Author Topic: Verilog RS232 Synch-UART & RS232 Debugger source code and educational tutorial.  (Read 7895 times)

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Offline BrianHGTopic starter

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     Ok, I've worked on this utility over the past 2 weeks for use in the 'FPGA VGA Controller for 8-bit computer' thread.  I wanted a means to access/peek into a FPGA project which had a memory bus.  I designed a Verilog core to do this and since I was really helping out in the thread, and this core plus PC host HEX viewer/editor works really well, I figured I would document the source code really well and provide it as an example & tutorial material.

There are 3 pieces:

1) The ' SYNC_RS232_UART.v ' : A synchronizing RS232 transceiver.  The 'synchronizing' transmitter with the receiver is crucial when interfacing with a PC as high speed full duplex communication require that the bit and word timing of serial data coming into the PC matches the clock and phase of the data the PC may be transmitting out at the same time.  Many simple example Verilog RS232 UARTs arent capable of this.  Read attached source code and see attached illustration to show you an example setup where my transmitter aligns itself to a received RS232 serial signal with a slightly different baud rate.

878970-0

Get full code in attached .v.txt file.


2) The ' RS232_Debugger.v ' : A Verilog module which uses the SYNC_RS232_UART.v, has an RS232 RXD input and TXD output.  It also has a memory address output and 8 bit memory data input and output with a memory read request and memory write enable.  This module also provides a reset output, 4 utility 8 bit output ports and 4 utility 8 bit input ports.  Once again, everything is documented in the available 'RS232_Debugger.v' source code and I'm here to answer questions.

878974-1

Get full code in attached .v.txt file.


3) The ' RS232_Debugger.exe ' Viewer / HEX editor software.  (For now, I haven't included the source code for this one, give me a week to clean it up first, though, it is fully functional.)  The software offers real-time viewing and editing of the user configured memory size set in the RS232_Debugger.v's memory address size parameter while also continuously displaying the values of the 4 utility 8 bit input ports as well as being able to set the values of the 4 utility 8 bit output ports.  When the RS232 com port is closed, the RS232_Debugger.exe functions as a stand alone HEX / ASCII file editor which can edit up to 1 megabyte files.


The Verilog code was written using pure synchronous logic.  No fancy async-reset/presets, no S/R, J-K flipflops.  These examples should easily integrate into any vendor's FPGAs EDA tool platform.  If anyone out there has success, let us know.

Update: Get version 1.1 of ' RS232_Debugger.v ' here: RS232_Debugger.v Ver 1.1

Update: Get versions 1.2 which now work in ModelSim here: RS232_UART & RS232_Debugger V1.2

Get latest hex editor here: RS232 Hex Editor V1.3, Jan 14, 2022
« Last Edit: January 14, 2022, 06:33:05 pm by BrianHG »
 
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Offline BrianHGTopic starter

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This is the source for the 'SYNC_RS232_UART.v':
Code: [Select]
// *****************************************************************
// *** SYNC_RS232_UART.v V1.0, November 22, 2019
// ***
// *** This transceiver follows slight baud timing errors introduced
// *** by the external host interface's clock making the TDX output
// *** clock timing synchronize to the RXD coming in allowing
// *** high speed synchronous communications.  A requirement
// *** for PC RS232 full duplex synchronous communications.
// ***
// *** Written by Brian Guralnick.
// *** Using generic Verilog code which only uses synchronous logic.
// *** Well commented for educational purposes.
// *****************************************************************

module sync_rs232_uart (
input  wire       clk,            // System clock
input  wire       rxd,            // RS232 serial input data pin
output reg        rx_rdy,         // Pulsed high for 1 system clock when the received 8 bit data byte is ready
output reg  [7:0] rx_data,        // Received 8 bit data byte.

input  wire       ena_tx,         // Signals the transmitter to latch the 8 bit data and begin transmitting
input  wire [7:0] tx_data,        // 8 bit data byte input to be transmitted
output reg        txd,            // RS232 serial output data pin
output reg        tx_busy,        // High when transmitter is busy.  Low when you may load a byte to transmit

output reg        rx_sample_pulse // For debugging RXD errors only.  This is an output test pulse
                                  // aligned to when the receiver has sampled the RXD input.
  ) ;

// Setup parameters
parameter CLK_IN_HZ    = 50000000;    // Set to system input clock frequency
parameter BAUD_RATE    = 921600;      // Set to desired baud rate

localparam RX_PERIOD    = (CLK_IN_HZ / BAUD_RATE) -1 ; // Set's a reference counter size for each transmitted/received serial data bit
localparam TX_PERIOD    = (CLK_IN_HZ / BAUD_RATE) -1 ;

// Receiver regs
reg     [15:0]     rx_period ;
reg     [3:0]      rx_position ;
reg     [9:0]      rx_byte ;
reg                rxd_reg, last_rxd ;
reg    rx_busy, rx_last_busy ;

// Transmitter regs
reg     [15:0]     tx_period   = 16'h0 ;
reg     [3:0]      tx_position = 4'h0 ;
reg     [9:0]      tx_byte     = 10'b1111111111 ;
reg     [7:0]      tx_data_reg = 8'b11111111 ;
reg                tx_run      = 1'b0 ;



//********************************************************************************************
// make the rx_trigger 'WIRE' equal to any new RXD input High to Low transition (IE start bit)
// when the receiver is not busy receiving a byte
//********************************************************************************************
wire    rx_trigger ;
assign  rx_trigger = ( ~rxd_reg && last_rxd && ~rx_busy );


always @ (posedge clk) begin
//********************************
// Receiver functions.
//********************************

// register clock the UART RDX input signal.
// This is a personal preference as I prefer FPGA inputs which don't directly feed combinational logic
rxd_reg      <= rxd;
last_rxd     <= rxd_reg;                  // create a 1 clock delay register of the rxd_reg serial bit

rx_last_busy <= rx_busy;                  // create a 1 clock delay of the rx_busy resister.
rx_rdy       <= rx_last_busy && ~rx_busy; // create the rx_rdy out pulse for 1 single clock when the rx_busy flag has gone low signifying that rx_data is ready


if ( rx_trigger ) begin                                        // if a 'rx_trigger' event has taken place
rx_period      <= ( RX_PERIOD[15:0] >> 1 ) ; // set the period clock to half way inside a serial bit.  This makes the best time to sample incoming
                                             // serial bits as the source baud rate may be slightly slow or fast maintaining a good data capture window all the way until the stop bit
rx_busy        <= 1'd1 ;                     // set the rx_busy flag to signify operation of the UART serial receiver
rx_position    <= 4'h9 ;                     // set the serial bit counter to position 9
end else begin

if ( rx_period==0 ) begin      // if the receiver period counter has reached it's end
rx_period     <=  RX_PERIOD[15:0] ;    // reset the period counter
rx_sample_pulse <=  rx_busy ;                // *** This is only a test pulse for debugging purposes

if ( rx_position != 0 ) begin                  // if the receiver's bit position counter hasn't reached it's end
rx_position   <= rx_position - 1'd1 ;  // decrement the position counter
rx_byte[9]    <= rxd_reg ;             // load the receiver's serial shift regitser with the RXD input pin
rx_byte[8:0]  <= rx_byte[9:1] ;        // shift the input serial shift register.

