gary/lib/UART.bsv

package UART;

import Cntrs::*;
import GetPut::*;
import FIFOF::*;
import SpecialFIFOs::*;
import StmtFSM::*;
import Connectable::*;

import PinSync::*;
import GlitchFilter::*;
import Strobe::*;

(* always_enabled *)
interface UART_RX_PHY;
   (* prefix="" *)
   method Action rx_in((* port="rx_in" *) bit b);
   (* result="cts" *)
   method Bool stop_sending();
endinterface

(* always_enabled *)
interface UART_TX_PHY;
   (* result="tx_out" *)
   method bit tx_out();
   (* prefix="" *)
   method Action can_send((* port="rts" *) Bool send);
endinterface

(* always_enabled *)
interface UART_PHY;
   (* prefix="" *)
   method Action rx_in((* port="rx_in" *) bit b);
   (* result="tx_out" *)
   method bit tx_out();
   (* result="cts" *)
   method Bool stop_sending();
   (* prefix="" *)
   method Action can_send((* port="rts" *) Bool send);
endinterface

interface UART_RX;
   interface UART_RX_PHY phy;
   interface Get#(Bit#(8)) receive;
endinterface

interface UART_TX;
   interface UART_TX_PHY phy;
   interface Put#(Bit#(8)) send;
endinterface

interface UART;
   interface UART_PHY phy;
   interface Put#(Bit#(8)) send;
   interface Get#(Bit#(8)) receive;
endinterface

typedef enum {
   WaitIdle,
   Idle,
   Read,
   Stop,
   Cork
} RXState deriving (Bits, Eq);

module mkUARTReceiver(Integer clock_frequency, Integer uart_bitrate, UART_RX ifc);
   Reg#(bit) rx_sync <- mkPinSync(0);
   let rx_in <- mkGlitchFilter(3, 0);
   mkConnection(toGet(asReg(rx_sync)), toPut(asReg(rx_in)));

   Reg#(RXState) rx_state <- mkReg(WaitIdle);
   Strobe bit_16x_strobe <- mkStrobe(clock_frequency, 16*uart_bitrate);
   Count#(UInt#(4)) cnt <- mkCount(0);
   Reg#(Bit#(8)) shift_in <- mkReg(0);
   FIFOF#(Bit#(8)) rx <- mkBypassFIFOF();

   (* no_implicit_conditions, fire_when_enabled *)
   rule rx_counter (bit_16x_strobe);
      cnt.incr(1);
   endrule

   (* no_implicit_conditions, fire_when_enabled *)
   rule rx_wait_idle (rx_state == WaitIdle && bit_16x_strobe && rx_in == 1);
      rx_state <= Idle;
   endrule

   (* no_implicit_conditions, fire_when_enabled *)
   rule rx_idle (rx_state == Idle && bit_16x_strobe && rx_in == 0);
      rx_state <= Read;
      cnt <= 1;
      shift_in <= 8'hFF;
   endrule

   (* no_implicit_conditions, fire_when_enabled *)
   rule rx_read (rx_state == Read && bit_16x_strobe && cnt == 7);
      let shifted_out = shift_in[0];
      shift_in <= {rx_in, shift_in[7:1]};
      if (shifted_out == 0) begin // start bit reached end of shiftreg
         rx_state <= Stop;
      end
   endrule

   (* fire_when_enabled *)
   rule rx_stop (rx_state == Stop);
      if (rx.notFull) begin
         rx.enq(shift_in);
         rx_state <= WaitIdle;
      end
      else
         rx_state <= Cork;
   endrule

   (* fire_when_enabled *)
   rule rx_cork (rx_state == Cork);
      rx.enq(shift_in);
      rx_state <= WaitIdle;
   endrule

   interface UART_RX_PHY phy;
      method rx_in = rx_sync._write;
      method Bool stop_sending();
         // Signal is active low, so 1 == "stop sending"
         return rx_state == Cork;
      endmethod
   endinterface

   interface receive = toGet(rx);
endmodule

typedef enum {
   Idle,
   Ready,
   Send
} TXState deriving (Bits, Eq);

module mkUARTTransmitter(Integer clock_frequency, Integer uart_bitrate, UART_TX ifc);
   Reg#(bit) cts_sync <- mkPinSync(0);
   let cts_in <- mkGlitchFilter(3, 0);
   mkConnection(toGet(asReg(cts_sync)), toPut(asReg(cts_in)));

