hw/ip/usbdev/rtl/usbdev_linkstate.sv - 3p/lowrisc/opentitan - Git at Google

 // Copyright lowRISC contributors.
 // Licensed under the Apache License, Version 2.0, see LICENSE for details.
 // SPDX-License-Identifier: Apache-2.0
 //
 // Link state detection
 //

 module usbdev_linkstate (
   input  logic clk_48mhz_i,
   input  logic rst_ni,
   input  logic us_tick_i,
   input  logic usb_sense_i,
   input  logic usb_dp_i,
   input  logic usb_dn_i,
   input  logic usb_oe_i,
   input  logic rx_jjj_det_i,
   input  logic sof_valid_i,
   output logic link_disconnect_o,  // level
   output logic link_connect_o,     // level
   output logic link_reset_o,       // level
   output logic link_active_o,      // level
   output logic link_suspend_o,     // level
   output logic link_resume_o,      // pulse
   output logic host_lost_o,        // level

   output logic [2:0] link_state_o
 );

   localparam logic [11:0] SUSPEND_TIMEOUT = 12'd3000; // 3ms by spec
   localparam logic [2:0]  RESET_TIMEOUT   = 3'd3;     // 3us. Can be 2.5us - 10ms by spec

   typedef enum logic [2:0] {
     // Unpowered state
     LinkDisconnect = 0,
     // Powered states
     LinkPowered = 1,
     LinkPoweredSuspend = 2,
     // Active states
     LinkActive = 3,
     LinkActiveNoSOF = 5,
     LinkSuspend = 4
   } link_state_e;

   typedef enum logic [1:0] {
     NoRst,
     RstCnt,
     RstPend
   } link_rst_state_e;

   typedef enum logic [1:0] {
     Active,
     InactCnt,
     InactPend
   } link_inac_state_e;

   link_state_e  link_state_d, link_state_q;
   logic         see_pwr_sense;

   // Reset FSM
   logic [2:0]      link_rst_timer_d, link_rst_timer_q;
   link_rst_state_e link_rst_state_d, link_rst_state_q;
   logic            link_reset; // reset detected (level)

   // Link inactivity detection
   logic              monitor_inac; // monitor link inactivity
   logic [11:0]       link_inac_timer_d, link_inac_timer_q;
   link_inac_state_e  link_inac_state_d, link_inac_state_q;


   // Events that are not triggered by a timeout
   logic ev_bus_active;

   // Events that are triggered by timeout
   logic ev_bus_inactive, ev_reset;

   assign link_disconnect_o = (link_state_q == LinkDisconnect);
   assign link_connect_o    = (link_state_q != LinkDisconnect);
   assign link_suspend_o    = (link_state_q == LinkSuspend ||
     link_state_q == LinkPoweredSuspend);
   assign link_active_o     = (link_state_q == LinkActive) ||
     (link_state_q == LinkActiveNoSOF);
   // Link state is stable, so we can output it to the register
   assign link_state_o      =  link_state_q;

   // If the PHY reflects the line state on rx pins when the device is driving
   // then the usb_oe_i check isn't needed here. But it seems best to do the check
   // to be robust in the face of different PHY designs.
   logic see_se0, line_se0_raw;
   assign line_se0_raw = (usb_dn_i == 1'b0) & (usb_dp_i == 1'b0) & (usb_oe_i == 1'b0);

   // four ticks is a bit time
   // Could completely filter out 2-cycle EOP SE0 here but
   // does not seem needed
   prim_filter #(.Cycles(6)) filter_se0 (
     .clk_i    (clk_48mhz_i),
     .rst_ni   (rst_ni),
     .enable_i (1'b1),
     .filter_i (line_se0_raw),
     .filter_o (see_se0)
   );

   prim_filter #(.Cycles(6)) filter_pwr_sense (
     .clk_i    (clk_48mhz_i),
     .rst_ni   (rst_ni),
     .enable_i (1'b1),
     .filter_i (usb_sense_i),
     .filter_o (see_pwr_sense)
   );