end else begin                         // if the receiver's bit position counter reached 0
rx_data       <= rx_byte[9:2]; // load the output data register with the correct 8 bit contents of the serial input register
rx_busy       <= 1'b0;         // turn off the serial receiver busy flag
end

end else begin                                 // if the receiver period counter has not reached it's end
rx_period <= rx_period - 1'b1; // just decrement the receiver period counter
rx_sample_pulse <=  1'b0 ;     // *** This is only a test pulse for debugging purposes
end
end // ~rx_trigger



//***********************************************************
// SYNCHRONOUS! Transmitter functions
//              This was the most puzzling to get just right
//              So that both high and low speed intermittent
//              and continuous COM transactions would never
//              cause a byte error when communicating with
//              a PC as fast as possible.
//***********************************************************

if (ena_tx) begin                    // If a transmit request comes in
tx_data_reg    <= tx_data ;  // register a copy of the input data bus
tx_busy        <= 1 ;        // Set the busy flag
end


// ***********************************************************************************************************************
// This section prepares the data, controls and shift register during the middle of the previous transmission bit.
// ***********************************************************************************************************************

if ( tx_period == (TX_PERIOD[15:0] >> 1) ) begin    // ******* at the center of a serial transmitter bit ********

if ( tx_position==1 ) begin      // during the transmission of a stop bit
tx_run  <= 0 ;   // turn off the transmitter running flag.  This point is the beginning of when
                 // a synchronous transmit word alignment to an incomming RXD rx_trigger is permitted

if (tx_busy) begin                         // before the next start bit, if the busy flag was set,
tx_byte[8:1] <= tx_data_reg[7:0] ; // load the register copy of the tx_data_reg into the serial shift register
tx_byte[9]   <= 1'b1 ;             // Add a stop bit into the shift register's 10th bit
tx_byte[0]   <= 1'b0 ;             // Add a start bit into the serial shift register's first bit
tx_busy      <= 1'b0 ;             // Turn off the busy flag signifying that another transmit byte may be loaded
end    // into the tx_data_reg

end else begin

tx_byte[8:0] <= tx_byte[9:1] ;   // at any other point than the stop-bit period, shift the serial tx_byte shift register
tx_byte[9]   <= 1'b1 ;           // load a default stop bit into bit 10 of the serial shift register

if ( tx_position == 0 ) tx_run  <= ~txd ;  // during the 'center of a serial 'START' transmitter bit'
                           // if the serial UART TXD output pin has a start bit, turn on the transmitter running flag
                           // which signifies the point where it is no longer permit-able to align a transmit word
                           // to an incoming RXD byte potentially corrupting a serial transmission.
end
end


// ***********************************************************************************************************************
// This section takes the above prepared registers and sends them out during the transition edge of the tx_period clock
// and during inactivity, or during the permitted alignment window, it will re-align the transmission period clock to
// a potential incoming rx_trigger event.
// ***********************************************************************************************************************

// if a RXD start bit transition edge is detected and the transmitter is not running,
// IE during the safe synchronous transmit word alignment period
// set halfway between the center of transmitting the stop bit and next start bit

if (  rx_trigger && ~tx_run ) begin

tx_period      <= TX_PERIOD[15:0] - 2'h2 ;    // reset "SYNCHRONIZE" the transmit period timer to the rx_trigger event, recognizing that the rx_trigger is
      // delayed by 2 clocks, so we shave off 2 additional clock cycles for dead perfect parallel TXD output alignment.

tx_position    <= 1'b0 ;                      // force set the transmit reference position to the start bit
txd            <= tx_byte[0] ;                // immediately set the UART TXD output to the serial out shift register's start bit.  IE see above if(tx_busy)

end else if ( tx_period==0  )begin                    // if the transmitter period counter has reached it's end

tx_period      <= TX_PERIOD[15:0]  ;          // reset the period counter
txd            <= tx_byte[0] ;                // set the UART TXD output to the serial shift register's output.

if ( tx_position == 0 ) tx_position <= 4'h9 ; // if the transmitter reference bit position counter is at the start bit, set it to bit 1.
else tx_position  <= tx_position - 1'b1 ;     // otherwise, count down the position counter towards the stop bit

end else tx_period <= tx_period - 1'b1 ;              // if the transmit period has not reached it's end, it should count down.

end // always

endmodule
 
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Offline BrianHGTopic starter

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Get version 1.1 here: RS232_Debugger.v Ver 1.1
This is the source for the 'rs232_DEBUGGER.v' version 1.0:
Code: [Select]
// *********************************************************************************
// *** RS232_Debugger.v Ver 1.0.  November 22, 2019
// ***
// *** This RS232_Debugger.v allows a PC to access, real-time
// *** display & edit up to 16 megabytes of addressable memory.
// *** (For PCs with a 921600 baud limit, 1 megabyte max memory
// *** recommended as it takes 14 seconds to transfer that entire
// *** block of memory.  This improves with faster com ports as the FPGA
// *** can easily achieve more than 10 megabaud with this Verilog code.)
// ***
// *** This RS232_Debugger.v can also generate a reset signal sent from the
// *** PC control software and it also has 4 utility 8 bit input ports which
// *** are continuously monitored  and displayed in real-time.  It also has 4
// *** utility 8 bit output ports which can be set to any value at any time.
// ***
// *** In a minimum configuration, this module uses 370 logic cells + the required
// *** SYNC_RS232_UART.v uses 107 logic cells for a total of 477 logic cells.  The
// *** total increases to 570 logic cells when every feature and all 24 address
// *** bits are being used.
// ***
// *** Written by and (C) Brian Guralnick.
// *** Using generic Verilog code which only uses synchronous logic.
// *** Well commented and intended for educational purposes.
// ***
// *********************************************************************************


module rs232_debugger (

    input  wire clk,       // System clock.  Recommend at least 20MHz for the 921600 baud rate.
                           // This module is capable of over 100MHz on even the slowest FPGAs.