   Reg#(TXState) tx_state <- mkReg(Idle);
   Strobe bit_strobe <- mkStrobe(clock_frequency, uart_bitrate);
   Reg#(UInt#(4)) cnt <- mkReg(0);
   Reg#(Bit#(9)) shift_out <- mkReg(9'h1FF);
   FIFOF#(Bit#(8)) tx <- mkPipelineFIFOF();

   (* fire_when_enabled *)
   rule tx_idle (tx_state == Idle && tx.notEmpty);
      shift_out <= {tx.first, 0};
      tx.deq();
      tx_state <= Ready;
      bit_strobe.reset();
   endrule

   (* no_implicit_conditions, fire_when_enabled *)
   rule rx_ready (tx_state == Ready && bit_strobe && cts_in == 1);
      tx_state <= Send;
      cnt <= 0;
   endrule

   (* no_implicit_conditions, fire_when_enabled *)
   rule tx_send (tx_state == Send && bit_strobe);
      shift_out <= {1'b1, shift_out[8:1]};
      cnt <= cnt+1;
      if (cnt == 9)
         tx_state <= Idle;
   endrule

   interface UART_TX_PHY phy;
      method bit tx_out();
         if (tx_state == Send)
            return shift_out[0];
         else
            return 1'b1;
      endmethod
      method Action can_send(b);
         cts_sync <= pack(b);
      endmethod
   endinterface

   interface Put send = toPut(tx);
endmodule

module mkUART(Integer clock_frequency, Integer uart_bitrate, UART ifc);
   let _rx <- mkUARTReceiver(clock_frequency, uart_bitrate);
   let _tx <- mkUARTTransmitter(clock_frequency, uart_bitrate);

   interface UART_PHY phy;
      method rx_in = _rx.phy.rx_in;
      method tx_out = _tx.phy.tx_out;
      method stop_sending = _rx.phy.stop_sending;
      method can_send = _tx.phy.can_send;
   endinterface
   interface send = _tx.send;
   interface receive = _rx.receive;
endmodule

typeclass FlowControlled#(type ifc);
   module disableFlowControl(ifc i, Empty ret);
endtypeclass

instance FlowControlled#(UART_RX_PHY);
   module disableFlowControl(UART_RX_PHY phy, Empty ifc);
   endmodule
endinstance

instance FlowControlled#(UART_TX_PHY);
   module disableFlowControl(UART_TX_PHY phy, Empty ifc);
      (* no_implicit_conditions,fire_when_enabled *)
      rule always_send;
         phy.can_send(True);
      endrule
   endmodule
endinstance

instance FlowControlled#(UART_PHY);
   module disableFlowControl(UART_PHY phy, Empty ifc);
      (* no_implicit_conditions,fire_when_enabled *)
      rule always_send;
         phy.can_send(True);
      endrule
   endmodule
endinstance

instance FlowControlled#(UART_RX);
   module disableFlowControl(UART_RX rx, Empty ifc);
      disableFlowControl(rx.phy);
   endmodule
endinstance

instance FlowControlled#(UART_TX);
   module disableFlowControl(UART_TX tx, Empty ifc);
      disableFlowControl(tx.phy);
   endmodule
endinstance

instance FlowControlled#(UART);
   module disableFlowControl(UART uart, Empty ifc);
      disableFlowControl(uart.phy);
   endmodule
endinstance

endpackage
debugger/UART: implement a UART with RTS/CTS flow control In practice the flow control is unusable on ULX3S dev boards because the CTS line isn't hooked up (it's instead wired to JTAG_TDO, to enable the USB<>UART chip to serve a dual purpose as a bitbanged JTAG programmer) Still, support for flow control is nice, for the future. And the UART itself also works regardless of flow control, which is of course nice. 2024-09-09 21:47:19 +02:00			`package UART;`

			`import Cntrs::*;`
			`import GetPut::*;`
			`import FIFOF::*;`
			`import SpecialFIFOs::*;`
			`import StmtFSM::*;`
			`import Connectable::*;`

