Bochs/bochs/iodev/pciusb.cc

/////////////////////////////////////////////////////////////////////////
// $Id: pciusb.cc,v 1.72 2009-01-18 13:11:27 vruppert Exp $
/////////////////////////////////////////////////////////////////////////
//
//  Copyright (C) 2009  Benjamin D Lunt (fys at frontiernet net)
//
//  This library is free software; you can redistribute it and/or
//  modify it under the terms of the GNU Lesser General Public
//  License as published by the Free Software Foundation; either
//  version 2 of the License, or (at your option) any later version.
//
//  This library 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
//  Lesser General Public License for more details.
//
//  You should have received a copy of the GNU Lesser General Public
//  License along with this library; if not, write to the Free Software
//  Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301  USA

// Experimental PCI USB adapter

// Notes: See usb_common.cc

// Define BX_PLUGGABLE in files that can be compiled into plugins.  For
// platforms that require a special tag on exported symbols, BX_PLUGGABLE
// is used to know when we are exporting symbols and when we are importing.
#define BX_PLUGGABLE

#include "iodev.h"

#if BX_SUPPORT_PCI && BX_SUPPORT_PCIUSB

#include "pci.h"
#include "usb_common.h"
#include "usb_hid.h"
#include "usb_msd.h"
#include "pciusb.h"

#define LOG_THIS theUSBDevice->

bx_pciusb_c* theUSBDevice = NULL;

const Bit8u usb_iomask[32] = {2, 1, 2, 1, 2, 1, 2, 0, 4, 0, 0, 0, 1, 0, 0, 0,
                              3, 1, 3, 1, 3, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0};

int libpciusb_LTX_plugin_init(plugin_t *plugin, plugintype_t type, int argc, char *argv[])
{
  theUSBDevice = new bx_pciusb_c();
  bx_devices.pluginPciUSBAdapter = theUSBDevice;
  BX_REGISTER_DEVICE_DEVMODEL(plugin, type, theUSBDevice, BX_PLUGIN_PCIUSB);
  return 0; // Success
}

void libpciusb_LTX_plugin_fini(void)
{
  delete theUSBDevice;
}

bx_pciusb_c::bx_pciusb_c()
{
  put("USB");
  for (int i=0; i<BX_USB_CONFDEV; i++) {
    memset((void*)&hub[i], 0, sizeof(bx_usb_t));
  }
  device_buffer = NULL;
}

bx_pciusb_c::~bx_pciusb_c()
{
  if (BX_USB_THIS device_buffer != NULL)
    delete [] BX_USB_THIS device_buffer;

  for (int i=0; i<BX_USB_CONFDEV; i++) {
    for (int j=0; j<USB_NUM_PORTS; j++) {
      if (BX_USB_THIS hub[i].usb_port[j].device != NULL) {
        delete BX_USB_THIS hub[i].usb_port[j].device;
      }
    }
  }

  SIM->get_param_string(BXPN_USB1_PORT1)->set_handler(NULL);
  SIM->get_param_string(BXPN_USB1_PORT2)->set_handler(NULL);

  BX_DEBUG(("Exit"));
}

void bx_pciusb_c::init(void)
{
  // called once when bochs initializes

  if (!SIM->get_param_bool(BXPN_USB1_ENABLED)->get()) return;

  BX_USB_THIS device_buffer = new Bit8u[65536];

  // Call our timer routine every 1mS (1,000uS)
  // Continuous and active
  BX_USB_THIS hub[0].timer_index =
                   bx_pc_system.register_timer(this, usb_timer_handler, 1000, 1,1, "usb.timer");

  BX_USB_THIS hub[0].devfunc = BX_PCI_DEVICE(1,2);
  DEV_register_pci_handlers(this, &BX_USB_THIS hub[0].devfunc, BX_PLUGIN_PCIUSB,
                            "Experimental PCI USB");

  for (unsigned i=0; i<256; i++) {
    BX_USB_THIS hub[0].pci_conf[i] = 0x0;
  }

  BX_USB_THIS hub[0].base_ioaddr = 0x0;

  BX_INFO(("usb1 initialized - I/O base and IRQ assigned by PCI BIOS"));

  //FIXME: for now, we want a status bar // hub zero, port zero
  BX_USB_THIS hub[0].statusbar_id[0] = bx_gui->register_statusitem("USB");

  SIM->get_param_string(BXPN_USB1_PORT1)->set_handler(usb_param_handler);
  SIM->get_param_string(BXPN_USB1_PORT1)->set_runtime_param(1);
  SIM->get_param_string(BXPN_USB1_PORT2)->set_handler(usb_param_handler);
  SIM->get_param_string(BXPN_USB1_PORT2)->set_runtime_param(1);

