litex/verilog/m1crg/m1crg.v

/*
 * Milkymist-NG SoC
 * Copyright (C) 2007, 2008, 2009, 2010, 2011, 2012 Sebastien Bourdeauducq
 *
 * This program is free software: you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation, version 3 of the License.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program.  If not, see <http://www.gnu.org/licenses/>.
 */

module m1crg #(
	parameter in_period = 0.0,
	parameter f_mult = 0,
	parameter f_div = 0,
	parameter clk2x_period = (in_period*f_div)/(2.0*f_mult)
) (
	input clkin,
	input trigger_reset,
	
	output sys_clk,
	output reg sys_rst,
	
	/* Reset off-chip devices */
	output ac97_rst_n,
	output videoin_rst_n,
	output flash_rst_n,
	
	/* DDR PHY clocks */
	output clk2x_270,
	output clk4x_wr,
	output clk4x_wr_strb,
	output clk4x_rd,
	output clk4x_rd_strb
);

/*
 * Reset
 */

reg [19:0] rst_debounce;
always @(posedge sys_clk) begin
	if(trigger_reset)
		rst_debounce <= 20'hFFFFF;
	else if(rst_debounce != 20'd0)
		rst_debounce <= rst_debounce - 20'd1;
	sys_rst <= rst_debounce != 20'd0;
end

assign ac97_rst_n = ~sys_rst;
assign videoin_rst_n = ~sys_rst;

/*
 * We must release the Flash reset before the system reset
 * because the Flash needs some time to come out of reset
 * and the CPU begins fetching instructions from it
 * as soon as the system reset is released.
 * From datasheet, minimum reset pulse width is 100ns
 * and reset-to-read time is 150ns.
 */

reg [7:0] flash_rstcounter;

always @(posedge sys_clk) begin
	if(trigger_reset)
		flash_rstcounter <= 8'd0;
	else if(~flash_rstcounter[7])
		flash_rstcounter <= flash_rstcounter + 8'd1;
end

assign flash_rst_n = flash_rstcounter[7];

/*
 * Clock management. Inspired by the NWL reference design.
 */

wire sdr_clkin;
wire clkdiv;

IBUF #(
	.IOSTANDARD("DEFAULT")
) clk2_iob (
	.I(clkin),
	.O(sdr_clkin)
);

BUFIO2 #(
	.DIVIDE(1),
	.DIVIDE_BYPASS("FALSE"),
	.I_INVERT("FALSE")
) bufio2_inst2 (
	.I(sdr_clkin),
	.IOCLK(),
	.DIVCLK(clkdiv),
	.SERDESSTROBE()
);

wire pll_lckd;
wire buf_pll_fb_out;
wire pllout0;
wire pllout1;
wire pllout2;
wire pllout3;

PLL_ADV #(
	.BANDWIDTH("OPTIMIZED"),
	.CLKFBOUT_MULT(4*f_mult),
	.CLKFBOUT_PHASE(0.0),
	.CLKIN1_PERIOD(in_period),
	.CLKIN2_PERIOD(in_period),
	.CLKOUT0_DIVIDE(f_div),
	.CLKOUT0_DUTY_CYCLE(0.5),
	.CLKOUT0_PHASE(0),
	.CLKOUT1_DIVIDE(f_div),
	.CLKOUT1_DUTY_CYCLE(0.5),
	.CLKOUT1_PHASE(0),
	.CLKOUT2_DIVIDE(2*f_div),
	.CLKOUT2_DUTY_CYCLE(0.5),
	.CLKOUT2_PHASE(270.0),
	.CLKOUT3_DIVIDE(4*f_div),
	.CLKOUT3_DUTY_CYCLE(0.5),
	.CLKOUT3_PHASE(0.0),
	.CLKOUT4_DIVIDE(7),
	.CLKOUT4_DUTY_CYCLE(0.5),
	.CLKOUT4_PHASE(0),
	.CLKOUT5_DIVIDE(7),
	.CLKOUT5_DUTY_CYCLE(0.5),
	.CLKOUT5_PHASE(0.0),
	.COMPENSATION("INTERNAL"),
	.DIVCLK_DIVIDE(1),
	.REF_JITTER(0.100),
	.CLK_FEEDBACK("CLKFBOUT"),
	.SIM_DEVICE("SPARTAN6")
) pll (
	.CLKFBDCM(),
	.CLKFBOUT(buf_pll_fb_out),
	.CLKOUT0(pllout0), /* < x4 clock for writes */
	.CLKOUT1(pllout1), /* < x4 clock for reads */
	.CLKOUT2(pllout2), /* < x2 90 clock to generate memory clock, clock DQS and memory address and control signals. */
	.CLKOUT3(pllout3), /* < x1 clock for system and memory controller */
	.CLKOUT4(),
	.CLKOUT5(),
	.CLKOUTDCM0(),
	.CLKOUTDCM1(),
	.CLKOUTDCM2(),
	.CLKOUTDCM3(),
	.CLKOUTDCM4(),
	.CLKOUTDCM5(),
	.DO(),
	.DRDY(),
	.LOCKED(pll_lckd),
	.CLKFBIN(buf_pll_fb_out),
	.CLKIN1(clkdiv),
	.CLKIN2(1'b0),
	.CLKINSEL(1'b1),
	.DADDR(5'b00000),
	.DCLK(1'b0),
	.DEN(1'b0),
	.DI(16'h0000),
	.DWE(1'b0),
	.RST(1'b0),
	.REL(1'b0)
);

