter clk3_div_by = 1;
|
| 390 |
|
|
parameter clk3_mult_by = 1;
|
| 391 |
|
|
parameter clk3_div_by = 1;
|
| 392 |
|
|
parameter clk4_mult_by = 1;
|
| 393 |
|
|
parameter clk4_div_by = 1;
|
| 394 |
3 |
unneback |
input clk_i, rst_n_i;
|
| 395 |
|
|
output lock;
|
| 396 |
|
|
output reg [0:number_of_clk-1] clk_o;
|
| 397 |
|
|
|
| 398 |
139 |
unneback |
initial
|
| 399 |
|
|
clk_o = {number_of_clk{1'b0}};
|
| 400 |
|
|
|
| 401 |
4 |
unneback |
always
|
| 402 |
139 |
unneback |
#((period_time*clk0_div_by/clk0_mult_by)/2) clk_o[0] <= (!rst_n_i) ? 1'b0 : ~clk_o[0];
|
| 403 |
4 |
unneback |
|
| 404 |
|
|
generate if (number_of_clk > 1)
|
| 405 |
|
|
always
|
| 406 |
139 |
unneback |
#((period_time*clk1_div_by/clk1_mult_by)/2) clk_o[1] <= (!rst_n_i) ? 1'b0 : ~clk_o[1];
|
| 407 |
4 |
unneback |
endgenerate
|
| 408 |
|
|
|
| 409 |
|
|
generate if (number_of_clk > 2)
|
| 410 |
|
|
always
|
| 411 |
139 |
unneback |
#((period_time*clk2_div_by/clk2_mult_by)/2) clk_o[2] <= (!rst_n_i) ? 1'b0 : ~clk_o[2];
|
| 412 |
4 |
unneback |
endgenerate
|
| 413 |
|
|
|
| 414 |
139 |
unneback |
generate if (number_of_clk > 3)
|
| 415 |
|
|
always
|
| 416 |
|
|
#((period_time*clk3_div_by/clk3_mult_by)/2) clk_o[3] <= (!rst_n_i) ? 1'b0 : ~clk_o[3];
|
| 417 |
3 |
unneback |
endgenerate
|
| 418 |
|
|
|
| 419 |
139 |
unneback |
generate if (number_of_clk > 4)
|
| 420 |
|
|
always
|
| 421 |
|
|
#((period_time*clk4_div_by/clk4_mult_by)/2) clk_o[4] <= (!rst_n_i) ? 1'b0 : ~clk_o[4];
|
| 422 |
|
|
endgenerate
|
| 423 |
|
|
|
| 424 |
3 |
unneback |
assign #lock_delay lock = rst_n_i;
|
| 425 |
|
|
|
| 426 |
|
|
endmodule
|
| 427 |
|
|
|
| 428 |
|
|
`endif //altera
|
| 429 |
17 |
unneback |
`endif //actel
|
| 430 |
40 |
unneback |
`undef MODULE
|
| 431 |
|
|
`endif
|
