ftx_prog.c

/*
 * This is a Linux command-line alternative to the FTDI MProg/FTProg
 * utilities for FTDI's FT-X series.
 *
 * Modified for the FT-X series by Richard Meadows 2012.
 *
 * Based upon:
 * ft232r_prog.c by Mark Lord.  Copyright 2010-2012.
 *
 * 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; either version 2, or (at your option)
 * any later version.
 *
 * 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; see the file LICENSE.txt.  If not, write to
 * the Free Software Foundation, 675 Mass Ave, Cambridge, MA 02139, USA.
 */

#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include <errno.h>
#include <sys/types.h>
#include <sys/stat.h>
#include <fcntl.h>
#include <ftdi.h>
#include <stdbool.h>
#include <unistd.h>

#define MYVERSION	"0.4"

#define CBUS_COUNT	7

static struct ftdi_context ftdi;
static int verbose = 0;
static int erase_eeprom = 0;
static int ignore_crc_error = 0;
static bool use_8b_strings = false;
static const char *save_path = NULL, *restore_path = NULL;

/* ------------ Bit Definitions for EEPROM Decoding ------------ */

enum cbus_mode {
  cbus_tristate	=  0,
  cbus_rxled	=  1,
  cbus_txled	=  2,
  cbus_txrxled	=  3,
  cbus_pwren	=  4,
  cbus_sleep	=  5,
  cbus_drive0	=  6,
  cbus_drive1	=  7,
  cbus_gpio	=  8,
  cbus_txden	=  9,
  cbus_clk24	= 10,
  cbus_clk12	= 11,
  cbus_clk6	= 12,
  cbus_bcd_det	= 13,
  cbus_bcd_det_i	= 14,
  cbus_i2c_txe	= 15,
  cbus_i2c_rxf	= 16,
  cbus_vbus_sense	= 17,
  cbus_bitbang_wr	= 18,
  cbus_bitbang_rd	= 19,
  cbus_timestamp	= 20,
  cbus_keep_awake	= 21,
  _cbus_mode_end
};
enum misc_config {
  bcd_enable		= 0x01,
  force_power_enable	= 0x02,
  deactivate_sleep	= 0x04,
  rs485_echo_suppress	= 0x08,
  ext_osc			= 0x10,
  ext_osc_feedback_en	= 0x20,
  vbus_sense_alloc	= 0x40,
  load_vcp		= 0x80,
};
enum power_config {
  remote_wakeup		= 0x20,
  self_powered		= 0x40,
};
enum dbus_cbus_config {
  dbus_drive_strength	= 0x03,
  dbus_slow_slew		= 0x04,
  dbus_schmitt		= 0x08,
  cbus_drive_strength	= 0x30,
  cbus_slow_slew		= 0x40,
  cbus_schmitt		= 0x80,
};
enum peripheral_config {
  suspend_pull_down	= 0x04,
  serial_number_avail	= 0x08,
  ft1248_cpol		= 0x10,
  ft1248_bord		= 0x20,
  ft1248_flow_control	= 0x40,
  disable_i2c_schmitt	= 0x80,
  invert_txd		= 0x01,
  invert_rxd		= 0x02,
  invert_rts		= 0x04,
  invert_cts		= 0x08,
  invert_dtr		= 0x10,
  invert_dsr		= 0x20,
  invert_dcd		= 0x40,
  invert_ri		= 0x80,
};

/* ------------ Command Line Arguments ------------ */

enum arg_type {
  arg_help,
  arg_dump,
  arg_verbose,
  arg_save,
  arg_restore,
  arg_8b_strings,
  arg_cbus,
  arg_manufacturer,
  arg_product,
  arg_old_serno,
  arg_new_serno,
  arg_max_bus_power,
  arg_suspend_pull_down,
  arg_load_vcp,
  arg_remote_wakeup,
  arg_ft1248_cpol,
  arg_ft1248_bord,
  arg_ft1248_flow_control,
  arg_i2c_schmitt,
  arg_i2c_slave_address,
  arg_i2c_device_id,
  arg_rs485_echo_suppression,

  arg_old_vid,
  arg_old_pid,
  arg_new_vid,
  arg_new_pid,
  arg_invert,
  arg_self_powered,
  arg_ignore_crc_error,
  arg_erase_eeprom,
  arg_dbus_config,
  arg_cbus_config
};

struct args_required_t
{
  enum arg_type t;
  int number;
};

const struct args_required_t req_info[] =
{
  {arg_help, 0},
  {arg_dump, 0},
  {arg_verbose, 0},
  {arg_save, 1},
  {arg_restore, 1},
  {arg_8b_strings, 0},
  {arg_cbus, 2},
  {arg_manufacturer, 1},
  {arg_product, 1},
  {arg_old_serno, 1},
  {arg_new_serno, 1},
  {arg_max_bus_power, 1},
  {arg_suspend_pull_down, 1},
  {arg_load_vcp, 1},
  {arg_remote_wakeup, 1},
  {arg_ft1248_cpol, 1},
  {arg_ft1248_bord, 1},
  {arg_ft1248_flow_control, 1},
  {arg_i2c_schmitt, 1},
  {arg_i2c_slave_address, 1},
  {arg_i2c_device_id, 1},
  {arg_rs485_echo_suppression, 1},

  {arg_old_vid, 1},
  {arg_old_pid, 1},
  {arg_new_vid, 1},
  {arg_new_pid, 1},
  {arg_invert, 1},
  {arg_self_powered, 1},
  {arg_ignore_crc_error, 0},
  {arg_erase_eeprom, 0},
  {arg_cbus_config,1},
};