  //HACK: Turn on debug messages from the start
  //BX_USB_THIS setonoff(LOGLEV_DEBUG, ACT_REPORT);
}

void bx_pciusb_c::reset(unsigned type)
{
  unsigned i, j;

  if (!SIM->get_param_bool(BXPN_USB1_ENABLED)->get()) return;

  if (type == BX_RESET_HARDWARE) {
    static const struct reset_vals_t {
      unsigned      addr;
      unsigned char val;
    } reset_vals[] = {
      { 0x00, 0x86 }, { 0x01, 0x80 }, // 0x8086 = vendor
      { 0x02, 0x20 }, { 0x03, 0x70 }, // 0x7020 = device
      { 0x04, 0x05 }, { 0x05, 0x00 }, // command_io
      { 0x06, 0x80 }, { 0x07, 0x02 }, // status
      { 0x08, 0x01 },                 // revision number
      { 0x09, 0x00 },                 // interface
      { 0x0a, 0x03 },                 // class_sub  USB Host Controller
      { 0x0b, 0x0c },                 // class_base Serial Bus Controller
      { 0x0D, 0x20 },                 // bus latency
      { 0x0e, 0x00 },                 // header_type_generic
      // address space 0x20 - 0x23
      { 0x20, 0x01 }, { 0x21, 0x00 },
      { 0x22, 0x00 }, { 0x23, 0x00 },
      { 0x3c, 0x00 },                 // IRQ
      { 0x3d, BX_PCI_INTD },          // INT
      { 0x60, 0x10 },                 // USB revision 1.0
      { 0x6a, 0x01 },                 // USB clock
      { 0xc1, 0x20 }                  // PIRQ enable

    };
    for (i = 0; i < sizeof(reset_vals) / sizeof(*reset_vals); ++i) {
        BX_USB_THIS hub[0].pci_conf[reset_vals[i].addr] = reset_vals[i].val;
    }
  }

  // reset locals
  BX_USB_THIS busy = 0;
  BX_USB_THIS global_reset = 0;

  // Put the USB registers into their RESET state
  for (i=0; i<BX_USB_CONFDEV; i++) {
    BX_USB_THIS hub[i].usb_command.max_packet_size = 0;
    BX_USB_THIS hub[i].usb_command.configured = 0;
    BX_USB_THIS hub[i].usb_command.debug = 0;
    BX_USB_THIS hub[i].usb_command.resume = 0;
    BX_USB_THIS hub[i].usb_command.suspend = 0;
    BX_USB_THIS hub[i].usb_command.reset = 0;
    BX_USB_THIS hub[i].usb_command.host_reset = 0;
    BX_USB_THIS hub[i].usb_command.schedule = 0;
    BX_USB_THIS hub[i].usb_status.error_interrupt = 0;
    BX_USB_THIS hub[i].usb_status.host_error = 0;
    BX_USB_THIS hub[i].usb_status.host_halted = 0;
    BX_USB_THIS hub[i].usb_status.interrupt = 0;
    BX_USB_THIS hub[i].usb_status.pci_error = 0;
    BX_USB_THIS hub[i].usb_status.resume = 0;
    BX_USB_THIS hub[i].usb_enable.short_packet = 0;
    BX_USB_THIS hub[i].usb_enable.on_complete = 0;
    BX_USB_THIS hub[i].usb_enable.resume = 0;
    BX_USB_THIS hub[i].usb_enable.timeout_crc = 0;
    BX_USB_THIS hub[i].usb_frame_num.frame_num = 0x0000;
    BX_USB_THIS hub[i].usb_frame_base.frame_base = 0x00000000;
    BX_USB_THIS hub[i].usb_sof.sof_timing = 0x40;
    for (j=0; j<USB_NUM_PORTS; j++) {
      BX_USB_THIS hub[i].usb_port[j].connect_changed = 0;
      BX_USB_THIS hub[i].usb_port[j].line_dminus = 0;
      BX_USB_THIS hub[i].usb_port[j].line_dplus = 0;
      BX_USB_THIS hub[i].usb_port[j].low_speed = 0;
      BX_USB_THIS hub[i].usb_port[j].reset = 0;
      BX_USB_THIS hub[i].usb_port[j].resume = 0;
      BX_USB_THIS hub[i].usb_port[j].suspend = 0;
      BX_USB_THIS hub[i].usb_port[j].enabled = 0;
      BX_USB_THIS hub[i].usb_port[j].able_changed = 0;
      BX_USB_THIS hub[i].usb_port[j].status = 0;
      if (BX_USB_THIS hub[i].usb_port[j].device != NULL) {
        delete BX_USB_THIS hub[i].usb_port[j].device;
        BX_USB_THIS hub[i].usb_port[j].device = NULL;
      }
    }
  }