   // Simple events
   assign ev_bus_active = !rx_jjj_det_i;

   assign monitor_inac = see_pwr_sense ? ((link_state_q == LinkPowered) | link_active_o) :
                         1'b0;

   always_comb begin
     link_state_d = link_state_q;
     link_resume_o = 0;

     // If VBUS ever goes away the link has disconnected
     if (!see_pwr_sense) begin
       link_state_d = LinkDisconnect;
     end else begin
       unique case (link_state_q)
         // No USB supply detected (USB spec: Attached)
         LinkDisconnect: begin
           if (see_pwr_sense) begin
             link_state_d = LinkPowered;
           end
         end

         LinkPowered: begin
           if (ev_reset) begin
             link_state_d = LinkActiveNoSOF;
           end else if (ev_bus_inactive) begin
             link_state_d = LinkPoweredSuspend;
           end
         end

         LinkPoweredSuspend: begin
           if (ev_reset) begin
             link_state_d = LinkActiveNoSOF;
           end else if (ev_bus_active) begin
             link_resume_o = 1;
             link_state_d  = LinkPowered;
           end
         end

         // Active but not yet seen a frame
         // One reason for getting stuck here is the host thinks it is a LS link
         // which could happen if the flipped bit does not match the actual pins
         // Annother is the SI is bad so good data is not recovered from the link
         LinkActiveNoSOF: begin
           if (ev_bus_inactive) begin
             link_state_d = LinkSuspend;
           end else if (sof_valid_i) begin
             link_state_d = LinkActive;
           end
         end

         // Active (USB spec: Default / Address / Configured)
         LinkActive: begin
           if (ev_bus_inactive) begin
             link_state_d = LinkSuspend;
           end else if (ev_reset) begin
             link_state_d = LinkActiveNoSOF;
           end
         end

         LinkSuspend: begin
           if (ev_reset) begin
             link_resume_o = 1;
             link_state_d  = LinkActiveNoSOF;
           end else if (ev_bus_active) begin
             link_resume_o = 1;
             link_state_d  = LinkActive;
           end
         end

         default: begin
           link_state_d = LinkDisconnect;
         end
       endcase // case (link_state_q)
     end
   end

   always_ff @(posedge clk_48mhz_i or negedge rst_ni) begin
     if (!rst_ni) begin
       link_state_q <= LinkDisconnect;
     end else begin
       link_state_q <= link_state_d;
     end
   end

   /////////////////////
   // Reset detection //
   /////////////////////
   //  Here we clean up the SE0 signal and generate a signle ev_reset at
   //  the end of a valid reset

   always_comb begin : proc_rst_fsm
     link_rst_state_d  = link_rst_state_q;
     link_rst_timer_d  = link_rst_timer_q;
     ev_reset          = 1'b0;
     link_reset        = 1'b0;

     unique case (link_rst_state_q)
       // No reset signal detected
       NoRst: begin
         if (see_se0) begin
           link_rst_state_d = RstCnt;
           link_rst_timer_d = 0;
         end
       end

       // Reset signal detected -> counting
       RstCnt: begin
         if (!see_se0) begin
           link_rst_state_d = NoRst;
         end else begin
           if (us_tick_i) begin
             if (link_rst_timer_q == RESET_TIMEOUT) begin
               link_rst_state_d = RstPend;
             end else begin
               link_rst_timer_d = link_rst_timer_q + 1;
             end
           end
         end
       end

       // Detected reset -> wait for falling edge
       RstPend: begin
         if (!see_se0) begin
           link_rst_state_d = NoRst;
           ev_reset = 1'b1;
         end
         link_reset = 1'b1;
       end

       default : link_rst_state_d = NoRst;
     endcase
   end

   assign link_reset_o = link_reset;

   always_ff @(posedge clk_48mhz_i or negedge rst_ni) begin : proc_reg_rst
     if (!rst_ni) begin
       link_rst_state_q <= NoRst;
       link_rst_timer_q <= 0;
     end else begin
       link_rst_state_q <= link_rst_state_d;
       link_rst_timer_q <= link_rst_timer_d;
     end
   end