/* ------------ Strings for argument parsing ------------ */

static const char* arg_type_strings[] = {
  "--help",
  "--dump",
  "--verbose",
  "--save",
  "--restore",
  "--8bit-strings",
  "--cbus",
  "--manufacturer",
  "--product",
  "--old-serial-number",
  "--new-serial-number",
  "--max-bus-power",
  "--suspend-pull-down",
  "--load-vcp",
  "--remote-wakeup",
  "--ft1248-cpol",
  "--ft1248-bord",
  "--ft1248-flow-control",
  "--i2c-schmitt",
  "--i2c-slave-address",
  "--i2c-device-id",
  "--rs485-echo-supp",
  "--old-vid",
  "--old-pid",
  "--new-vid",
  "--new-pid",
  "--invert",
  "--self-powered",
  "--ignore-crc-error",
  "--erase-eeprom",
  "--dbus-config",
  "--cbus-config",
  NULL
};
static const char* rs232_strings[] = {
  "txd",
  "rxd",
  "rts",
  "cts",
  "dtr",
  "dsr",
  "dcd",
  "ri",
  NULL
};
static const char* cbus_strings[] = {
  "0",
  "1",
  "2",
  "3",
  "4",
  "5",
  "6",
  NULL
};
static const char* cbus_mode_strings[] = {
  "Tristate",
  "RxLED",
  "TxLED",
  "TxRxLED",
  "PWREN",
  "SLEEP",
  "Drive_0",
  "Drive_1",
  "GPIO",
  "TXDEN",
  "CLK24MHz",
  "CLK12MHz",
  "CLK6MHz",
  "BCD_Charger",
  "BCD_Charger#",
  "I2C_TXE",
  "I2C_RXF",
  "VBUS_Sense",
  "BitBang_WR",
  "BitBang_RD",
  "Time_Stamp",
  "Keep_Awake",
  NULL
};
static const char *d_cbus_config_strings [] = {
  "4ma",
  "8ma",
  "12ma",
  "16ma",
  "slow_slew",
  "fast_slew",
  "normal",
  "schmitt",
  NULL
};

static const char *arg_type_help[] = {
  "   				    # (show this help text)",
  "				    # (dump eeprom settings to stdout)",
  "				    # (show debug info and raw eeprom contents)",
  "			 <file>     # (save original eeprom contents to file)",
  "			 <file>     # (restore initial eeprom contents from file)",
  "                      # (byte strings)",
  "[cbus]",
  "		 <string>   # (new USB manufacturer string)",
  "			 <string>   # (new USB product name string)",
  "	 <string>   # (current serial number of device to be reprogrammed)",
  "	 <string>   # (new USB serial number string)",
  "		 <number>   # (max bus current in milli-amperes)",
  "	 [on|off]   # (force I/O pins into logic low state on suspend)",
  "		 [on|off]   # (controls if the VCP drivers are loaded)",
  "		 [on|off]   # (allows the interface to be woken up by something other than USB)",
  "		 [high|low] # (set the clock polarity on the FT1248 interface to active high or active low)",
  "		 [msb|lsb]  # (set the bit order on the FT1248 interface to msb first or lsb first)",
  "	 [on|off]   # (flow control for FT1248 interface)",
  "		 [on|off]   # (schmitt trigger on I2C interface)",
  "	 <number>   # (I2C slave address)",
  "		 <number>   # (I2C device ID)",
  "		 [on|off]   # (enable echo supression on the RS485 bus)",
  "			 <number>   # (current vendor id of device to be reprogrammed, eg. 0x0403)",
  "			 <number>   # (current product id of device to be reprogrammed, eg. 0x6001)",
  "			 <number>   # (new/custom vendor id to be programmed)",
  "			 <number>   # (new/custom product id be programmed)",
  "[invert]",
  "		 [on|off]   # (specify if chip is bus-powered or self-powered)",
  "   				    # Ignore CRC errors and continue ",
  "   				    # Erase the EEPROM and exit",
  "dbus_cfg",
  "cbus_cfg",

};

static const char *bool_strings[] = {
  "False",
  "True",
  "false",
  "true",
  "Off",
  "On",
  "off",
  "on",
  "0",
  "1",
  "No",
  "Yes",
  "no",
  "yes",
  "disable",
  "enable",
  "low",
  "high",
  "msb",
  "lsb",
};

struct eeprom_fields {
  /* Misc Config */
  unsigned char bcd_enable;
  unsigned char force_power_enable;
  unsigned char deactivate_sleep;
  unsigned char rs485_echo_suppress;
  unsigned char ext_osc;
  unsigned char ext_osc_feedback_en;
  unsigned char vbus_sense_alloc;
  unsigned char load_vcp;

  /* USB VID/PID */
  unsigned short usb_vid;
  unsigned short usb_pid;

  /* USB Release Number */
  unsigned short usb_release_major;
  unsigned short usb_release_minor;

  /* Max Power and Config */
  unsigned char remote_wakeup;
  unsigned char self_powered;
  unsigned char max_power; /* Units of 2mA */

  /* Device and perhiperal control */
  unsigned char suspend_pull_down;
  unsigned char serial_number_avail;
  unsigned char ft1248_cpol;
  unsigned char ft1248_bord;
  unsigned char ft1248_flow_control;
  unsigned char disable_i2c_schmitt;
  unsigned char invert_txd;
  unsigned char invert_rxd;
  unsigned char invert_rts;
  unsigned char invert_cts;
  unsigned char invert_dtr;
  unsigned char invert_dsr;
  unsigned char invert_dcd;
  unsigned char invert_ri;

  /* DBUS & CBUS Control */
  unsigned char dbus_drive_strength;
  unsigned char dbus_slow_slew;
  unsigned char dbus_schmitt;
  unsigned char cbus_drive_strength;
  unsigned char cbus_slow_slew;
  unsigned char cbus_schmitt;

  /* Manufacturer, Product and Serial Number string */
  char* manufacturer_string;
  char* product_string;
  char* serial_string;

  /* I2C */
  unsigned short i2c_slave_addr;
  unsigned int i2c_device_id;