  BX_USB_THIS mousedev = NULL;
  BX_USB_THIS keybdev = NULL;

  init_device(0, SIM->get_param_string(BXPN_USB1_PORT1)->getptr());
  init_device(1, SIM->get_param_string(BXPN_USB1_PORT2)->getptr());
}

void bx_pciusb_c::register_state(void)
{
  unsigned i, j;
  char hubnum[8], portnum[8];
  bx_list_c *hub, *usb_cmd, *usb_st, *usb_en, *port;

  bx_list_c *list = new bx_list_c(SIM->get_bochs_root(), "pciusb", "PCI USB Controller State", BX_USB_CONFDEV + 2);
  for (i=0; i<BX_USB_CONFDEV; i++) {
    sprintf(hubnum, "hub%d", i+1);
    hub = new bx_list_c(list, hubnum, USB_NUM_PORTS + 7);
    usb_cmd = new bx_list_c(hub, "usb_command", 8);
    new bx_shadow_bool_c(usb_cmd, "max_packet_size", &BX_USB_THIS hub[i].usb_command.max_packet_size);
    new bx_shadow_bool_c(usb_cmd, "configured", &BX_USB_THIS hub[i].usb_command.configured);
    new bx_shadow_bool_c(usb_cmd, "debug", &BX_USB_THIS hub[i].usb_command.debug);
    new bx_shadow_bool_c(usb_cmd, "resume", &BX_USB_THIS hub[i].usb_command.resume);
    new bx_shadow_bool_c(usb_cmd, "suspend", &BX_USB_THIS hub[i].usb_command.suspend);
    new bx_shadow_bool_c(usb_cmd, "reset", &BX_USB_THIS hub[i].usb_command.reset);
    new bx_shadow_bool_c(usb_cmd, "host_reset", &BX_USB_THIS hub[i].usb_command.host_reset);
    new bx_shadow_bool_c(usb_cmd, "schedule", &BX_USB_THIS hub[i].usb_command.schedule);
    usb_st = new bx_list_c(hub, "usb_status", 6);
    new bx_shadow_bool_c(usb_st, "host_halted", &BX_USB_THIS hub[i].usb_status.host_halted);
    new bx_shadow_bool_c(usb_st, "host_error", &BX_USB_THIS hub[i].usb_status.host_error);
    new bx_shadow_bool_c(usb_st, "pci_error", &BX_USB_THIS hub[i].usb_status.pci_error);
    new bx_shadow_bool_c(usb_st, "resume", &BX_USB_THIS hub[i].usb_status.resume);
    new bx_shadow_bool_c(usb_st, "error_interrupt", &BX_USB_THIS hub[i].usb_status.error_interrupt);
    new bx_shadow_bool_c(usb_st, "interrupt", &BX_USB_THIS hub[i].usb_status.interrupt);
    usb_en = new bx_list_c(hub, "usb_enable", 4);
    new bx_shadow_bool_c(usb_en, "short_packet", &BX_USB_THIS hub[i].usb_enable.short_packet);
    new bx_shadow_bool_c(usb_en, "on_complete", &BX_USB_THIS hub[i].usb_enable.on_complete);
    new bx_shadow_bool_c(usb_en, "resume", &BX_USB_THIS hub[i].usb_enable.resume);
    new bx_shadow_bool_c(usb_en, "timeout_crc", &BX_USB_THIS hub[i].usb_enable.timeout_crc);
    new bx_shadow_num_c(hub, "frame_num", &BX_USB_THIS hub[i].usb_frame_num.frame_num, BASE_HEX);
    new bx_shadow_num_c(hub, "frame_base", &BX_USB_THIS hub[i].usb_frame_base.frame_base, BASE_HEX);
    new bx_shadow_num_c(hub, "sof_timing", &BX_USB_THIS hub[i].usb_sof.sof_timing, BASE_HEX);
    for (j=0; j<USB_NUM_PORTS; j++) {
      sprintf(portnum, "port%d", j+1);
      port = new bx_list_c(hub, portnum, 11);
      new bx_shadow_bool_c(port, "suspend", &BX_USB_THIS hub[i].usb_port[j].suspend);
      new bx_shadow_bool_c(port, "reset", &BX_USB_THIS hub[i].usb_port[j].reset);
      new bx_shadow_bool_c(port, "low_speed", &BX_USB_THIS hub[i].usb_port[j].low_speed);
      new bx_shadow_bool_c(port, "resume", &BX_USB_THIS hub[i].usb_port[j].resume);
      new bx_shadow_bool_c(port, "line_dminus", &BX_USB_THIS hub[i].usb_port[j].line_dminus);
      new bx_shadow_bool_c(port, "line_dplus", &BX_USB_THIS hub[i].usb_port[j].line_dplus);
      new bx_shadow_bool_c(port, "able_changed", &BX_USB_THIS hub[i].usb_port[j].able_changed);
      new bx_shadow_bool_c(port, "enabled", &BX_USB_THIS hub[i].usb_port[j].enabled);
      new bx_shadow_bool_c(port, "connect_changed", &BX_USB_THIS hub[i].usb_port[j].connect_changed);
      new bx_shadow_bool_c(port, "status", &BX_USB_THIS hub[i].usb_port[j].status);
      // empty list for USB device state
      new bx_list_c(port, "device", 20);
    }
    register_pci_state(hub, BX_USB_THIS hub[i].pci_conf);
  }
  new bx_shadow_bool_c(list, "busy", &BX_USB_THIS busy);
  new bx_shadow_num_c(list, "global_reset", &BX_USB_THIS global_reset);
}