output reg  cmd_rst,   // When sent by the PC RS232_Debugger utility, this outputs a high signal for 8 clock cycles.
                       // It also runs high for 8 clock cycles during power-up.

    input  wire rxd,       // Connect this to the RS232 RXD input pin.
    output wire txd,       // Connect this to the RS232 TXD output pin.

output reg         LED_txd,             // Optionally wire this to a LED, it will go high whenever the RS232 TXD is active.
output reg         LED_rxd,             // Optionally wire this to a LED, it will go high whenever the RS232 RXD is active.

output reg         host_rd_req,         // This output will pulse high for 1 clock when a read request is taking place.
input  wire        host_rd_rdy,         // This input should be set high once the 'host_rdata[7:0]' input contains valid data.
// Tie this input high if your read data will be always valid within 12 clock cycles since the hosr_rd_req.

output reg         host_wr_ena,         // This output will pulse high for 1 clock when a write request is taking place.

output wire [ADDR_SIZE-1:0] host_addr,  // This output contains the requested read and write address.
output reg  [7:0]  host_wdata,          // This output contains the source RS232 8bit data to be written.
input  wire [7:0]  host_rdata,          // This input receives the 8 bit ram data to be sent to the RS232.
                                        // If 'host_rd_rdy' is tied to '1' the data needs to be valid within 12 clocks of the 'host_rd_req' pulse.

// These are 4 8 bit utility input ports which are continuously read and displayed in the RS232_Debugger utility.
input  wire [7:0]  in0,
input  wire [7:0]  in1,
input  wire [7:0]  in2,
input  wire [7:0]  in3,


// These are 4 8 bit utility output ports which are set by the RS232_Debugger utility.
output reg  [7:0]  out0,
output reg  [7:0]  out1,
output reg  [7:0]  out2,
output reg  [7:0]  out3
);

reg [7:0] in_reg0,in_reg1,in_reg2,in_reg3; // These 'in_reg#[7:0]' will be used to latch all 4 'in#[7:0]' inputs in parallel before transmitting their state through the RS232 transceiver.

parameter CLK_IN_HZ    = 50000000;  // Set this parameter to your clock system clock frequency in Hertz
parameter BAUD_RATE    = 921600;    // Keep this parameter at 921600 for the commanding RS232_Debugger PC software.
parameter ADDR_SIZE    = 20;        // This sets the address size for the memory access.  24 is maximum, but unrealistic
                                    // at 921600 baud as it would take almost 4 minutes to transfer everything.  20 address bits,
                                    // 1048576 bytes / 1 megabyte takes around 14 seconds to transfer with the built in overhead.
                                    // For those who can access faster RS232 ports, these larger memory sizes could become more viable.

localparam CLK_1KHz_PERIOD  = CLK_IN_HZ / 1000 ;     // The counter period for generating an internal 1 KHz timer
localparam DEBUG_WDT_TIME   = 4'd15;                 // Com activity watch dog timer.  Time until a incomming Write to ram command is aborted due to inactive com.
localparam LED_HOLD_TIME    = 4'd15;                 // Keep the LED_rxd/txd signal high for at least this amount of ms time during RXD/TXD transactions.

reg        [17:0]  tick_1KHz_counter ;               // This reg is the counter for the main clock input which is used to generate the 1KHz timer.
reg                tick_1KHz ;                       // This reg will pulse for 1 'clk' cycle at 1KHz.
reg        [4:0]   timeout_cnt;          // This is a counter which is used for the communications watch dog timer which times out at the 'DEBUG_WDT' parameter count running at 1KHz speed.
reg        [4:0]   led_txd_timeout, led_rxd_timeout; // These are timer counters used to keep the communication status LEDs on for the 'LED_HOLD_TIME' parameter count running at 1KHz speed.