  /* CBUS */
  enum cbus_mode cbus[CBUS_COUNT];

  /* Other memory areas */
  unsigned char user_mem[92];			/* user memory space */
  unsigned char factory_config[32];	/* factory configuration values */

  /* These are not actually eeprom values; here for convenience */
  unsigned short		old_vid;
  unsigned short		old_pid;
  const char		*old_serno;
};

/* ------------ libftdi helpers ------------ */

static void do_deinit (void)
{
  ftdi_deinit(&ftdi);
}

static void do_close (void)
{
  ftdi_usb_close(&ftdi);
}

/* ------------ Printing ------------ */

/**
 * Prints a hex dump of a block of memory
 */
static void dumpmem (const char *msg, void *addr, int len)
{
  char *data = addr, hex[3 * 16 + 1], ascii[17];
  unsigned int i, offset = 0;

  if (msg)
    printf("%s:\n", msg);
  for (i = 0; i < len;) {
    unsigned int i16 = i % 16;
    unsigned char c = data[i];
    sprintf(hex + (3 * i16), " %02x", c);
    ascii[i16] = (c < ' ' || c > '~') ? '.' : c;
    if (++i == len || i16 == 15) {
      ascii[i16 + 1] = '\0';
      for (; i16 != 15; ++i16)
        strcat(hex, "   ");
      printf("%04x:%s  %s\n", offset, hex, ascii);
      offset = i;
    }
  }
}
/**
 * A helper that prints either true or false
 */
const char* print_bool(char value)
{
  if (value) return bool_strings[1];
  return bool_strings[0];
}
/**
 * Prints out the current FT-X EEPROM Configuration
 */
static void ee_dump (struct eeprom_fields *ee)
{
  unsigned int c;

  /* Misc Config */
  printf("	Battery Charge Detect (BCD) Enabled = %s\n",
         print_bool(ee->bcd_enable));
  printf("	Force Power Enable Signal on CBUS = %s\n",
         print_bool(ee->force_power_enable));
  printf("	Deactivate Sleep in Battery Charge Mode = %s\n",
         print_bool(ee->deactivate_sleep));

  printf("	External Oscillator Enabled = %s\n", print_bool(ee->ext_osc));
  printf("	External Oscillator Feedback Resistor Enabled = %s\n",
         print_bool(ee->ext_osc_feedback_en));
  printf("	CBUS pin allocated to VBUS Sense Mode = %s\n",
         print_bool(ee->vbus_sense_alloc));
  printf("	Load Virtual COM Port (VCP) Drivers = %s\n",
         print_bool(ee->load_vcp));

  /* USB VID/PID */
  printf("	Vendor ID (VID) = 0x%04x\n", ee->usb_vid);
  printf("	Product ID (PID) = 0x%04x\n", ee->usb_pid);

  /* USB Release Number */
  printf("	USB Version = USB%d.%d\n", ee->usb_release_major,
         ee->usb_release_minor);

  /* Max Power and Config */
  printf("	Remote Wakeup by something other than USB = %s\n",
         print_bool(ee->remote_wakeup));
  printf("	Self Powered = %s\n", print_bool(ee->self_powered));
  printf("	Maximum Current Supported from USB = %dmA\n",
         2 * ee->max_power); /* units of 2mA */

  /* Device and perhiperal control */
  printf("	Pins Pulled Down on USB Suspend = %s\n",
         print_bool(ee->suspend_pull_down));
  printf("	Indicate USB Serial Number Available = %s\n",
         print_bool(ee->serial_number_avail));

  printf(" FT1248\n");
  printf("-------\n");
  printf("	FT1248 Clock Polarity = %s\n",
         ee->ft1248_cpol ? "Active High":"Active Low");
  printf("	FT1248 Bit Order = %s\n",
         ee->ft1248_bord ? "LSB to MSB":"MSB to LSB");
  printf("	FT1248 Flow Control Enabled = %s\n",
         print_bool(ee->ft1248_flow_control));

  printf(" RS232\n");
  printf("-------\n");
  printf("	Invert TXD = %s\n", print_bool(ee->invert_txd));
  printf("	Invert RXD = %s\n", print_bool(ee->invert_rxd));
  printf("	Invert RTS = %s\n", print_bool(ee->invert_rts));
  printf("	Invert CTS = %s\n", print_bool(ee->invert_cts));
  printf("	Invert DTR = %s\n", print_bool(ee->invert_dtr));
  printf("	Invert DSR = %s\n", print_bool(ee->invert_dsr));
  printf("	Invert DCD = %s\n", print_bool(ee->invert_dcd));
  printf("	Invert RI = %s\n", print_bool(ee->invert_ri));

  printf(" RS485\n");
  printf("-------\n");
  printf("	RS485 Echo Suppression Enabled = %s\n",
         print_bool(ee->rs485_echo_suppress));

  /* DBUS & CBUS Control */
  printf("	DBUS Drive Strength = %dmA\n", 4 * (ee->dbus_drive_strength+1));
  printf("	DBUS Slow Slew Mode = %u\n", ee->dbus_slow_slew);
  printf("	DBUS Schmitt Trigger = %u\n", ee->dbus_schmitt);
  printf("	CBUS Drive Strength = %dmA\n", 4 * (ee->cbus_drive_strength+1));
  printf("	CBUS Slow Slew Mode = %u\n", ee->cbus_slow_slew);
  printf("	CBUS Schmitt Trigger = %u\n", ee->cbus_schmitt);

  /* Manufacturer, Product and Serial Number string */
  printf("	Manufacturer = %s\n", ee->manufacturer_string);
  printf("	Product = %s\n", ee->product_string);
  printf("	Serial Number = %s\n", ee->serial_string);