   ////////////////////
   // Idle detection //
   ////////////////////
   //  Here we clean up the idle signal and generate a signle ev_bus_inactive
   //  after the timer expires
   always_comb begin : proc_idle_det
     link_inac_state_d = link_inac_state_q;
     link_inac_timer_d = link_inac_timer_q;
     ev_bus_inactive   = 0;

     unique case (link_inac_state_q)
       // Active or disabled
       Active: begin
         link_inac_timer_d = 0;
         if (!ev_bus_active && monitor_inac) begin
           link_inac_state_d = InactCnt;
         end
       end

       // Got an inactivity signal -> count duration
       InactCnt: begin
         if (ev_bus_active || !monitor_inac) begin
           link_inac_state_d  = Active;
         end else if (us_tick_i) begin
           if (link_inac_timer_q == SUSPEND_TIMEOUT) begin
             link_inac_state_d = InactPend;
             ev_bus_inactive = 1;
           end else begin
             link_inac_timer_d = link_inac_timer_q + 1;
           end
         end
       end

       // Counter expired & event sent, wait here
       InactPend: begin
         if (ev_bus_active || !monitor_inac) begin
           link_inac_state_d  = Active;
         end
       end

       default : link_inac_state_d = Active;
     endcase
   end

   always_ff @(posedge clk_48mhz_i or negedge rst_ni) begin : proc_reg_idle_det
     if (!rst_ni) begin
       link_inac_state_q <= Active;
       link_inac_timer_q <= 0;
     end else begin
       link_inac_state_q <= link_inac_state_d;
       link_inac_timer_q <= link_inac_timer_d;
     end
   end

   /////////////////////////
   // Host loss detection //
   /////////////////////////
   // host_lost if no sof in 4.096ms (supposed to be every 1ms)
   // and the link is active
   logic [12:0] host_presence_timer;

   assign host_lost_o = host_presence_timer[12];
   always_ff @(posedge clk_48mhz_i or negedge rst_ni) begin
     if (!rst_ni) begin
       host_presence_timer <= '0;
     end else begin
       if (sof_valid_i || !link_active_o || link_reset) begin
         host_presence_timer <= '0;
       end else if (us_tick_i && !host_lost_o) begin
         host_presence_timer <= host_presence_timer + 1;
       end
     end
   end

 endmodule
	// Copyright lowRISC contributors.
	// Licensed under the Apache License, Version 2.0, see LICENSE for details.
	// SPDX-License-Identifier: Apache-2.0
	//
	// Link state detection
	//

	module usbdev_linkstate (
	input logic clk_48mhz_i,
	input logic rst_ni,
	input logic us_tick_i,
	input logic usb_sense_i,
	input logic usb_dp_i,
	input logic usb_dn_i,
	input logic usb_oe_i,
	input logic rx_jjj_det_i,
	input logic sof_valid_i,
	output logic link_disconnect_o, // level
	output logic link_connect_o, // level
	output logic link_reset_o, // level
	output logic link_active_o, // level
	output logic link_suspend_o, // level
	output logic link_resume_o, // pulse
	output logic host_lost_o, // level

	output logic [2:0] link_state_o
	);

	localparam logic [11:0] SUSPEND_TIMEOUT = 12'd3000; // 3ms by spec
	localparam logic [2:0] RESET_TIMEOUT = 3'd3; // 3us. Can be 2.5us - 10ms by spec

	typedef enum logic [2:0] {
	// Unpowered state
	LinkDisconnect = 0,
	// Powered states
	LinkPowered = 1,
	LinkPoweredSuspend = 2,
	// Active states
	LinkActive = 3,
	LinkActiveNoSOF = 5,
	LinkSuspend = 4
	} link_state_e;

	typedef enum logic [1:0] {
	NoRst,
	RstCnt,
	RstPend
	} link_rst_state_e;

	typedef enum logic [1:0] {
	Active,
	InactCnt,
	InactPend
	} link_inac_state_e;

	link_state_e link_state_d, link_state_q;
	logic see_pwr_sense;

	// Reset FSM
	logic [2:0] link_rst_timer_d, link_rst_timer_q;
	link_rst_state_e link_rst_state_d, link_rst_state_q;
	logic link_reset; // reset detected (level)