// *****************************************************************************************************************************************************************************
// **** Example command structure shown in RS232 received and transmitted hex bytes:
// ****
// **** Example #1: CMD_READ_BYTES (See figure #1)
// ****                         <<      SETUP HEADER    >>  <<CMD_PREFIX> <ADDR_POINT><TRANSFER_SIZE>> <<CMD_PREFIX> <ADDR_POINT><TRANSFER_SIZE>>
// **** Read host ram  string ( 80 FF FF 00 00 00 00 00 00   52 65 61 64    00 01 00        04          52 65 61 64    00 01 00        04        ) Both copies must match for
// **** The last 16 characters RX_Buffer string             <<          Copy #1 of command          >> <<          Copy #2 of command          >>  the command to be accepted.
// ****
// ****                                                                        RX_Buffer #7,6,5,4= 32'h 52 65 61 64 = CMD_READ_BYTES
// ****                                                                        RX_Buffer #3,2,1=   24'h 00 01 00    = From Address 24'h000100
// ****                                                                        RX_Buffer #0 =       8'h 04          = Transfer 8'h04 + 1 = 5 bytes.
// ****
// ****                                                                        The RS232_Debugger will then transmit 5 bytes read from host ram port.
// **** Example #2: CMD_READ_BURST
// ****                         <<      SETUP HEADER    >>  <<CMD_PREFIX> <ADDR_POINT><TRANSFER_SIZE>> <<CMD_PREFIX> <ADDR_POINT><TRANSFER_SIZE>>
// **** Read host ram  string ( 80 FF FF 00 00 00 00 00 00   52 65 61 50    00 80 00        0F          52 65 61 50    00 80 00        0F        )
// **** The last 16 characters RX_Buffer string             <<          Copy #1 of command          >> <<          Copy #2 of command          >>
// ****
// ****                                                                        RX_Buffer #7,6,5,4= 32'h 52 65 61 50 = CMD_READ_BURST
// ****                                                                        RX_Buffer #3,2,1=   24'h 00 80 00    = From Address 24'h008000
// ****                                                                        RX_Buffer #0 =       8'h 0F          = Transfer (8'h0F + 1) *256 = 4096 bytes.
// ****
// ****                                                                        The RS232_Debugger will then transmit 4096 bytes read from host ram port.
// ****
// **** Example #3: CMD_WRITE_BYTES (See figure #2)
// ****                         <<      SETUP HEADER    >>  <<CMD_PREFIX> <ADDR_POINT><TRANSFER_SIZE>> <<CMD_PREFIX> <ADDR_POINT><TRANSFER_SIZE>>
// **** Read host ram  string ( 80 FF FF 00 00 00 00 00 00   57 72 69 74    00 01 00        04          57 72 69 74    00 01 00        04        )
// **** The last 16 characters RX_Buffer string             <<          Copy #1 of command          >> <<          Copy #2 of command          >>
// ****
// ****                                                                        RX_Buffer #7,6,5,4= 32'h 57 72 69 74 = CMD_WRITE_BYTES
// ****                                                                        RX_Buffer #3,2,1=   24'h 00 01 00    = To Address 24'h000100
// ****                                                                        RX_Buffer #0 =       8'h 04          = Transfer 8'h7F + 1 = 5 bytes.
// ****
// ****                                                                        The RS232_Debugger will now expect to receive 5 bytes which will be written
// ****                                                                        into the host ram.  The 5 received characters will be echoed back as verification.
// ****                                                                        If there is a pause or delay for more than 0.1 seconds, write command halts/aborts.
// ****
// **** Example #4: CMD_SET_PORTS (See figure #3)
// ****                         <<      SETUP HEADER    >>  <<CMD_PREFIX> <Out0><Out1><Out2><Out3>> <<CMD_PREFIX> <Out0><Out1><Out2><Out3>>
// **** Read host ram  string ( 80 FF FF 00 00 00 00 00 00   53 65 74 50    AA    BB    CC    DD     53 65 74 50    AA    BB    CC    DD    )
// **** The last 16 characters RX_Buffer string             <<       Copy #1 of command          >> <<          Copy #2 of command       >>
// ****
// ****                                                                        RX_Buffer #7,6,5,4= 32'h 53 65 74 50 = CMD_SET_PORTS
// ****                                                                        RX_Buffer #3      =  8'h AA          = Output port Out0[7:0] will be set to 8'hAA
// ****                                                                        RX_Buffer #2      =  8'h BB          = Output port Out1[7:0] will be set to 8'hBB
// ****                                                                        RX_Buffer #1      =  8'h CC          = Output port Out2[7:0] will be set to 8'hCC
// ****                                                                        RX_Buffer #0      =  8'h DD          = Output port Out3[7:0] will be set to 8'hDD
// ****
// ****                                                                        The RS232_Debugger will then transmit back the values of:
// ****                                                                        Ports In0[7:0], In1[7:0], In2[7:0], In3[7:0], then Parameter 'ADDR_SIZE[7:0]'.
// ****
// ****
// *****************************************************************************************************************************************************************************


wire [31:0]      CMD_READ_BYTES, CMD_READ_BURST, CMD_WRITE_BYTES, CMD_WRITE_BURST, CMD_RESET, CMD_SET_PORTS;  // Set wire labels for all the command strings.
reg  [15*8+7:0]  RX_buffer;               // This 16 word * 8 bit character register will take in the RS232 data as an 8 bit word pipe, 16 characters long.
wire [31:0]      CMD_PREFIX ;             // Define a 32 bit wire bus in the RX_buffer which contains the command prefix and CMD_SUFFIX
wire [23:0]      CMD_ADDRESS_POINTER ;    // Define a 24 bit wire bus for the 'CMD_ADDRESS_POINTER'
wire [7:0]       CMD_TRANSFER_SIZE ;      // Define an 8 bit wire bus for the 'CMD_TRANSFER_SIZE'

reg    [3:0]    RXD_00_cnt; // This register will count the consecutive number of bytes = 8'h00 ahead of the command.  It will reset to 0 if any other byte value is received.
reg    [3:0]    RXD_FF_cnt; // This register will count the number of bytes = 8'hFF ahead of the command.  It will reset to 0 if any other byte value other than 8'h00 is received.

// Assign values to all the command wires
wire       CMD_HEADER, CMD_VERIFY;
assign     CMD_HEADER          = ( RXD_FF_cnt==4'h2 && RXD_00_cnt==4'h6 );  // Two consecutive 8'hFF and then 6 consecutive 8'h00 must be transmitted
// as a header before a command, otherwise, all potential received commands will be ignored.

assign     CMD_VERIFY          = ( RX_buffer[15*8+7:8*8] == RX_buffer[7*8+7:0*8] ); // To verify authenticate an incoming command, the 2 consecutive identical copies
    // of the 8 byte command must match
 
assign     CMD_PREFIX          = RX_buffer[7*8+7:4*8] ;  // The point in the receive buffer is where the 4 character command is located
assign     CMD_READ_BYTES      = 32'h52656164 ;          // Read host ram and transmit to RS232, from 1 through 256 bytes.
assign     CMD_READ_BURST      = 32'h52656150 ;          // Page read host ram and transmit to RS232, from 256 through 65536 bytes.
assign     CMD_WRITE_BYTES     = 32'h57726974 ;          // Read RS232 data and write into host ram, from 1 through 256 bytes.
assign     CMD_WRITE_BURST     = 32'h57726950 ;          // Page Read RS232 data and write into host ram, from 256 through 65536 bytes.
assign     CMD_RESET           = 32'h52657365 ;          // Cycle the reset output command prefix
assign     CMD_SET_PORTS       = 32'h53657450 ;          // Set the general purpose output ports and read general purpose input ports + then transmit 'ADDR_SIZE' parameter.
assign     CMD_ADDRESS_POINTER = RX_buffer[3*8+7:1*8] ;  // Point to the 3 8 bit words in the command's register which contains the 24 bit starting read and write address
assign     CMD_TRANSFER_SIZE   = RX_buffer[0*8+7:0*8] ;  // Point to the 8 bit word in the command's register which contains the number of bytes+1 to transfer
// Or in the case of a R/W_BURST, set the byte transfer quantity to (CMD_TRANSFER_SIZE+1) * 256

reg        [16:0]   byte_count;                          // This register will be used to count the number of bytes which were requested by 'CMD_TRANSFER_SIZE' to be received or transmitted through the RS232 transceiver.
reg        [23:0]   host_addr_reg ;                      // This register will hold and count the host read and write address.
reg        [7:0]    host_rdata_reg ; // when the 'host_rd_rdy' input goes high, this register will latch the 'host_rdata' input port.