  /* I2C */
  printf("  I2C\n");
  printf("-------\n");
  printf("	I2C Slave Address = %d \n", ee->i2c_slave_addr);
  printf("	I2C Device ID = %d \n", ee->i2c_device_id);
  printf("	I2C Schmitt Triggers Disabled = %s\n",
         print_bool(ee->disable_i2c_schmitt));

  /* CBUS */
  printf("  CBUS\n");
  printf("-------\n");
  for (c = 0; c < CBUS_COUNT; ++c) {
    /* Check this is a valid cbus mode */
      if (ee->cbus[c] < _cbus_mode_end) {
        printf("	CBUS%u = %s\n", c, cbus_mode_strings[ee->cbus[c]]);
      } else {
        printf("	CBUS%u = %d\n", c, ee->cbus[c]);
      }
  }
}

/* ------------ Cyclic Redundancy Check ------------ */

static unsigned short calc_crc_ftx (void *addr)
{
  unsigned int i;
  unsigned short crc = 0xaaaa;
  unsigned char* d8 = addr;

  /* Word Addresses 0x0 - 0x11 inclusive */
  for (i = 0; i < 0x12*2; i += 2) {
    crc ^= d8[i] | (d8[i+1] << 8);
    crc  = (crc << 1) | (crc >> 15);
  }

  /* Word Addresses 0x12 - 0x39 are ignored */

  /* Word Addresses 0x40 - 0x7E inclusive */
  for (i = 0x40*2; i < 0x7F*2; i += 2) {
    crc ^= d8[i] | (d8[i+1] << 8);
    crc  = (crc << 1) | (crc >> 15);
  }

  /* Word Address 0x7E is ignored */
  /* Word Address 0x7F is the checksum */

  return crc;
}
static unsigned short verify_crc (void *addr, int len)
{
  unsigned short crc    = calc_crc_ftx(addr);
  unsigned char *d8     = addr;
  unsigned short actual = d8[len-2] | (d8[len-1] << 8);

  if (crc != actual) {
    fprintf(stderr, "Bad CRC: crc=0x%04x, actual=0x%04x\n", crc, actual);
    if (ignore_crc_error == 0) {
      exit(EINVAL);
    } else {
      fprintf(stderr, "Ignoring CRC error\n");
    }
  }
  if (verbose) { printf("CRC: Okay (0x%04x)\n", crc); }
  return crc;
}
static unsigned short update_crc (void *addr, int len)
{
  unsigned short crc = calc_crc_ftx(addr);
  unsigned char *d8  = addr;

  d8[len-2] = crc;
  d8[len-1] = crc >> 8;
  return crc;
}

/* ------------ EEPROM Encoding and Decoding ------------ */

/**
 * Checks that the strings aren't too big to fit in the string
 * descriptors memory.
 */
static int ee_check_strings(char* man, char* prod, char* ser)
{
  /* if the strings are too long */
  if (strlen(man) + strlen(prod) + strlen(ser) > 96)	return 1;
  return 0;
}
/**
 * Inserts a string into a buffer to be written out to the eeprom
 */
static void ee_encode_string(char* str, unsigned char *ptr_field,
                             unsigned char* len_field, unsigned char* eeprom,
                             unsigned char* string_addr)
{
  int original_length = strlen(str), length;

  if (use_8b_strings) {
    length = original_length;
  } else {
    length = strlen(str)*2 + 2;
    char* ftstr = malloc(length);

    /* Encode a FT Prog compatible string */
    ftstr[0] = length;
    ftstr[1] = 3;

    int in, out;
    for (in = 0, out = 2; out < length; in++, out += 2) {
      ftstr[out] = str[in];
      ftstr[out+1] = 0;
    }

    str = ftstr;
  }

  /* Copy the strings to the string area */
  memcpy(eeprom + *string_addr, str, length);

  /* Write the the two metadata fields */
  *ptr_field = *string_addr;
  *len_field = length;
  /* Move the string area address forward */
  *string_addr += *len_field;
}
/**
 * Encodes an eeprom_fields object into a buffer ready to be written
 * out to the eeprom.
 */
static unsigned short ee_encode (unsigned char *eeprom, int len,
                                 struct eeprom_fields *ee)
{
  int c; unsigned char string_desc_addr = 0xA0;

  memset(eeprom, 0, len);

  /* Misc Config */
  if (ee->bcd_enable)			eeprom[0x00] |= bcd_enable;
  if (ee->force_power_enable)		eeprom[0x00] |= force_power_enable;
  if (ee->deactivate_sleep)		eeprom[0x00] |= deactivate_sleep;
  if (ee->rs485_echo_suppress)		eeprom[0x00] |= rs485_echo_suppress;
  if (ee->ext_osc)				eeprom[0x00] |= ext_osc;
  if (ee->ext_osc_feedback_en)		eeprom[0x00] |= ext_osc_feedback_en;
  if (ee->vbus_sense_alloc)		eeprom[0x00] |= vbus_sense_alloc;
  if (ee->load_vcp)			eeprom[0x00] |= load_vcp;

  /* USB VID/PID */
  eeprom[0x02] = ee->usb_vid & 0xFF;
  eeprom[0x03] = (ee->usb_vid >> 8) & 0xFF;
  eeprom[0x04] = ee->usb_pid & 0xFF;
  eeprom[0x05] = (ee->usb_pid >> 8) & 0xFF;

  /* USB Release Number */
  eeprom[0x07] = ee->usb_release_major;
  eeprom[0x06] = ee->usb_release_minor;

  /* Max Power and Config */
  if (ee->remote_wakeup)			eeprom[0x08] |= remote_wakeup;
  if (ee->self_powered)			eeprom[0x08] |= self_powered;
  eeprom[0x08] |= 0x80;	/* This is a reserved bit! */
  eeprom[0x09] = ee->max_power; /* Units of 2mA */