	// Link inactivity detection
	logic monitor_inac; // monitor link inactivity
	logic [11:0] link_inac_timer_d, link_inac_timer_q;
	link_inac_state_e link_inac_state_d, link_inac_state_q;


	// Events that are not triggered by a timeout
	logic ev_bus_active;

	// Events that are triggered by timeout
	logic ev_bus_inactive, ev_reset;

	assign link_disconnect_o = (link_state_q == LinkDisconnect);
	assign link_connect_o = (link_state_q != LinkDisconnect);
	assign link_suspend_o = (link_state_q == LinkSuspend \|\|
	link_state_q == LinkPoweredSuspend);
	assign link_active_o = (link_state_q == LinkActive) \|\|
	(link_state_q == LinkActiveNoSOF);
	// Link state is stable, so we can output it to the register
	assign link_state_o = link_state_q;

	// If the PHY reflects the line state on rx pins when the device is driving
	// then the usb_oe_i check isn't needed here. But it seems best to do the check
	// to be robust in the face of different PHY designs.
	logic see_se0, line_se0_raw;
	assign line_se0_raw = (usb_dn_i == 1'b0) & (usb_dp_i == 1'b0) & (usb_oe_i == 1'b0);

	// four ticks is a bit time
	// Could completely filter out 2-cycle EOP SE0 here but
	// does not seem needed
	prim_filter #(.Cycles(6)) filter_se0 (
	.clk_i (clk_48mhz_i),
	.rst_ni (rst_ni),
	.enable_i (1'b1),
	.filter_i (line_se0_raw),
	.filter_o (see_se0)
	);

	prim_filter #(.Cycles(6)) filter_pwr_sense (
	.clk_i (clk_48mhz_i),
	.rst_ni (rst_ni),
	.enable_i (1'b1),
	.filter_i (usb_sense_i),
	.filter_o (see_pwr_sense)
	);

	// Simple events
	assign ev_bus_active = !rx_jjj_det_i;

	assign monitor_inac = see_pwr_sense ? ((link_state_q == LinkPowered) \| link_active_o) :
	1'b0;

	always_comb begin
	link_state_d = link_state_q;
	link_resume_o = 0;

	// If VBUS ever goes away the link has disconnected
	if (!see_pwr_sense) begin
	link_state_d = LinkDisconnect;
	end else begin
	unique case (link_state_q)
	// No USB supply detected (USB spec: Attached)
	LinkDisconnect: begin
	if (see_pwr_sense) begin
	link_state_d = LinkPowered;
	end
	end

	LinkPowered: begin
	if (ev_reset) begin
	link_state_d = LinkActiveNoSOF;
	end else if (ev_bus_inactive) begin
	link_state_d = LinkPoweredSuspend;
	end
	end

	LinkPoweredSuspend: begin
	if (ev_reset) begin
	link_state_d = LinkActiveNoSOF;
	end else if (ev_bus_active) begin
	link_resume_o = 1;
	link_state_d = LinkPowered;
	end
	end

	// Active but not yet seen a frame
	// One reason for getting stuck here is the host thinks it is a LS link
	// which could happen if the flipped bit does not match the actual pins
	// Annother is the SI is bad so good data is not recovered from the link
	LinkActiveNoSOF: begin
	if (ev_bus_inactive) begin
	link_state_d = LinkSuspend;
	end else if (sof_valid_i) begin
	link_state_d = LinkActive;
	end
	end

	// Active (USB spec: Default / Address / Configured)
	LinkActive: begin
	if (ev_bus_inactive) begin
	link_state_d = LinkSuspend;
	end else if (ev_reset) begin
	link_state_d = LinkActiveNoSOF;
	end
	end

	LinkSuspend: begin
	if (ev_reset) begin
	link_resume_o = 1;
	link_state_d = LinkActiveNoSOF;
	end else if (ev_bus_active) begin
	link_resume_o = 1;
	link_state_d = LinkActive;
	end
	end

	default: begin
	link_state_d = LinkDisconnect;
	end
	endcase // case (link_state_q)
	end
	end

	always_ff @(posedge clk_48mhz_i or negedge rst_ni) begin
	if (!rst_ni) begin
	link_state_q <= LinkDisconnect;
	end else begin
	link_state_q <= link_state_d;
	end
	end