			`import PinSync::*;`
			`import GlitchFilter::*;`
			`import Strobe::*;`

			`(* always_enabled *)`
			`interface UART_RX_PHY;`
			`(* prefix="" *)`
			`method Action rx_in((* port="rx_in" *) bit b);`
			`(* result="cts" *)`
			`method Bool stop_sending();`
			`endinterface`

			`(* always_enabled *)`
			`interface UART_TX_PHY;`
			`(* result="tx_out" *)`
			`method bit tx_out();`
			`(* prefix="" *)`
			`method Action can_send((* port="rts" *) Bool send);`
			`endinterface`

			`(* always_enabled *)`
			`interface UART_PHY;`
			`(* prefix="" *)`
			`method Action rx_in((* port="rx_in" *) bit b);`
			`(* result="tx_out" *)`
			`method bit tx_out();`
			`(* result="cts" *)`
			`method Bool stop_sending();`
			`(* prefix="" *)`
			`method Action can_send((* port="rts" *) Bool send);`
			`endinterface`

			`interface UART_RX;`
			`interface UART_RX_PHY phy;`
			`interface Get#(Bit#(8)) receive;`
			`endinterface`

			`interface UART_TX;`
			`interface UART_TX_PHY phy;`
			`interface Put#(Bit#(8)) send;`
			`endinterface`

			`interface UART;`
			`interface UART_PHY phy;`
			`interface Put#(Bit#(8)) send;`
			`interface Get#(Bit#(8)) receive;`
			`endinterface`

			`typedef enum {`
			`WaitIdle,`
			`Idle,`
			`Read,`
			`Stop,`
			`Cork`
			`} RXState deriving (Bits, Eq);`

			`module mkUARTReceiver(Integer clock_frequency, Integer uart_bitrate, UART_RX ifc);`
			`Reg#(bit) rx_sync <- mkPinSync(0);`
			`let rx_in <- mkGlitchFilter(3, 0);`
			`mkConnection(toGet(asReg(rx_sync)), toPut(asReg(rx_in)));`

			`Reg#(RXState) rx_state <- mkReg(WaitIdle);`
			`Strobe bit_16x_strobe <- mkStrobe(clock_frequency, 16*uart_bitrate);`
			`Count#(UInt#(4)) cnt <- mkCount(0);`
			`Reg#(Bit#(8)) shift_in <- mkReg(0);`
			`FIFOF#(Bit#(8)) rx <- mkBypassFIFOF();`

			`(* no_implicit_conditions, fire_when_enabled *)`
			`rule rx_counter (bit_16x_strobe);`
			`cnt.incr(1);`
			`endrule`

			`(* no_implicit_conditions, fire_when_enabled *)`
			`rule rx_wait_idle (rx_state == WaitIdle && bit_16x_strobe && rx_in == 1);`
			`rx_state <= Idle;`
			`endrule`

			`(* no_implicit_conditions, fire_when_enabled *)`
			`rule rx_idle (rx_state == Idle && bit_16x_strobe && rx_in == 0);`
			`rx_state <= Read;`
			`cnt <= 1;`
			`shift_in <= 8'hFF;`
			`endrule`

			`(* no_implicit_conditions, fire_when_enabled *)`
			`rule rx_read (rx_state == Read && bit_16x_strobe && cnt == 7);`
			`let shifted_out = shift_in[0];`
			`shift_in <= {rx_in, shift_in[7:1]};`
			`if (shifted_out == 0) begin // start bit reached end of shiftreg`
			`rx_state <= Stop;`
			`end`
			`endrule`

			`(* fire_when_enabled *)`
			`rule rx_stop (rx_state == Stop);`
			`if (rx.notFull) begin`
			`rx.enq(shift_in);`
			`rx_state <= WaitIdle;`
			`end`
			`else`
			`rx_state <= Cork;`
			`endrule`

			`(* fire_when_enabled *)`
			`rule rx_cork (rx_state == Cork);`
			`rx.enq(shift_in);`
			`rx_state <= WaitIdle;`
			`endrule`

			`interface UART_RX_PHY phy;`
			`method rx_in = rx_sync._write;`
			`method Bool stop_sending();`
			`// Signal is active low, so 1 == "stop sending"`
			`return rx_state == Cork;`
			`endmethod`
			`endinterface`

			`interface receive = toGet(rx);`
			`endmodule`

			`typedef enum {`
			`Idle,`
			`Ready,`
			`Send`
			`} TXState deriving (Bits, Eq);`