assign     host_addr[ADDR_SIZE-1:0]  = host_addr_reg[ADDR_SIZE-1:0];  // Assign the host register output port the the host_addr_reg register counter


reg        [1:0]  Function ;         // This register holds which of the 4 possible program functions the RS232_Debugger is running.
wire       [1:0]  FUNC_WAIT, FUNC_READ, FUNC_WRITE, FUNC_SET_PORTS ;
assign     FUNC_WAIT       = 2'h0 ;  // This function state waits for incoming commands.  When a valid command is received, it will setup the next function state.
assign     FUNC_READ       = 2'h1 ;  // This function state will read 'byte_count+1' bytes of host ram and transmit the contents to the RS232 port's TXD.
assign     FUNC_WRITE      = 2'h2 ;  // This function state will read 'byte_count+1' bytes from the RS232 port's RXD and send the data to the host ram + send a copy back to the RS232 port's TXD.
assign     FUNC_SET_PORTS  = 2'h3 ;  // This function state will send the the 4 in#[7:0] ports' values and then the 'ADDR_SIZE' parameter through the RS232 transceiver.


reg        [3:0]      rst_clk;  // This will be used as a counter to pulse out the 'cmd_rst' output pin for 8 clock cycles when commanded to by the RS232.
reg        [3:0]      tx_cyc;   // This counter will be used to slow down and sequence actions when transmitting bytes out through the RS232 transceiver.



// *************************************************************************
// *** SYNC_RS232_UART.v setup.  Read the SYNC_RS232_UART.v file to see how
// *** I engineered this module and how I got the transmitter to function
// *** synchronously with a PC's serial incoming RXD transmission.
// ***
// *** Timing diagrams on EEVBlog forum here:
// ***
// *************************************************************************

wire         uart_tx_full;
wire         rxd_rdy;
reg  [4:0]   ena_rxd_dly;  //  This register will receive the UART's 'rxd_rdy' pulse and serial shift that pulse along it's 5 bits.
wire [7:0]   uart_rbyte;
reg          uart_tx;
reg  [7:0]   uart_tbyte;   // This reg will hold the byte which is about to be transmitted

sync_rs232_uart  rs232_io ( .clk(clk),
.rxd(rxd),             // Goes to RXD Input Pin
.txd(txd),             // Goes to TXD output pin

.rx_data(uart_rbyte),  // Received data byte
.rx_rdy(rxd_rdy),      // 1 clock pulse high when the received data bit is ready

.ena_tx(uart_tx),      // Pulsed high for 1 clock when tx_data byte is ready to be sent
.tx_data(uart_tbyte),  // The byte which will be transmitted
.tx_busy(uart_tx_full) ); // High when the 1 word FIFO in the UART's transmit buffer is full
defparam
rs232_io.CLK_IN_HZ    = CLK_IN_HZ,
rs232_io.BAUD_RATE    = BAUD_RATE;


always @ (posedge clk) begin

// ******************************************************************
// ****** Generate a generic 1 KHz timer tick pulse.
// ******************************************************************
if ( tick_1KHz_counter <= 18'h1 ) begin
tick_1KHz_counter <= CLK_1KHz_PERIOD[17:0];
tick_1KHz         <= 1'b1 ;
end else begin
tick_1KHz_counter <= tick_1KHz_counter - 1'b1 ;
tick_1KHz         <= 1'b0 ;
end

// ******************************************************************
// ****** Generate a status activity RXD and TXD led driver output.
// ****** This routine keeps the LED outputs on long enough to
// ****** visibly see as the data bursts are too short to be seen.
// ******************************************************************
if (uart_tx_full) begin
led_txd_timeout <= LED_HOLD_TIME ;
LED_txd         <= 1'b1 ;
end else if ( led_txd_timeout!=5'h0 && tick_1KHz ) led_txd_timeout <= led_txd_timeout - 1'b1 ;
else if     ( led_txd_timeout==5'h0 )              LED_txd         <= 1'b0 ;

if (rxd_rdy) begin
led_rxd_timeout <= LED_HOLD_TIME ;
LED_rxd         <= 1'b1 ;
end else if ( led_rxd_timeout!=5'h0 && tick_1KHz ) led_rxd_timeout <= led_rxd_timeout - 1'b1 ;
else if     ( led_rxd_timeout==5'h0 )              LED_rxd         <= 1'b0 ;

// ******************************************************************
// ******************************************************************

cmd_rst <= ~rst_clk[3] ;                    // Register delay and invert latch bit 4 of the reset counter.
if (~rst_clk[3]) begin                      // *** Generate an 8 clock wide reset pulse
rst_clk <= rst_clk + 1'b1 ;   // Count until bit 3 on the counter goes high.
end else begin

if (cmd_rst) begin                          // Last single 1 shot reset from the reset output signal 'cmd_rst'.
host_addr_reg        <= 24'h0 ;
host_wr_ena          <= 1'b0 ;      // make sure we aren't writing ram.
host_rd_req          <= 1'b0 ;      // make sure we aren't requesting a read from memory
ena_rxd_dly[4:0]     <= 5'h0 ;      // clear out any possible RS232 transceiver rx_rdy
RX_buffer[15*8+7:0]  <= 128'h0 ;    // clear out the entire 16 word by 8 bit character input command buffer.
Function             <= FUNC_WAIT ; // set the program state to the 'wait for incoming command' function.
uart_tx      <= 1'b0 ;      // make sure no transmit character command is being sent to the RS232 transceiver.
end else begin


// ******************************************************************************************
// *** setup a sequential accessible delayed pipe of the RS232 transceiver's 'rx_rdy' signal.
// ******************************************************************************************
ena_rxd_dly[0]    <=  rxd_rdy ;
ena_rxd_dly[4:1]  <=  ena_rxd_dly[3:0] ;


// ******************************************************************************************************************
// *** setup case statement for the 4 possible functions, FUNC_WAIT, FUNC_READ, FUNC_WRITE, FUNC_SET_PORTS
// ******************************************************************************************************************
case (Function)


// ************************************************************************************************************************************************************************************
// *** Beginning Function FUNC_WAIT.  This function state waits for incoming commands.  When a valid command is received, it will setup the next function state.
// ************************************************************************************************************************************************************************************
FUNC_WAIT : begin

host_rd_req <= 1'b0;  // force off any ram transactions.
host_wr_ena <= 1'b0;

if (ena_rxd_dly[3]) begin  // Note we are using the ena_rxd_dly[3] deliberately since if the 'FUNC_WRITE' is called, it uses a pre-setup time by triggering sequenced actions on earlier ena_rxd_dly[#]s