	/////////////////////
	// Reset detection //
	/////////////////////
	// Here we clean up the SE0 signal and generate a signle ev_reset at
	// the end of a valid reset

	always_comb begin : proc_rst_fsm
	link_rst_state_d = link_rst_state_q;
	link_rst_timer_d = link_rst_timer_q;
	ev_reset = 1'b0;
	link_reset = 1'b0;

	unique case (link_rst_state_q)
	// No reset signal detected
	NoRst: begin
	if (see_se0) begin
	link_rst_state_d = RstCnt;
	link_rst_timer_d = 0;
	end
	end

	// Reset signal detected -> counting
	RstCnt: begin
	if (!see_se0) begin
	link_rst_state_d = NoRst;
	end else begin
	if (us_tick_i) begin
	if (link_rst_timer_q == RESET_TIMEOUT) begin
	link_rst_state_d = RstPend;
	end else begin
	link_rst_timer_d = link_rst_timer_q + 1;
	end
	end
	end
	end

	// Detected reset -> wait for falling edge
	RstPend: begin
	if (!see_se0) begin
	link_rst_state_d = NoRst;
	ev_reset = 1'b1;
	end
	link_reset = 1'b1;
	end

	default : link_rst_state_d = NoRst;
	endcase
	end

	assign link_reset_o = link_reset;

	always_ff @(posedge clk_48mhz_i or negedge rst_ni) begin : proc_reg_rst
	if (!rst_ni) begin
	link_rst_state_q <= NoRst;
	link_rst_timer_q <= 0;
	end else begin
	link_rst_state_q <= link_rst_state_d;
	link_rst_timer_q <= link_rst_timer_d;
	end
	end

	////////////////////
	// Idle detection //
	////////////////////
	// Here we clean up the idle signal and generate a signle ev_bus_inactive
	// after the timer expires
	always_comb begin : proc_idle_det
	link_inac_state_d = link_inac_state_q;
	link_inac_timer_d = link_inac_timer_q;
	ev_bus_inactive = 0;

	unique case (link_inac_state_q)
	// Active or disabled
	Active: begin
	link_inac_timer_d = 0;
	if (!ev_bus_active && monitor_inac) begin
	link_inac_state_d = InactCnt;
	end
	end

	// Got an inactivity signal -> count duration
	InactCnt: begin
	if (ev_bus_active \|\| !monitor_inac) begin
	link_inac_state_d = Active;
	end else if (us_tick_i) begin
	if (link_inac_timer_q == SUSPEND_TIMEOUT) begin
	link_inac_state_d = InactPend;
	ev_bus_inactive = 1;
	end else begin
	link_inac_timer_d = link_inac_timer_q + 1;
	end
	end
	end

	// Counter expired & event sent, wait here
	InactPend: begin
	if (ev_bus_active \|\| !monitor_inac) begin
	link_inac_state_d = Active;
	end
	end

	default : link_inac_state_d = Active;
	endcase
	end

	always_ff @(posedge clk_48mhz_i or negedge rst_ni) begin : proc_reg_idle_det
	if (!rst_ni) begin
	link_inac_state_q <= Active;
	link_inac_timer_q <= 0;
	end else begin
	link_inac_state_q <= link_inac_state_d;
	link_inac_timer_q <= link_inac_timer_d;
	end
	end

	/////////////////////////
	// Host loss detection //
	/////////////////////////
	// host_lost if no sof in 4.096ms (supposed to be every 1ms)
	// and the link is active
	logic [12:0] host_presence_timer;

	assign host_lost_o = host_presence_timer[12];
	always_ff @(posedge clk_48mhz_i or negedge rst_ni) begin
	if (!rst_ni) begin
	host_presence_timer <= '0;
	end else begin
	if (sof_valid_i \|\| !link_active_o \|\| link_reset) begin
	host_presence_timer <= '0;
	end else if (us_tick_i && !host_lost_o) begin
	host_presence_timer <= host_presence_timer + 1;
	end
	end
	end

	endmodule