  /* Device and perhiperal control */
  if (ee->suspend_pull_down)		eeprom[0x0A] |= suspend_pull_down;
  if (ee->serial_number_avail)		eeprom[0x0A] |= serial_number_avail;
  if (ee->ft1248_cpol)			eeprom[0x0A] |= ft1248_cpol;
  if (ee->ft1248_bord)			eeprom[0x0A] |= ft1248_bord;
  if (ee->ft1248_flow_control)		eeprom[0x0A] |= ft1248_flow_control;
  if (ee->disable_i2c_schmitt)		eeprom[0x0A] |= disable_i2c_schmitt;
  if (ee->invert_txd)			eeprom[0x0B] |= invert_txd;
  if (ee->invert_rxd)			eeprom[0x0B] |= invert_rxd;
  if (ee->invert_rts)			eeprom[0x0B] |= invert_rts;
  if (ee->invert_cts)			eeprom[0x0B] |= invert_cts;
  if (ee->invert_dtr)			eeprom[0x0B] |= invert_dtr;
  if (ee->invert_dsr)			eeprom[0x0B] |= invert_dsr;
  if (ee->invert_dcd)			eeprom[0x0B] |= invert_dcd;
  if (ee->invert_ri)			eeprom[0x0B] |= invert_ri;

  /* DBUS & CBUS Control */
  eeprom[0x0C] |= (ee->dbus_drive_strength & dbus_drive_strength);
  if (ee->dbus_slow_slew)			eeprom[0x0C] |= dbus_slow_slew;
  if (ee->dbus_schmitt)			eeprom[0x0C] |= dbus_schmitt;
  eeprom[0x0C] |= (ee->cbus_drive_strength << 4) & cbus_drive_strength;
  if (ee->cbus_slow_slew)			eeprom[0x0C] |= cbus_slow_slew;
  if (ee->cbus_schmitt)			eeprom[0x0C] |= cbus_schmitt;

  /* eeprom[0x0D] is unused */

  /* Manufacturer, Product and Serial Number string */
  if (ee_check_strings(ee->manufacturer_string, ee->product_string,
                       ee->serial_string)) {
    fprintf(stderr,
            "Failed to encode, strings too long to fit in string memory area!\n");
    exit(EINVAL);
  }
  ee_encode_string(ee->manufacturer_string, &eeprom[0x0E], &eeprom[0x0F],
                   eeprom, &string_desc_addr);
  ee_encode_string(ee->product_string, &eeprom[0x10], &eeprom[0x11],
                   eeprom, &string_desc_addr);
  ee_encode_string(ee->serial_string, &eeprom[0x12], &eeprom[0x13],
                   eeprom, &string_desc_addr);

  /* I2C */
  eeprom[0x14] = ee->i2c_slave_addr & 0xFF;
  eeprom[0x15] = (ee->i2c_slave_addr >> 8) & 0xFF;
  eeprom[0x16] = ee->i2c_device_id & 0xFF;
  eeprom[0x17] = (ee->i2c_device_id >> 8) & 0xFF;
  eeprom[0x18] = (ee->i2c_device_id >> 16) & 0xFF;

  /* CBUS */
  for (c = 0; c < CBUS_COUNT; c++) {
    eeprom[0x1A + c] = ee->cbus[c];
  }

  /* User Memory Space */
  memcpy(&eeprom[0x24], ee->user_mem, 92);
  /* Factory Configuration Values */
  memcpy(&eeprom[0x80], ee->factory_config, 32);

  return update_crc(eeprom, len);
}
/**
 * Extracts a string from the a buffer read from eeprom
 */
static char* ee_decode_string(unsigned char *eeprom, unsigned char* ptr,
                              unsigned char len)
{
  char* str = malloc(len+1);

  if (str != NULL) {
    /* Copy the string from the EEPROM memory */
    memcpy(str, ptr, len);

    /* Decode strings written by FT Prog correctly */
    if (use_8b_strings) {
      str[len] = '\0';
    } else {

      /* Pick the actual ASCII characters out of the FT Prog encoded string */
      int in, out;
      for (in = 2, out = 0; in < len; in += 2, out++) {
        str[out] = str[in];
      }

      str[out] = '\0';
    }
  }

  return str;
}
/*
 * Populates an eeprom_fields object from a buffer read from eeprom
 */
static void ee_decode (unsigned char *eeprom, int len, struct eeprom_fields *ee)
{
  int c;

  /* Misc Config */
  ee->bcd_enable = (eeprom[0x00] & bcd_enable);
  ee->force_power_enable = (eeprom[0x00] & force_power_enable);
  ee->deactivate_sleep = (eeprom[0x00] & deactivate_sleep);
  ee->rs485_echo_suppress = (eeprom[0x00] & rs485_echo_suppress);
  ee->ext_osc = (eeprom[0x00] & ext_osc);
  ee->ext_osc_feedback_en = (eeprom[0x00] & ext_osc_feedback_en);
  ee->vbus_sense_alloc = (eeprom[0x00] & vbus_sense_alloc);
  ee->load_vcp = (eeprom[0x00] & load_vcp);

  /* USB VID/PID */
  ee->usb_vid = eeprom[0x02] | (eeprom[0x03] << 8);
  ee->usb_pid = eeprom[0x04] | (eeprom[0x05] << 8);

  /* USB Release Number */
  ee->usb_release_major = eeprom[0x07];
  ee->usb_release_minor = eeprom[0x06];

  /* Max Power and Config */
  ee->remote_wakeup = (eeprom[0x08] & remote_wakeup);
  ee->self_powered = (eeprom[0x08] & self_powered);
  ee->max_power = eeprom[0x09]; /* Units of 2mA */