BUFPLL #(
	.DIVIDE(4)
) wr_bufpll (
	.PLLIN(pllout0),
	.GCLK(sys_clk),
	.LOCKED(pll_lckd),
	.IOCLK(clk4x_wr),
	.LOCK(),
	.SERDESSTROBE(clk4x_wr_strb)
);

BUFPLL #(
	.DIVIDE(4)
) rd_bufpll (
	.PLLIN(pllout1),
	.GCLK(sys_clk),
	.LOCKED(pll_lckd),
	.IOCLK(clk4x_rd),
	.LOCK(),
	.SERDESSTROBE(clk4x_rd_strb)
);

BUFG bufg_x2_2(
	.I(pllout2),
	.O(clk2x_270)
);

BUFG bufg_x1(
	.I(pllout3),
	.O(sys_clk)
);
 
endmodule
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`/*`
			`* Milkymist-NG SoC`
			`* Copyright (C) 2007, 2008, 2009, 2010, 2011, 2012 Sebastien Bourdeauducq`
			`*`
			`* This program is free software: you can redistribute it and/or modify`
			`* it under the terms of the GNU General Public License as published by`
			`* the Free Software Foundation, version 3 of the License.`
			`*`
			`* This program is distributed in the hope that it will be useful,`
			`* but WITHOUT ANY WARRANTY; without even the implied warranty of`
			`* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the`
			`* GNU General Public License for more details.`
			`*`
			`* You should have received a copy of the GNU General Public License`
			`* along with this program. If not, see <http://www.gnu.org/licenses/>.`
			`*/`

			`module m1crg #(`
			`parameter in_period = 0.0,`
			`parameter f_mult = 0,`
			`parameter f_div = 0,`
			`parameter clk2x_period = (in_periodf_div)/(2.0f_mult)`
			`) (`
			`input clkin,`
			`input trigger_reset,`

			`output sys_clk,`
			`output reg sys_rst,`

			`/* Reset off-chip devices */`
			`output ac97_rst_n,`
			`output videoin_rst_n,`
			`output flash_rst_n,`

Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`/* DDR PHY clocks */`
s6ddrphy: write path OK in simulation 2012-02-20 17:55:20 -05:00			`output clk2x_270,`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`output clk4x_wr,`
			`output clk4x_wr_strb,`
			`output clk4x_rd,`
			`output clk4x_rd_strb`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`);`

			`/*`
			`* Reset`
			`*/`

			`reg [19:0] rst_debounce;`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`always @(posedge sys_clk) begin`
			`if(trigger_reset)`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`rst_debounce <= 20'hFFFFF;`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`else if(rst_debounce != 20'd0)`
			`rst_debounce <= rst_debounce - 20'd1;`
			`sys_rst <= rst_debounce != 20'd0;`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`end`

			`assign ac97_rst_n = ~sys_rst;`
			`assign videoin_rst_n = ~sys_rst;`

			`/*`
			`* We must release the Flash reset before the system reset`
			`* because the Flash needs some time to come out of reset`
			`* and the CPU begins fetching instructions from it`
			`* as soon as the system reset is released.`
			`* From datasheet, minimum reset pulse width is 100ns`
			`* and reset-to-read time is 150ns.`
			`*/`

			`reg [7:0] flash_rstcounter;`

Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`always @(posedge sys_clk) begin`
			`if(trigger_reset)`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`flash_rstcounter <= 8'd0;`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`else if(~flash_rstcounter[7])`
			`flash_rstcounter <= flash_rstcounter + 8'd1;`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`end`

			`assign flash_rst_n = flash_rstcounter[7];`

			`/*`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`* Clock management. Inspired by the NWL reference design.`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`*/`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`wire sdr_clkin;`
			`wire clkdiv;`

			`IBUF #(`
			`.IOSTANDARD("DEFAULT")`
			`) clk2_iob (`
			`.I(clkin),`
			`.O(sdr_clkin)`
			`);`