void bx_pciusb_c::after_restore_state(void)
{
  if (DEV_pci_set_base_io(BX_USB_THIS_PTR, read_handler, write_handler,
                         &BX_USB_THIS hub[0].base_ioaddr,
                         &BX_USB_THIS hub[0].pci_conf[0x20],
                         32, &usb_iomask[0], "USB Hub #1"))
  {
     BX_INFO(("new base address: 0x%04x", BX_USB_THIS hub[0].base_ioaddr));
  }
  for (int i=0; i<BX_USB_CONFDEV; i++) {
    for (int j=0; j<USB_NUM_PORTS; j++) {
      if (BX_USB_THIS hub[i].usb_port[j].device != NULL) {
        BX_USB_THIS hub[i].usb_port[j].device->after_restore_state();
      }
    }
  }
}

void bx_pciusb_c::init_device(Bit8u port, const char *devname)
{
  usbdev_type type = USB_DEV_TYPE_NONE;
  char pname[BX_PATHNAME_LEN];

  if (!strlen(devname) || !strcmp(devname, "none")) return;

  if (!strcmp(devname, "mouse")) {
    type = USB_DEV_TYPE_MOUSE;
    BX_USB_THIS hub[0].usb_port[port].device = new usb_hid_device_t(type);
    if (BX_USB_THIS mousedev == NULL) {
      BX_USB_THIS mousedev = (usb_hid_device_t*)BX_USB_THIS hub[0].usb_port[port].device;
    }
  } else if (!strcmp(devname, "tablet")) {
    type = USB_DEV_TYPE_TABLET;
    BX_USB_THIS hub[0].usb_port[port].device = new usb_hid_device_t(type);
    if (BX_USB_THIS mousedev == NULL) {
      BX_USB_THIS mousedev = (usb_hid_device_t*)BX_USB_THIS hub[0].usb_port[port].device;
    }
  } else if (!strcmp(devname, "keypad")) {
    type = USB_DEV_TYPE_KEYPAD;
    BX_USB_THIS hub[0].usb_port[port].device = new usb_hid_device_t(type);
    if (BX_USB_THIS keybdev == NULL) {
      BX_USB_THIS keybdev = (usb_hid_device_t*)BX_USB_THIS hub[0].usb_port[port].device;
    }
  } else if (!strncmp(devname, "disk", 4)) {
    if ((strlen(devname) > 5) && (devname[4] == ':')) {
      type = USB_DEV_TYPE_DISK;
      BX_USB_THIS hub[0].usb_port[port].device = new usb_msd_device_t();
    } else {
      BX_PANIC(("USB device 'disk' needs a filename separated with a colon"));
      return;
    }
  } else {
    BX_PANIC(("unknown USB device: %s", devname));
    return;
  }
  sprintf(pname, "pciusb.hub1.port%d.device", port+1);
  bx_list_c *devlist = (bx_list_c*)SIM->get_param(pname, SIM->get_bochs_root());
  BX_USB_THIS hub[0].usb_port[port].device->register_state(devlist);
  usb_set_connect_status(port, type, 1);
}

void bx_pciusb_c::set_irq_level(bx_bool level)
{
  DEV_pci_set_irq(BX_USB_THIS hub[0].devfunc, BX_USB_THIS hub[0].pci_conf[0x3d], level);
}

// static IO port read callback handler
// redirects to non-static class handler to avoid virtual functions

Bit32u bx_pciusb_c::read_handler(void *this_ptr, Bit32u address, unsigned io_len)
{
#if !BX_USE_PCIUSB_SMF
  bx_pciusb_c *class_ptr = (bx_pciusb_c *) this_ptr;
  return class_ptr->read(address, io_len);
}