  /* Device and perhiperal control */
  ee->suspend_pull_down = (eeprom[0x0A] & suspend_pull_down);
  ee->serial_number_avail = (eeprom[0x0A] & serial_number_avail);
  ee->ft1248_cpol = (eeprom[0x0A] & ft1248_cpol);
  ee->ft1248_bord = (eeprom[0x0A] & ft1248_bord);
  ee->ft1248_flow_control = (eeprom[0x0A] & ft1248_flow_control);
  ee->disable_i2c_schmitt = (eeprom[0x0A] & disable_i2c_schmitt);
  ee->invert_txd = (eeprom[0x0B] & invert_txd);
  ee->invert_rxd = (eeprom[0x0B] & invert_rxd);
  ee->invert_rts = (eeprom[0x0B] & invert_rts);
  ee->invert_cts = (eeprom[0x0B] & invert_cts);
  ee->invert_dtr = (eeprom[0x0B] & invert_dtr);
  ee->invert_dsr = (eeprom[0x0B] & invert_dsr);
  ee->invert_dcd = (eeprom[0x0B] & invert_dcd);
  ee->invert_ri = (eeprom[0x0B] & invert_ri);

  /* DBUS & CBUS Control */
  ee->dbus_drive_strength = (eeprom[0x0C] & dbus_drive_strength);
  ee->dbus_slow_slew = (eeprom[0x0C] & dbus_slow_slew);
  ee->dbus_schmitt = (eeprom[0x0C] & dbus_schmitt);
  ee->cbus_drive_strength = (eeprom[0x0C] & cbus_drive_strength) >> 4;
  ee->cbus_slow_slew = (eeprom[0x0C] & cbus_slow_slew);
  ee->cbus_schmitt = (eeprom[0x0C] & cbus_schmitt);

  /* eeprom[0x0D] is unused */

  /* Manufacturer, Product and Serial Number string */
  ee->manufacturer_string = ee_decode_string(eeprom,
                                             eeprom+eeprom[0x0E], eeprom[0x0F]);
  ee->product_string = ee_decode_string(eeprom,
                                        eeprom+eeprom[0x10], eeprom[0x11]);
  ee->serial_string = ee_decode_string(eeprom,
                                       eeprom+eeprom[0x12], eeprom[0x13]);

  /* I2C */
  ee->i2c_slave_addr = eeprom[0x14] | (eeprom[0x15] << 8);
  ee->i2c_device_id = eeprom[0x16] | (eeprom[0x17] << 8) | (eeprom[0x18] << 16);

  /* CBUS */
  for (c = 0; c < CBUS_COUNT; c++) {
    ee->cbus[c] = eeprom[0x1A + c];
  }

  /* User Memory Space */
  memcpy(ee->user_mem, &eeprom[0x24], 92);
  /* Factory Configuration Values */
  memcpy(ee->factory_config, &eeprom[0x80], 32);
}

/* ------------ Help ------------ */

static const char *myname;

/**
 * Prints a human-readable expression showing all the possibilities
 * for an option.
 */
static void print_options(FILE *fp, const char** options)
{
  int j;

  fprintf(fp, "  [");
  for (j = 0; options[j];) {
    fprintf(fp, "%s", options[j]);
    if (options[++j])
      fprintf(fp, "|");
  }
  fprintf(fp, "]");
}
/*
 * Prints a human readable help text.
 */
static void show_help (FILE *fp)
{
  int i;

  fprintf(fp, "\nUsage:  %s [<arg> <val>]..\n", myname);
  fprintf(fp, "\nwhere <arg> must be any of:\n");

  for (i = 0; arg_type_strings[i]; ++i) { /* For each argument */
    /* Get the help string */
    const char *val = arg_type_help[i];
    /* Print its name */
    fprintf(fp, "    %s", arg_type_strings[i]);

    if (val) { /* If there is a help string */
      if (strcmp(val, "[cbus]") == 0) {
        fprintf(fp, "  [1..%d]", CBUS_COUNT);
        print_options(fp, cbus_mode_strings);
      } else if (strcmp(val, "[invert]") == 0) {
        print_options(fp, rs232_strings);
      } else if (strcmp(val, "dbus_cfg") == 0) {
        print_options(fp, d_cbus_config_strings);
      } else if (strcmp(val, "cbus_cfg") == 0) {
        print_options(fp, d_cbus_config_strings);
      } else {
        fprintf(fp, "  %s", val);
      }
    }
    fputc('\n', fp);
  }
  fputc('\n', fp);
}

/* ------------ EEPROM Reading and Writing ------------ */

#ifdef USE_LIBFTDI1
static int ee_write(unsigned char *eeprom, int len)
{
  if (ftdi_set_eeprom_buf(&ftdi, eeprom, len) != 0)
    exit(EIO);

  if (ftdi_write_eeprom(&ftdi) != 0)
    exit(EIO);

  return 0;
}
#else
static int ee_prepare_write(void)
{
  unsigned short status;
  int ret;

  /* These commands were traced while running MProg */
  if ((ret = ftdi_usb_reset(&ftdi)) != 0) { return ret; }
  if ((ret = ftdi_poll_modem_status(&ftdi, &status)) != 0) { return ret; }
  if ((ret = ftdi_set_latency_timer(&ftdi, 0x77)) != 0) { return ret; }

  return 0;
}
static int ee_write(unsigned char *eeprom, int len)
{
  int i;

  if (ee_prepare_write()) {
    fprintf(stderr, "ee_prepare_write() failed: %s\n",
            ftdi_get_error_string(&ftdi));
    exit(EIO);
  }

  for (i = 0; i < len/2; i++) {
    if (ftdi_write_eeprom_location(&ftdi, i,
                                   eeprom[i*2] | (eeprom[(i*2)+1] << 8))) {
      fprintf(stderr, "ftdi_write_eeprom_location() failed: %s\n",
              ftdi_get_error_string(&ftdi));
      exit(EIO);
    }
  }

  return 0;
}
#endif

static unsigned short ee_read_and_verify (unsigned char *eeprom, int len)
{
#ifdef USE_LIBFTDI1
  if (ftdi_read_eeprom(&ftdi) != 0)
    exit(EIO);