			`BUFIO2 #(`
			`.DIVIDE(1),`
			`.DIVIDE_BYPASS("FALSE"),`
			`.I_INVERT("FALSE")`
			`) bufio2_inst2 (`
			`.I(sdr_clkin),`
			`.IOCLK(),`
			`.DIVCLK(clkdiv),`
			`.SERDESSTROBE()`
			`);`

Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`wire pll_lckd;`
			`wire buf_pll_fb_out;`
			`wire pllout0;`
			`wire pllout1;`
			`wire pllout2;`
			`wire pllout3;`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00
			`PLL_ADV #(`
			`.BANDWIDTH("OPTIMIZED"),`
			`.CLKFBOUT_MULT(4*f_mult),`
			`.CLKFBOUT_PHASE(0.0),`
			`.CLKIN1_PERIOD(in_period),`
			`.CLKIN2_PERIOD(in_period),`
			`.CLKOUT0_DIVIDE(f_div),`
			`.CLKOUT0_DUTY_CYCLE(0.5),`
			`.CLKOUT0_PHASE(0),`
			`.CLKOUT1_DIVIDE(f_div),`
			`.CLKOUT1_DUTY_CYCLE(0.5),`
			`.CLKOUT1_PHASE(0),`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.CLKOUT2_DIVIDE(2*f_div),`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.CLKOUT2_DUTY_CYCLE(0.5),`
s6ddrphy: write path OK in simulation 2012-02-20 17:55:20 -05:00			`.CLKOUT2_PHASE(270.0),`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.CLKOUT3_DIVIDE(4*f_div),`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.CLKOUT3_DUTY_CYCLE(0.5),`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.CLKOUT3_PHASE(0.0),`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.CLKOUT4_DIVIDE(7),`
			`.CLKOUT4_DUTY_CYCLE(0.5),`
			`.CLKOUT4_PHASE(0),`
			`.CLKOUT5_DIVIDE(7),`
			`.CLKOUT5_DUTY_CYCLE(0.5),`
			`.CLKOUT5_PHASE(0.0),`
			`.COMPENSATION("INTERNAL"),`
			`.DIVCLK_DIVIDE(1),`
			`.REF_JITTER(0.100),`
			`.CLK_FEEDBACK("CLKFBOUT"),`
			`.SIM_DEVICE("SPARTAN6")`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`) pll (`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.CLKFBDCM(),`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.CLKFBOUT(buf_pll_fb_out),`
			`.CLKOUT0(pllout0), /* < x4 clock for writes */`
			`.CLKOUT1(pllout1), /* < x4 clock for reads */`
			`.CLKOUT2(pllout2), /* < x2 90 clock to generate memory clock, clock DQS and memory address and control signals. */`
			`.CLKOUT3(pllout3), /* < x1 clock for system and memory controller */`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.CLKOUT4(),`
			`.CLKOUT5(),`
			`.CLKOUTDCM0(),`
			`.CLKOUTDCM1(),`
			`.CLKOUTDCM2(),`
			`.CLKOUTDCM3(),`
			`.CLKOUTDCM4(),`
			`.CLKOUTDCM5(),`
			`.DO(),`
			`.DRDY(),`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.LOCKED(pll_lckd),`
			`.CLKFBIN(buf_pll_fb_out),`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.CLKIN1(clkdiv),`
			`.CLKIN2(1'b0),`
			`.CLKINSEL(1'b1),`
			`.DADDR(5'b00000),`
			`.DCLK(1'b0),`
			`.DEN(1'b0),`
			`.DI(16'h0000),`
			`.DWE(1'b0),`
			`.RST(1'b0),`
			`.REL(1'b0)`
			`);`

			`BUFPLL #(`
			`.DIVIDE(4)`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`) wr_bufpll (`
			`.PLLIN(pllout0),`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.GCLK(sys_clk),`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.LOCKED(pll_lckd),`
			`.IOCLK(clk4x_wr),`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.LOCK(),`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.SERDESSTROBE(clk4x_wr_strb)`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`);`

			`BUFPLL #(`
			`.DIVIDE(4)`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`) rd_bufpll (`
			`.PLLIN(pllout1),`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.GCLK(sys_clk),`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.LOCKED(pll_lckd),`
			`.IOCLK(clk4x_rd),`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`.LOCK(),`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.SERDESSTROBE(clk4x_rd_strb)`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`);`

			`BUFG bufg_x2_2(`
Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`.I(pllout2),`
s6ddrphy: write path OK in simulation 2012-02-20 17:55:20 -05:00			`.O(clk2x_270)`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`);`

Prepare for new DDR PHY 2012-02-19 12:43:42 -05:00			`BUFG bufg_x1(`
			`.I(pllout3),`
			`.O(sys_clk)`
Generate all clocks for the DDR PHY 2012-02-16 12:02:37 -05:00			`);`

			`endmodule`