RX_buffer[15*8+7:0]    <= { RX_buffer[14*8+7:0] , uart_rbyte } ;  // This will shift 1 byte at a time through the 16 character command buffer

if      ( RX_buffer[15*8+7:15*8]==8'h00 ) RXD_00_cnt <= RXD_00_cnt + (RXD_00_cnt!=3'h7); // test the last byte in the 16 character buffer and
else RXD_00_cnt <= 3'h0 ;                           // count the number of bytes which are sequentially = 8'h00.

if      ( RX_buffer[15*8+7:15*8]==8'hFF ) RXD_FF_cnt <= RXD_FF_cnt + (RXD_FF_cnt!=3'h7); // test the last byte in the 16 character buffer and
else if ( RX_buffer[15*8+7:15*8]!=8'h00 ) RXD_FF_cnt <= 3'h0 ;                           // count the number of bytes which are sequentially = 8'hFF

end

if ( CMD_HEADER &&  CMD_VERIFY  ) begin  // Test to see if the command prefix string meets the 2 bytes of 8'hFF,
     // then 6 bytes of 8'h00, and then 2 command string of 8 bytes each which are identical

// ********************************************************************************************************
// *** setup case statement which will perform actions based on the 6 possible incoming CMD_PREFIX :
// ***       CMD_READ_BYTES, CMD_READ_BURST, CMD_WRITE_BYTES, CMD_WRITE_BURST, CMD_RESET, CMD_SET_PORTS
// ********************************************************************************************************
case (CMD_PREFIX)


// ********************************************************************************************************
// *** CMD_PREFIX case CMD_READ_BYTES. Read host ram and transmit to RS232, from 1 through 256 bytes.
// ********************************************************************************************************
CMD_READ_BYTES  : begin
byte_count[16:8]    <= 9'h0;
byte_count[7:0]     <= CMD_TRANSFER_SIZE ;
host_addr_reg[23:0] <= CMD_ADDRESS_POINTER ;
Function            <= FUNC_READ ;
tx_cyc     <= 4'h0;
RX_buffer[15*8+7:0] <= 128'h0;
timeout_cnt         <= DEBUG_WDT_TIME ;  // set the receive abort timeout counter
end  // end of case CMD_READ_BYTES

// ********************************************************************************************************
// *** CMD_PREFIX case CMD_WRITE_BYTES. Read RS232 data and write into host ram, from 1 through 256 bytes.
// ********************************************************************************************************
CMD_WRITE_BYTES : begin
byte_count[16:8]    <= 9'h0;
byte_count[7:0]     <= CMD_TRANSFER_SIZE ;
host_addr_reg[23:0] <= CMD_ADDRESS_POINTER ;
Function            <= FUNC_WRITE ;
RX_buffer[15*8+7:0] <= 128'h0;
timeout_cnt         <= DEBUG_WDT_TIME ;  // set the receive abort timeout counter
end  // end of case CMD_WRITE_BYTES

// ********************************************************************************************************
// *** CMD_PREFIX case CMD_READ_BURST. Page read host ram and transmit to RS232, from 256 through 65536 bytes.
// ********************************************************************************************************
CMD_READ_BURST  : begin
byte_count[16]      <= 1'b0;
byte_count[15:8]    <= CMD_TRANSFER_SIZE ;
byte_count[7:0]     <= 8'hFF ;
host_addr_reg[23:0] <= CMD_ADDRESS_POINTER ;
Function            <= FUNC_READ ;
tx_cyc     <= 4'h0;
RX_buffer[15*8+7:0] <= 128'h0;
timeout_cnt         <= DEBUG_WDT_TIME ;  // set the receive abort timeout counter
end  // end of case CMD_READ_BURST

// ********************************************************************************************************
// *** CMD_PREFIX case CMD_WRITE_BURST. Page Read RS232 data and write into host ram, from 256 through 65536 bytes.
// ********************************************************************************************************
CMD_WRITE_BURST : begin
byte_count[16]      <= 1'b0;
byte_count[15:8]    <= CMD_TRANSFER_SIZE ;
byte_count[7:0]     <= 8'hFF ;
host_addr_reg[23:0] <= CMD_ADDRESS_POINTER ;
Function            <= FUNC_WRITE ;
RX_buffer[15*8+7:0] <= 128'h0;
timeout_cnt         <= DEBUG_WDT_TIME ;   // set the receive abort timeout counter
end  // end of case CMD_WRITE_BURST

// ********************************************************************************************************
// *** CMD_PREFIX case CMD_RESET.  Trigger the com_rst output.
// ********************************************************************************************************
CMD_RESET       : begin
rst_clk             <= 4'h0; // Clearing the rst_clk which will begin the 8 clock reset period
Function            <= FUNC_WAIT ;
RX_buffer[15*8+7:0] <= 128'h0;
end  // end of case CMD_RESET

// *********************************************************************************************************************************************
// *** CMD_PREFIX case CMD_SET_PORTS.  Set the general purpose output ports and read general purpose input ports + the transmit 'ADDR_SIZE' parameter.
// *********************************************************************************************************************************************
CMD_SET_PORTS   : begin
out0 <= RX_buffer[3*8+7:3*8] ;  // The 4 out# ports were sent withing the RX_buffer command's suffix.
out1 <= RX_buffer[2*8+7:2*8] ;  // Usually, the address and data transfer size is stored here.
out2 <= RX_buffer[1*8+7:1*8] ;
out3 <= RX_buffer[0*8+7:0*8] ;
// *** Parallel register all 4 peripheral input ports.
in_reg0 <= in0 ;
in_reg1 <= in1 ;
in_reg2 <= in2 ;
in_reg3 <= in3 ;

byte_count[16]      <= 1'b0 ;
byte_count[15:0]    <= 16'h4 ;  // There are 5 bytes to be sent, the 4 in_reg#[7:0] registers and the 'ADDR_SIZE' parameter.
Function            <= FUNC_SET_PORTS ;
tx_cyc     <= 4'h0 ;
RX_buffer[15*8+7:0] <= 128'h0 ;
timeout_cnt         <= DEBUG_WDT_TIME ;  // set the receive abort timeout counter
end  // end of case CMD_SET_PORTS

endcase
// ********************************************************************************************************
// *** End of case (CMD_PREFIX) for the 6 possible commands:
// ***       CMD_READ_BYTES, CMD_READ_BURST, CMD_WRITE_BYTES, CMD_WRITE_BURST, CMD_RESET, CMD_SET_PORTS
// ********************************************************************************************************


end // End of Command verification if ( CMD_HEADER &&  CMD_VERIFY  )


end
// ************************************************************************************************************************************************************************************
// *** Ending case Function FUNC_WAIT.
// ************************************************************************************************************************************************************************************