Bit32u bx_pciusb_c::read(Bit32u address, unsigned io_len)
{
#else
  UNUSED(this_ptr);
#endif // !BX_USE_PCIUSB_SMF
  Bit32u val = 0x0;
  Bit8u  offset,port;

  offset = address - BX_USB_THIS hub[0].base_ioaddr;

  switch (offset) {
    case 0x00: // command register (16-bit)
      val =   BX_USB_THIS hub[0].usb_command.max_packet_size << 7
            | BX_USB_THIS hub[0].usb_command.configured << 6
            | BX_USB_THIS hub[0].usb_command.debug << 5
            | BX_USB_THIS hub[0].usb_command.resume << 4
            | BX_USB_THIS hub[0].usb_command.suspend << 3
            | BX_USB_THIS hub[0].usb_command.reset << 2
            | BX_USB_THIS hub[0].usb_command.host_reset << 1
            | BX_USB_THIS hub[0].usb_command.schedule;
      break;

    case 0x02: // status register (16-bit)
      val = BX_USB_THIS hub[0].usb_status.host_halted << 5
            | BX_USB_THIS hub[0].usb_status.host_error << 4
            | BX_USB_THIS hub[0].usb_status.pci_error << 3
            | BX_USB_THIS hub[0].usb_status.resume << 2
            | BX_USB_THIS hub[0].usb_status.error_interrupt << 1
            | BX_USB_THIS hub[0].usb_status.interrupt;
      break;

    case 0x04: // interrupt enable register (16-bit)
      val = BX_USB_THIS hub[0].usb_enable.short_packet << 3
            | BX_USB_THIS hub[0].usb_enable.on_complete << 2
            | BX_USB_THIS hub[0].usb_enable.resume << 1
            | BX_USB_THIS hub[0].usb_enable.timeout_crc;
      break;

    case 0x06: // frame number register (16-bit)
      val = BX_USB_THIS hub[0].usb_frame_num.frame_num;
      break;

    case 0x08: // frame base register (32-bit)
      val = BX_USB_THIS hub[0].usb_frame_base.frame_base;
      break;

    case 0x0C: // start of Frame Modify register (8-bit)
      val = BX_USB_THIS hub[0].usb_sof.sof_timing;
      break;

    case 0x14: // port #3 non existant, but linux systems check it to see if there are more than 2
      BX_ERROR(("read from non existant offset 0x14 (port #3)"));
      val = 0xFF7F;
      break;

    case 0x10: // port #1
    case 0x11:
    case 0x12: // port #2
    case 0x13:
      port = (offset & 0x0F) >> 1;
      if (port < USB_NUM_PORTS) {
        val = BX_USB_THIS hub[0].usb_port[port].suspend << 12
              |                                       1 << 10  // some Root Hubs have bit 10 set ?????
              | BX_USB_THIS hub[0].usb_port[port].reset << 9
              | BX_USB_THIS hub[0].usb_port[port].low_speed << 8
              | 1 << 7
              | BX_USB_THIS hub[0].usb_port[port].resume << 6
              | BX_USB_THIS hub[0].usb_port[port].line_dminus << 5
              | BX_USB_THIS hub[0].usb_port[port].line_dplus << 4
              | BX_USB_THIS hub[0].usb_port[port].able_changed << 3
              | BX_USB_THIS hub[0].usb_port[port].enabled << 2
              | BX_USB_THIS hub[0].usb_port[port].connect_changed << 1
              | BX_USB_THIS hub[0].usb_port[port].status;
        if (offset & 1) val >>= 8;
        break;
      } // else fall through to default
    default:
      val = 0xFF7F; // keep compiler happy
      BX_ERROR(("unsupported io read from address=0x%04x!", (unsigned) address));
      break;
  }

  BX_DEBUG(("register read from address 0x%04X:  0x%08X (%2i bits)", (unsigned) address, (Bit32u) val, io_len * 8));

  return(val);
}

// static IO port write callback handler
// redirects to non-static class handler to avoid virtual functions

void bx_pciusb_c::write_handler(void *this_ptr, Bit32u address, Bit32u value, unsigned io_len)
{
#if !BX_USE_PCIUSB_SMF
  bx_pciusb_c *class_ptr = (bx_pciusb_c *) this_ptr;
  class_ptr->write(address, value, io_len);
}

void bx_pciusb_c::write(Bit32u address, Bit32u value, unsigned io_len)
{
#else
  UNUSED(this_ptr);
#endif // !BX_USE_PCIUSB_SMF
  Bit8u  offset,port;

  BX_DEBUG(("register write to  address 0x%04X:  0x%08X (%2i bits)", (unsigned) address, (unsigned) value, io_len * 8));

  offset = address - BX_USB_THIS hub[0].base_ioaddr;

  switch (offset) {
    case 0x00: // command register (16-bit) (R/W)
      if (value & 0xFF00)
        BX_DEBUG(("write to command register with bits 15:8 not zero: 0x%04x", value));