  if (ftdi_get_eeprom_buf(&ftdi, eeprom, len) != 0)
    exit(EIO);

  if (ftdi_eeprom_build(&ftdi) < 0)
    exit(EIO);
#else
  int i;

  for (i = 0; i < len/2; i++) {
    if (ftdi_read_eeprom_location(&ftdi, i, (void*)(eeprom + (i*2)))) {
      fprintf(stderr, "ftdi_read_eeprom_location() failed: %s\n",
              ftdi_get_error_string(&ftdi));
      exit(EIO);
    }
  }
#endif

  return verify_crc(eeprom, len);
}

/* ------------ Parsing Command Line ------------ */

static int match_arg (const char *arg, const char **possibles)
{
  int i;

  for (i = 0; possibles[i]; ++i) {
    if (0 == strcasecmp(possibles[i], arg))
      return i;
  }
  fprintf(stderr, "unrecognized arg: \"%s\"\n", arg);
  exit(EINVAL);
  return -1;  /* never reached */
}
static unsigned long unsigned_val (const char *arg, unsigned long max)
{
  unsigned long val;

  errno = 0;
  val = strtoul(arg, NULL, 0);
  if (errno || val > max) {
    fprintf(stderr, "%s: bad value (max=0x%lx)\n", arg, max);
    exit(EINVAL);
  }
  return val;
}



static int process_args (int argc, char *argv[], struct eeprom_fields *ee)
{
  int i; int c;
  int j;

  for (i = 1; i < argc;) {
    int arg;
    arg = match_arg(argv[i++], arg_type_strings);

    /* detect missing arguments and handle errors */
    int expected_args = 0;
    for (j = 0; j < (sizeof(req_info) / sizeof(req_info[0])); j++) {
      if (req_info[j].t == arg) expected_args = req_info[j].number;
    }

    int remaining_args = (argc - i);
    if (remaining_args < expected_args) {
      fprintf(stderr, "Missing arguments to %s.  "
              "Expected %i but only %i args remain\n",
              argv[i - 1], expected_args, remaining_args);
      fprintf(stderr, "type %s --help for more information\n", argv[0]);
      return -1;
    }

    switch (arg) {
    case arg_help:
      show_help(stdout);
      exit(1);
    case arg_dump:
      break;
    case arg_ignore_crc_error:
      ignore_crc_error = 1;
      break;
    case arg_erase_eeprom:
      erase_eeprom = 1;
      break;
    case arg_verbose:
      verbose = 1;
      break;
      /* File operations */
    case arg_save:
      save_path = argv[i++];
      break;
    case arg_restore:
      restore_path = argv[i++];
      break;
    case arg_8b_strings:
      use_8b_strings = true;
      break;
    case arg_cbus:
      c = match_arg(argv[i++], cbus_strings);
      ee->cbus[c] = match_arg(argv[i++], cbus_mode_strings);
      break;
    case arg_cbus_config:
      c = match_arg(argv[i++], d_cbus_config_strings);
      if(c < 4) {
        ee->cbus_drive_strength = c;
      } else if (4 == c) {
        ee->cbus_slow_slew = 1;
      } else if(6 == c) {
        ee->cbus_schmitt = 1;
      }
      break;
    case arg_dbus_config:
      c = match_arg(argv[i++], d_cbus_config_strings);
      if( c < 4)
        ee->dbus_drive_strength = c;
      else if( 4 == c){
        ee->dbus_slow_slew=1;
      }	else if( 6 == c)
        ee->dbus_schmitt=1;
      break;
    case arg_invert:
      switch(match_arg(argv[i++], rs232_strings)) {
      case 0:	ee->invert_txd = !ee->invert_txd; break;
      case 1:	ee->invert_rxd = !ee->invert_rxd; break;
      case 2:	ee->invert_rts = !ee->invert_rts; break;
      case 3:	ee->invert_cts = !ee->invert_cts; break;
      case 4:	ee->invert_dtr = !ee->invert_dtr; break;
      case 5:	ee->invert_dsr = !ee->invert_dsr; break;
      case 6:	ee->invert_dcd = !ee->invert_dcd; break;
      case 7:	ee->invert_ri = !ee->invert_ri; break;
      }
      break;
      /* Strings */
    case arg_manufacturer:
      ee->manufacturer_string = argv[i++];
      break;
    case arg_product:
      ee->product_string = argv[i++];
      break;
    case arg_new_serno:
      ee->serial_string = argv[i++];
      ee->serial_number_avail = strlen(ee->serial_string) > 0;
      break;
    case arg_max_bus_power:
      ee->max_power = unsigned_val(argv[i++], 0x1ff) / 2;
      break;
    case arg_self_powered:
      ee->self_powered = match_arg(argv[i++], bool_strings) & 1;
      break;
    case arg_suspend_pull_down:
      ee->suspend_pull_down = match_arg(argv[i++], bool_strings) & 1;
      break;
    case arg_load_vcp:
      ee->load_vcp = match_arg(argv[i++], bool_strings) & 1;
      break;
    case arg_remote_wakeup:
      ee->remote_wakeup = match_arg(argv[i++], bool_strings) & 1;
      break;
      /* FT1248 */
    case arg_ft1248_cpol:
      ee->ft1248_cpol = match_arg(argv[i++], bool_strings) & 1;
      break;
    case arg_ft1248_bord:
      ee->ft1248_bord = match_arg(argv[i++], bool_strings) & 1;
      break;
    case arg_ft1248_flow_control:
      ee->ft1248_flow_control = match_arg(argv[i++], bool_strings) & 1;
      break;
    case arg_i2c_schmitt:
      /* The command line arg is enabled +ve, the eeprom is disabled +ve */
      ee->disable_i2c_schmitt = !(match_arg(argv[i++], bool_strings) & 1);
      break;
      /* I2C */
    case arg_i2c_slave_address:
      ee->i2c_slave_addr = unsigned_val(argv[i++], 0xffff);
      break;
    case arg_i2c_device_id:
      ee->i2c_device_id = unsigned_val(argv[i++], 0xffff);
      break;
      /* RS485 */
    case arg_rs485_echo_suppression:
      ee->rs485_echo_suppress = match_arg(argv[i++], bool_strings) & 1;
      break;
      /* VID, PID, Ser No. */
    case arg_old_vid:
      ee->old_vid = unsigned_val(argv[i++], 0xffff);
      break;
    case arg_old_pid:
      ee->old_pid = unsigned_val(argv[i++], 0xffff);
      break;
    case arg_old_serno:
      ee->old_serno = argv[i++];
      break;
    case arg_new_vid:
      ee->usb_vid = unsigned_val(argv[i++], 0xffff);
      break;
    case arg_new_pid:
      ee->usb_pid = unsigned_val(argv[i++], 0xffff);
      break;
    }
  }