// ************************************************************************************************************************************************************************************
// *** Beginning Function FUNC_READ.  This function will read 'byte_count+1' bytes of host ram and transmit the contents to the RS232 port's TXD.
// ************************************************************************************************************************************************************************************
FUNC_READ : begin

if (~byte_count[16] && timeout_cnt!=5'h0 ) begin  //  keep on transmitting until byte counter elapses by counting below 0.

if ( uart_tx        ) timeout_cnt <= DEBUG_WDT_TIME ;      // If a character is transmitted, reset the watch dog timeout counter
else if ( tick_1KHz      ) timeout_cnt <= timeout_cnt - 1'b1 ;  // Otherwise, countdown the watch dog timer once at every 1KHz tick.

if ( host_rd_rdy ) host_rdata_reg <= host_rdata ;  // latch the host_rdata input if the host_read_rdy is set.

if (~(uart_tx_full && tx_cyc==4'h0) && ~(~host_rd_rdy && tx_cyc==4'h1) ) begin  // only run the tx_cyc counter when the UART RS232 transmitter
// is ready to transmit the next character and the host_rd_ready
// has gone high after tx_cyc 0 when the host_re_req pulse has been sent.
tx_cyc <= tx_cyc + 1'b1; // increment this cycle counter

if (tx_cyc==4'd0)  host_rd_req   <= 1'b1; // pulse the host_rd_req with the current valid address
else               host_rd_req   <= 1'b0;

if (tx_cyc==4'd13) uart_tbyte    <= host_rdata_reg ; // expect the returned data ready within 12 clock cycles, and latch that data into the RS232 transmitter data input register

if (tx_cyc==4'd14) uart_tx       <= 1'b1; // Trigger the RS232 transmit data enable
else               uart_tx       <= 1'b0;

if (tx_cyc==4'd15) host_addr_reg <= host_addr_reg + 1'b1;  // increment the host memory address
if (tx_cyc==4'd15) byte_count    <= byte_count - 1'b1;     // decrement the byte transfer size counter
end

end else begin                 // byte_count cycles has completed or timeout WDT has elapsed,
Function     <= FUNC_WAIT; // leave FUNC_READ and switch back to FUNC_WAIT for the next command.
uart_tx      <= 1'b0;
host_rd_req  <= 1'b0;
end

end //  End of case FUNC_READ
// ************************************************************************************************************************************************************************************
// *** Ending of Function FUNC_READ.
// ************************************************************************************************************************************************************************************



// ************************************************************************************************************************************************************************************
// *** Beginning Function FUNC_WRITE.  This function will read 'byte_count+1' bytes from the RS232 port's RXD and send the data to the host ram + send a copy back to the RS232 port's TXD.
// ************************************************************************************************************************************************************************************
FUNC_WRITE : begin

if (~byte_count[16] && timeout_cnt!=5'h0 ) begin  //  keep on reading from RS232 until byte counter elapses, or the timeout counter has reached it's end

if ( ena_rxd_dly[0] ) timeout_cnt <= DEBUG_WDT_TIME ;      // If a character is received, reset the watch dog timeout counter
else if ( tick_1KHz      ) timeout_cnt <= timeout_cnt - 1'b1 ;  // Otherwise, countdown the watch dog timer once at every 1KHz tick.


if (ena_rxd_dly[0]) host_wdata     <= uart_rbyte ;              // copy RS232 received data byte to the host memory data output port
if (ena_rxd_dly[0]) uart_tbyte     <= uart_rbyte ;              // copy RS232 received data byte to the RS232 transmitter output data port

if (ena_rxd_dly[1]) host_wr_ena     <= 1'b1;                    // Trigger the host memory write enable
else                host_wr_ena     <= 1'b0;

if (ena_rxd_dly[1]) uart_tx         <= 1'b1; // echo back received character by triggering the RS232 transmit data enable
else                uart_tx         <= 1'b0;

if (ena_rxd_dly[3]) host_addr_reg   <= host_addr_reg + 1'b1 ;   // increment the host memory address
if (ena_rxd_dly[3]) byte_count      <= byte_count - 1'b1 ;      // decrement the byte transfer size counter

end else begin                           // byte_count cycles has completed or timeout WDT has elapsed,
Function        <= FUNC_WAIT ;   // leave FUNC_WRITE and switch back to FUNC_WAIT for the next command.
host_wr_ena     <= 1'b0 ;
byte_count[16]  <= 1'b1 ;
end

end // End of case FUNC_WRITE
// ************************************************************************************************************************************************************************************
// *** Ending of Function FUNC_WRITE.
// ************************************************************************************************************************************************************************************



// ************************************************************************************************************************************************************************************
// *** Beginning of Function FUNC_SET_PORTS.  This function will send the 'ADDR_SIZE' parameter + the 4 in#[7:0] ports' data through the RS232's port's TXD.
// ************************************************************************************************************************************************************************************
FUNC_SET_PORTS : begin

if (~byte_count[16]) begin  //  keep on transmitting until byte counter elapses

if (~(uart_tx_full && tx_cyc==4'h0)) begin

tx_cyc <= tx_cyc + 1'b1 ;

if (tx_cyc==4'd13) begin
case (byte_count[2:0])              // Set the RS232 transmitter's data port with the correct data during the correct byte number
3'h4 : uart_tbyte <= in_reg0 ;
3'h3 : uart_tbyte <= in_reg1 ;
3'h2 : uart_tbyte <= in_reg2 ;
3'h1 : uart_tbyte <= in_reg3 ;
3'h0 : uart_tbyte <= ADDR_SIZE[7:0] ;
endcase // case (byte_count[2:0])
end

if (tx_cyc==4'd14) uart_tx     <= 1'b1 ;   // Trigger the RS232 transmit data enable
else               uart_tx     <= 1'b0 ;

if (tx_cyc==4'd15) byte_count  <= byte_count - 1'b1 ; // decrement the byte transfer size counter

end

end else begin                   // byte_count cycles has completed, leave FUNC_SET_PORTS and switch back to FUNC_WAIT for the next command.
Function      <= FUNC_WAIT ;
uart_tx       <= 1'b0 ;
host_rd_req   <= 1'b0 ;
end

end // End of case FUNC_WRITE_PORTS
// ************************************************************************************************************************************************************************************
// *** Ending of Function FUNC_SET_PORTS.
// ************************************************************************************************************************************************************************************



endcase // Case (Function)
// ******************************************************************************************************************
// *** End of case statement for the 4 possible functions, FUNC_WAIT, FUNC_READ, FUNC_WRITE, FUNC_SET_PORTS
// ******************************************************************************************************************


   end // ~rst
  end // ~soft_rst
 end // always @posedge
endmodule

« Last Edit: July 16, 2020, 02:03:16 am by BrianHG »
 

Offline BrianHGTopic starter

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For Quartus users, here are the project files with the simulation test benches setup using Quartus' .vwf (Vector Waveform) files which contain the test stimulus source waveforms.