			`module mkUARTTransmitter(Integer clock_frequency, Integer uart_bitrate, UART_TX ifc);`
			`Reg#(bit) cts_sync <- mkPinSync(0);`
			`let cts_in <- mkGlitchFilter(3, 0);`
			`mkConnection(toGet(asReg(cts_sync)), toPut(asReg(cts_in)));`

			`Reg#(TXState) tx_state <- mkReg(Idle);`
			`Strobe bit_strobe <- mkStrobe(clock_frequency, uart_bitrate);`
			`Reg#(UInt#(4)) cnt <- mkReg(0);`
			`Reg#(Bit#(9)) shift_out <- mkReg(9'h1FF);`
			`FIFOF#(Bit#(8)) tx <- mkPipelineFIFOF();`

			`(* fire_when_enabled *)`
			`rule tx_idle (tx_state == Idle && tx.notEmpty);`
			`shift_out <= {tx.first, 0};`
			`tx.deq();`
			`tx_state <= Ready;`
			`bit_strobe.reset();`
			`endrule`

			`(* no_implicit_conditions, fire_when_enabled *)`
			`rule rx_ready (tx_state == Ready && bit_strobe && cts_in == 1);`
			`tx_state <= Send;`
			`cnt <= 0;`
			`endrule`

			`(* no_implicit_conditions, fire_when_enabled *)`
			`rule tx_send (tx_state == Send && bit_strobe);`
			`shift_out <= {1'b1, shift_out[8:1]};`
			`cnt <= cnt+1;`
			`if (cnt == 9)`
			`tx_state <= Idle;`
			`endrule`

			`interface UART_TX_PHY phy;`
			`method bit tx_out();`
			`if (tx_state == Send)`
			`return shift_out[0];`
			`else`
			`return 1'b1;`
			`endmethod`
			`method Action can_send(b);`
			`cts_sync <= pack(b);`
			`endmethod`
			`endinterface`

			`interface Put send = toPut(tx);`
			`endmodule`

			`module mkUART(Integer clock_frequency, Integer uart_bitrate, UART ifc);`
			`let _rx <- mkUARTReceiver(clock_frequency, uart_bitrate);`
			`let _tx <- mkUARTTransmitter(clock_frequency, uart_bitrate);`

			`interface UART_PHY phy;`
			`method rx_in = _rx.phy.rx_in;`
			`method tx_out = _tx.phy.tx_out;`
			`method stop_sending = _rx.phy.stop_sending;`
			`method can_send = _tx.phy.can_send;`
			`endinterface`
			`interface send = _tx.send;`
			`interface receive = _rx.receive;`
			`endmodule`

			`typeclass FlowControlled#(type ifc);`
			`module disableFlowControl(ifc i, Empty ret);`
			`endtypeclass`

			`instance FlowControlled#(UART_RX_PHY);`
			`module disableFlowControl(UART_RX_PHY phy, Empty ifc);`
			`endmodule`
			`endinstance`

			`instance FlowControlled#(UART_TX_PHY);`
			`module disableFlowControl(UART_TX_PHY phy, Empty ifc);`
			`(* no_implicit_conditions,fire_when_enabled *)`
			`rule always_send;`
			`phy.can_send(True);`
			`endrule`
			`endmodule`
			`endinstance`

			`instance FlowControlled#(UART_PHY);`
			`module disableFlowControl(UART_PHY phy, Empty ifc);`
			`(* no_implicit_conditions,fire_when_enabled *)`
			`rule always_send;`
			`phy.can_send(True);`
			`endrule`
			`endmodule`
			`endinstance`

			`instance FlowControlled#(UART_RX);`
			`module disableFlowControl(UART_RX rx, Empty ifc);`
			`disableFlowControl(rx.phy);`
			`endmodule`
			`endinstance`

			`instance FlowControlled#(UART_TX);`
			`module disableFlowControl(UART_TX tx, Empty ifc);`
			`disableFlowControl(tx.phy);`
			`endmodule`
			`endinstance`

			`instance FlowControlled#(UART);`
			`module disableFlowControl(UART uart, Empty ifc);`
			`disableFlowControl(uart.phy);`
			`endmodule`
			`endinstance`

			`endpackage`