      BX_USB_THIS hub[0].usb_command.max_packet_size = (value & 0x80) ? 1: 0;
      BX_USB_THIS hub[0].usb_command.configured = (value & 0x40) ? 1: 0;
      BX_USB_THIS hub[0].usb_command.debug = (value & 0x20) ? 1: 0;
      BX_USB_THIS hub[0].usb_command.resume = (value & 0x10) ? 1: 0;
      BX_USB_THIS hub[0].usb_command.suspend = (value & 0x08) ? 1: 0;
      BX_USB_THIS hub[0].usb_command.reset = (value & 0x04) ? 1: 0;
      BX_USB_THIS hub[0].usb_command.host_reset = (value & 0x02) ? 1: 0;
      BX_USB_THIS hub[0].usb_command.schedule = (value & 0x01) ? 1: 0;

      // HCRESET
      if (BX_USB_THIS hub[0].usb_command.host_reset) {
        BX_USB_THIS reset(0);
        for (unsigned i=0; i<USB_NUM_PORTS; i++) {
          if (BX_USB_THIS hub[0].usb_port[i].status) {
            if (BX_USB_THIS hub[0].usb_port[i].device != NULL) {
              BX_USB_THIS usb_send_msg(BX_USB_THIS hub[0].usb_port[i].device, USB_MSG_RESET);
            }
          }
          BX_USB_THIS hub[0].usb_port[i].connect_changed = 1;
          BX_USB_THIS hub[0].usb_port[i].enabled = 0;
          BX_USB_THIS hub[0].usb_port[i].able_changed = 1;
        }
      }

      // If software set the GRESET bit, we need to send the reset to all USB.
      // The software should guarentee that the reset is for at least 10ms.
      // We hold the reset until software resets this bit
      if (BX_USB_THIS hub[0].usb_command.reset) {
        BX_USB_THIS global_reset = 1;
        BX_DEBUG(("Global Reset"));
      } else {
        // if software cleared the reset, then we need to reset the usb registers.
        if (BX_USB_THIS global_reset) {
          BX_USB_THIS global_reset = 0;
          unsigned int running = BX_USB_THIS hub[0].usb_command.schedule;
          BX_USB_THIS reset(0);
          BX_USB_THIS hub[0].usb_status.host_halted = (running) ? 1 : 0;
        }
      }

      // If Run/Stop, identify in log
      if (BX_USB_THIS hub[0].usb_command.schedule) {
        BX_USB_THIS hub[0].usb_status.host_halted = 0;
        BX_DEBUG(("Schedule bit set in Command register"));
      } else {
        BX_USB_THIS hub[0].usb_status.host_halted = 1;
        BX_DEBUG(("Schedule bit clear in Command register"));
      }

      // If Debug mode set, panic.  Not implemented
      if (BX_USB_THIS hub[0].usb_command.debug)
        BX_PANIC(("Software set DEBUG bit in Command register. Not implemented"));

      break;

    case 0x02: // status register (16-bit) (R/WC)
      if (value & 0xFFC0)
        BX_DEBUG(("write to status register with bits 15:6 not zero: 0x%04x", value));

      // host_halted, even though not specified in the specs, is read only
      //BX_USB_THIS hub[0].usb_status.host_halted = (value & 0x20) ? 0: BX_USB_THIS hub[0].usb_status.host_halted;
      BX_USB_THIS hub[0].usb_status.host_error = (value & 0x10) ? 0: BX_USB_THIS hub[0].usb_status.host_error;
      BX_USB_THIS hub[0].usb_status.pci_error = (value & 0x08) ? 0: BX_USB_THIS hub[0].usb_status.pci_error;
      BX_USB_THIS hub[0].usb_status.resume = (value & 0x04) ? 0: BX_USB_THIS hub[0].usb_status.resume;
      BX_USB_THIS hub[0].usb_status.error_interrupt = (value & 0x02) ? 0: BX_USB_THIS hub[0].usb_status.error_interrupt;
      BX_USB_THIS hub[0].usb_status.interrupt = (value & 0x01) ? 0: BX_USB_THIS hub[0].usb_status.interrupt;
      break;

    case 0x04: // interrupt enable register (16-bit)
      if (value & 0xFFF0)
        BX_DEBUG(("write to interrupt enable register with bits 15:4 not zero: 0x%04x", value));