Though QuartusIIv9.1 was used, I test opened these projects in Quartus Prime and upon opening them, all you need to do is choose a newer FPGA to switch the project to.  The .vwf files will simulate after an initial compile as these projects have all their .rpt and compilation folders erased so they may fit here on EEVblog's forum.
« Last Edit: November 26, 2019, 02:51:20 am by BrianHG »
 

Offline BrianHGTopic starter

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For users who have an FTDI USB-RS232 converter cable or FT232 - TTL RS232 converter and wish to get over 50 frames per second refresh when scrolling and viewing memory through the RS232_Debugger, these settings in Window's 'Device Manager' vastly accelerate FTDI USB driver's response.

See photo:

879002-0
« Last Edit: November 26, 2019, 02:13:23 am by BrianHG »
 
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Offline lawrence11

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Interresting interresting.

Can you make something with a tb, and many modules.

And will you choose many test bench or a single huge test bench?

How will you set yourself up to give flexibility to your starting conditions.

All of that good stuff, maybe some clock crossing from external sources.

Something to force to use the "double buffering technique".


 

Offline BrianHGTopic starter

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Interresting interresting.

Can you make something with a tb, and many modules.

Yes, as you can see, in both simulations, I actually using part of my RS232 UART, it's transmitter on it's own as a 'MASTER' while the entire UART module is being used again as a slave or as part of the 'debugger' module.

Quote
And will you choose many test bench or a single huge test bench?
The 2 operating together makes a larger test bench than just analyzing a single Verilog core.  In a way, they are also self generating part of their intermediary signals.  I personally make small test benches to test each core, and larger one, sometimes entire designs especially when I do graphics where I need to make sure an individual pixel arrives exactly on a specific clock, and to get that far, I need a bunch of Verilog core modules working together.  Under these circumstances, this must be done since a line or row of missing pixels at the edge of a 1080p picture being generated on a monitor may easily be missed.  These setups and the coding behind them can take months if you are doing everything from scratch and the first time around.

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How will you set yourself up to give flexibility to your starting conditions.

If you mean in my test-bench, I literally drew the starting waveforms in Quartus' vector waveform editor.  That utility is like a GUI paint software for signals.  However, it is time consuming and newer versions of Quartus Prime removed some nice features like 'cut' & 'paste' sections of the waveform. 

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All of that good stuff, maybe some clock crossing from external sources.

Clock domain switching is a complicated issue.  However, if your main FPGA clock operates at least twice as fast as the data you are capturing, like in my example UART which works out the initial falling edge of the RXD, (see in code how the 'rx_trigger' is created). The same trick may be used to trap data from any other asynchronous Verilog module, generating the flag to tell your high speed system clock logic that the data is ready to take a single snapshot of the results.  If you slower clock domain is even slower than 1/2 clock, delaying that 'rx_trigger' example by 1 additional system clock will guarantee a proper read no matter the internal FPGA delays unless you are running outside your compiler's timing analyzer's specified FMAX.

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Something to force to use the "double buffering technique".

You should only require double buffering if your 2 clock domains have slightly different frequencies, like somewhere in-between half and double.  The only other reason is if you are filling a buffer of data in small burst to be fed out and FPGA's do have 2 clock domain FIFO functions for these circumstances.
« Last Edit: November 26, 2019, 09:34:25 pm by BrianHG »
 

Offline BrianHGTopic starter

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I've just updated the RS232_Debugger_HEX-editor with the ability to save 16bit wide Quartus .mif files.

Use the regular 'm' to save a regular 8 bit .mif file.

Use a shift 'M' to save a 16 bit .mif file, in little-edian.  Note that converting an 8 bit to 16 bit in Quartus' .mif editor only does big-edian conversion.  So, this is why I had to add a save 16bit .mif in my hex editor.

Though it is a mess, I've also included the basic source file.  If I ever get the time, I'll re-do the hex editor with 'sane' programming.
« Last Edit: December 30, 2019, 08:47:04 am by BrianHG »
 

Offline BrianHGTopic starter

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New addition to the 'rs232_DEBUGGER.v', version 1.1.  A new parameter 'READ_REQ_1CLK' which will make the 'host_rd_req' output pulse for only a single clock instead of staying high until the 'host_rd_rdy' has been received.

See simulation:
1024380-0

'rs232_DEBUGGER.v.txt' ver. 1.1 attached below.

There are no changes to the 'SYNC_RS232_UART.v' located at the top of this thread.
« Last Edit: July 16, 2020, 02:06:32 am by BrianHG »
 

Offline BrianHGTopic starter

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Bug fix, RS232_Debugger_Hex-Editor_V1.2.zip, August 13, 2020.

A minor bug in the ASCII display window where any data which is changed to a 0xFF due to memory operation or pressing the page-up / page-down key might retain old cached character has been fixed.

This was only an on-screen ASCII display issue, the data and the HEX view always showed the correct data.
 

Offline BrianHGTopic starter

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Just created version 1.2.

This new patch just moves the parameters to the top of the module description and this code has been tested compatible with ModelSim.
 
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Offline BrianHGTopic starter

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GitHub repository added.

Now includes the .bas source code for the PC HexEditor host, IE, it can now be compiled for Linux with Linux Free Basic.

https://github.com/BrianHGinc/Verilog-RS232-Synch-UART-RS232-Debugger-and-PC-host-RS232-Hex-editor

 

Offline BrianHGTopic starter

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Version 1.3, Jan 14, 2022.

Now has an 'ENDIAN' setting which now shows you the correct 16bit values for 16bit ints.

When editing cells, this also allows the use of the +/- keys to increment/decrement 16bit values with the new ENDIAN settings being taken into account.

Also has a new Quartus save 32bit .mif files.

Also, changing the ENDIAN before saving a 16bit or 32bit Quartus .mif file will also swap they byte order making it easy to render wide .mif files with reverse ENIANess.
« Last Edit: January 15, 2022, 12:42:44 am by BrianHG »
 


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