  return 0;
}

/* ------------ File Save / Restore ------------ */

static void save_eeprom_to_file (const char *path, void *eeprom, int len)
{
  int count, fd = open(path, O_CREAT|O_WRONLY|O_TRUNC, 0644);

  if (fd == -1) {
    int err = errno;
    perror(path);
    exit(err);
  }
  count = write(fd, eeprom, len);
  if (count < 0) {
    int err = errno;
    perror(path);
    exit(err);
  }
  close(fd);
  if (count != len) {
    fprintf(stderr, "%s: wrong size, wrote %d/%d bytes\n", path, count, len);
    exit(EINVAL);
  }
  printf("%s: wrote %d bytes\n", path, count);
}

static void restore_eeprom_from_file (const char *path, void *eeprom, int len,
                                      int max)
{
  int count, fd = open(path, O_RDONLY);

  if (fd == -1) {
    int err = errno;
    perror(path);
    exit(err);
  }
  count = read(fd, eeprom, max);
  if (count < 0) {
    int err = errno;
    perror(path);
    exit(err);
  }
  close(fd);
  if (count != len ) {
    fprintf(stderr, "%s: wrong size, read %d/%d bytes\n", path, count, len);
    exit(EINVAL);
  }
  printf("%s: read %d bytes\n", path, count);
  verify_crc(eeprom, len);
}

/* ------------ Main ------------ */

int main (int argc, char *argv[])
{
  const char *slash;
  unsigned char old[0x100] = {0,}, new[0x100] = {0,};
  unsigned short new_crc;
  struct eeprom_fields ee;
  /* We only deal with the first 256 bytes and ignore the user memory space */
  unsigned int len = 0x100;

  myname = argv[0];
  slash = strrchr(myname, '/');
  if (slash)
    myname = slash + 1;

  printf("\n%s: version %s\n", myname, MYVERSION);
  printf("Modified for the FT-X series by Richard Meadows\n\n");
  printf("Based upon:\n");
  printf("ft232r_prog: version 1.23, by Mark Lord.\n");
  if (argc < 2) {
    show_help(stdout);
    exit(0);
  }

  ftdi_init(&ftdi);
  atexit(&do_deinit);

  memset(&ee, 0, sizeof(ee));
  ee.old_vid = 0x0403;	/* default; override with --old_vid arg */
  ee.old_pid = 0x6015;	/* default; override with --old_pid arg */
  if (process_args(argc, argv, &ee)) { /* handle --help and --old-* args */
    return -1;
  }

  if (ftdi_usb_open_desc(&ftdi, ee.old_vid, ee.old_pid, NULL, ee.old_serno)) {
    fprintf(stderr, "ftdi_usb_open() failed for %04x:%04x:%s %s\n",
            ee.old_vid, ee.old_pid,
            ee.old_serno ? ee.old_serno : "", ftdi_get_error_string(&ftdi));
    exit(ENODEV);
  }
  atexit(&do_close);

  /* First, read the original eeprom from the device */
  (void) ee_read_and_verify(old, len);
  if (verbose) dumpmem("existing eeprom", old, len);

  /* Save old contents to a file, if requested (--save) */
  if (save_path)
    save_eeprom_to_file(save_path, old, len);

  /* Restore contents from a file, if requested (--restore) */
  if (restore_path) {
    restore_eeprom_from_file(restore_path, new, len, sizeof(new));
    if (verbose) dumpmem(restore_path, new, len);
  }

  /* TODO: It'd be nice to check we can restore the EEPROM.. */

  /* Decode eeprom contents into ee struct */
  ee_decode(old, len, &ee);

  /* process args, and dump new settings */
  process_args(argc, argv, &ee);	/* Handle value-change args */
  ee_dump(&ee);

  /* Build new eeprom image */
  if (erase_eeprom == 0) {
    new_crc = ee_encode(new, len, &ee);
  }  else {
    memset(new, 0xff, 0x100);
    new_crc = 0xFFFF;
  }

  /* If different from original, then write it back to the device */
  if (0 == memcmp(old, new, len)) {
    printf("No change from existing eeprom contents.\n");
  } else {
    if (verbose) { dumpmem("new eeprom", new, len); }

    if (erase_eeprom == 0) {
      printf("Rewriting eeprom with new contents.\n");
    } else {
      printf("Erasing EEPROM\n");
    }

    printf("Continue? [y|n]:");
    if (getc(stdin) == 'y') {
      ee_write(new, len);

      /* Read it back again, and check for differences */
      if (ee_read_and_verify(new, len) != new_crc ) {
        fprintf(stderr, "Readback test failed, results may be botched\n");
        exit(EINVAL);
      }
      if (erase_eeprom == 1) { printf("Erase done\n"); }

      /* Reset the device to force it to load the new settings */
      ftdi_usb_reset(&ftdi);
    }
  }

  return 0;
}