      BX_USB_THIS hub[0].usb_enable.short_packet  = (value & 0x08) ? 1: 0;
      BX_USB_THIS hub[0].usb_enable.on_complete  = (value & 0x04) ? 1: 0;
      BX_USB_THIS hub[0].usb_enable.resume  = (value & 0x02) ? 1: 0;
      BX_USB_THIS hub[0].usb_enable.timeout_crc = (value & 0x01) ? 1: 0;

      if (value & 0x08) {
        BX_DEBUG(("Host set Enable Interrupt on Short Packet"));
      }
      if (value & 0x04) {
        BX_DEBUG(("Host set Enable Interrupt on Complete"));
      }
      if (value & 0x02) {
        BX_DEBUG(("Host set Enable Interrupt on Resume"));
      }
      break;

    case 0x06: // frame number register (16-bit)
      if (value & 0xF800)
        BX_DEBUG(("write to frame number register with bits 15:11 not zero: 0x%04x", value));

      if (BX_USB_THIS hub[0].usb_status.host_halted)
        BX_USB_THIS hub[0].usb_frame_num.frame_num = (value & 0x07FF);
      else
        // ignored by the hardward, but lets report it anyway
        BX_DEBUG(("write to frame number register with STATUS.HALTED == 0"));
      break;

    case 0x08: // frame base register (32-bit)
      if (value & 0xFFF)
        BX_PANIC(("write to frame base register with bits 11:0 not zero: 0x%08x", value));

      BX_USB_THIS hub[0].usb_frame_base.frame_base = (value & ~0xfff);
      break;

    case 0x0C: // start of Frame Modify register (8-bit)
      if (value & 0x80)
        BX_DEBUG(("write to SOF Modify register with bit 7 not zero: 0x%04x", value));

       BX_USB_THIS hub[0].usb_sof.sof_timing = value;
       break;

    case 0x14: // port #3 non existant, but linux systems check it to see if there are more than 2
      BX_ERROR(("write to non existant offset 0x14 (port #3)"));
      break;

    case 0x10: // port #1
    case 0x12: // port #2
      port = (offset & 0x0F) >> 1;
      if ((port < USB_NUM_PORTS) && (io_len == 2)) {
        // If the ports reset bit is set, don't allow any writes unless the new write will clear the reset bit
        if (BX_USB_THIS hub[0].usb_port[port].reset & (value & (1<<9)))
          break;
        if (value & ((1<<5) | (1<<4) | (1<<0)))
          BX_DEBUG(("write to one or more read-only bits in port #%d register: 0x%04x", port+1, value));
        if (!(value & (1<<7)))
          BX_DEBUG(("write to port #%d register bit 7 = 0", port+1));
        if (value & (1<<8))
          BX_DEBUG(("write to bit 8 in port #%d register ignored", port+1));
        if ((value & (1<<12)) && BX_USB_THIS hub[0].usb_command.suspend)
          BX_DEBUG(("write to port #%d register bit 12 when in Global-Suspend", port+1));

        BX_USB_THIS hub[0].usb_port[port].suspend = (value & (1<<12)) ? 1 : 0;
        BX_USB_THIS hub[0].usb_port[port].reset = (value & (1<<9)) ? 1 : 0;
        BX_USB_THIS hub[0].usb_port[port].resume = (value & (1<<6)) ? 1 : 0;
        if (!BX_USB_THIS hub[0].usb_port[port].enabled && (value & (1<<2)))
          BX_USB_THIS hub[0].usb_port[port].able_changed = 0;
        else
          BX_USB_THIS hub[0].usb_port[port].able_changed = (value & (1<<3)) ? 0 : BX_USB_THIS hub[0].usb_port[port].able_changed;
        BX_USB_THIS hub[0].usb_port[port].enabled = (value & (1<<2)) ? 1 : 0;
        BX_USB_THIS hub[0].usb_port[port].connect_changed = (value & (1<<1)) ? 0 : BX_USB_THIS hub[0].usb_port[port].connect_changed;

        // if port reset, reset function(s)
        //TODO: only reset items on the downstream...
        // for now, reset the one and only
        // TODO: descriptors, etc....
        if (BX_USB_THIS hub[0].usb_port[port].reset) {
          BX_USB_THIS hub[0].usb_port[port].suspend = 0;
          BX_USB_THIS hub[0].usb_port[port].resume = 0;
          BX_USB_THIS hub[0].usb_port[port].enabled = 0;
          // are we are currently connected/disconnected
          if (BX_USB_THIS hub[0].usb_port[port].status) {
            if (BX_USB_THIS hub[0].usb_port[port].device != NULL) {
              BX_USB_THIS hub[0].usb_port[port].low_speed =
                (BX_USB_THIS hub[0].usb_port[port].device->get_speed() == USB_SPEED_LOW);
              usb_set_connect_status(port, BX_USB_THIS hub[0].usb_port[port].device->get_type(), 1);
              BX_USB_THIS usb_send_msg(BX_USB_THIS hub[0].usb_port[port].device, USB_MSG_RESET);
            }
          }
          BX_INFO(("Port%d: Reset", port+1));
        }
        break;
      }
      // else fall through to default
    default:
      BX_ERROR(("unsupported io write to address=0x%04x!", (unsigned) address));
      break;
  }
}

void bx_pciusb_c::usb_timer_handler(void *this_ptr)
{
  bx_pciusb_c *class_ptr = (bx_pciusb_c *) this_ptr;
  class_ptr->usb_timer();
}

// Called once every 1ms
#define USB_STACK_SIZE  256
void bx_pciusb_c::usb_timer(void)
{
  int i;

  // If the "global reset" bit was set by software
  if (BX_USB_THIS global_reset) {
    for (i=0; i<USB_NUM_PORTS; i++) {
      BX_USB_THIS hub[0].usb_port[i].able_changed = 0;
      BX_USB_THIS hub[0].usb_port[i].connect_changed = 0;
      BX_USB_THIS hub[0].usb_port[i].enabled = 0;
      BX_USB_THIS hub[0].usb_port[i].line_dminus = 0;
      BX_USB_THIS hub[0].usb_port[i].line_dplus = 0;
      BX_USB_THIS hub[0].usb_port[i].low_speed = 0;
      BX_USB_THIS hub[0].usb_port[i].reset = 0;
      BX_USB_THIS hub[0].usb_port[i].resume = 0;
      BX_USB_THIS hub[0].usb_port[i].status = 0;
      BX_USB_THIS hub[0].usb_port[i].suspend = 0;
    }
    return;
  }

  // If command.schedule = 1, then run schedule
  //  *** This assumes that we can complete the frame within the 1ms time allowed ***
  // Actually, not complete, but reach the end of the frame.  This means that there may still
  //  be TDs and QHs that were BREADTH defined and will be executed on the next cycle/iteration.

  if (BX_USB_THIS busy) {
    BX_PANIC(("Did not complete last frame before the 1ms was over. Starting next frame."));
    BX_USB_THIS busy = 0;
  }
  if (BX_USB_THIS hub[0].usb_command.schedule) {
    BX_USB_THIS busy = 1;
    bx_bool fire_int = 0;
    set_irq_level(0);  // make sure it is low
    bx_bool interrupt = 0, shortpacket = 0, stalled = 0;
    struct TD td;
    struct HCSTACK stack[USB_STACK_SIZE+1];  // queue stack for this item only
    Bit32s stk = 0;
    Bit32u item, address, lastvertaddr = 0, queue_num = 0;
    Bit32u frame, frm_addr = BX_USB_THIS hub[0].usb_frame_base.frame_base +
                                (BX_USB_THIS hub[0].usb_frame_num.frame_num << 2);
    DEV_MEM_READ_PHYSICAL(frm_addr, 4, (Bit8u*) &frame);
    if ((frame & 1) == 0) {
      stack[stk].next = (frame & ~0xF);
      stack[stk].d = 0;
      stack[stk].q = (frame & 0x0002) ? 1 : 0;
      stack[stk].t = 0;
      while (stk > -1) {

        // Linux seems to just loop a few queues together and wait for the 1ms to end.
        // We will just count the stack and exit when we get to a good point to stop.
        if (stk >= USB_STACK_SIZE) break;

        // check to make sure we are not done before continue-ing on
        if ((stack[stk].d == HC_VERT) && stack[stk].t) { stk--; continue; }
        if ((stack[stk].d == HC_HORZ) && stack[stk].t) break;
        if (stack[stk].q) { // is a queue
          address = stack[stk].next;
          lastvertaddr = address + 4;
          // get HORZ slot
          stk++;
          DEV_MEM_READ_PHYSICAL(address, 4, (Bit8u*) &item);
          stack[stk].next = item & ~0xF;
          stack[stk].d = HC_HORZ;
          stack[stk].q = (item & 0x0002) ? 1 : 0;
          stack[stk].t = (item & 0x0001) ? 1 : 0;
          // get VERT slot
          stk++;
          DEV_MEM_READ_PHYSICAL(lastvertaddr, 4, (Bit8u*) &item);
          stack[stk].next = item & ~0xF;
          stack[stk].d = HC_VERT;
          stack[stk].q = (item & 0x0002) ? 1 : 0;
          stack[stk].t = (item & 0x0001) ? 1 : 0;
          BX_DEBUG(("Queue %3i: 0x%08X %i %i  0x%08X %i %i", queue_num,
            stack[stk-1].next, stack[stk-1].q, stack[stk-1].t,
            stack[stk].next, stack[stk].q, stack[stk].t));
          queue_num++;
        } else {  // else is a TD
          address = stack[stk].next;
          DEV_MEM_READ_PHYSICAL(address,    4, (Bit8u*) &td.dword0);
          DEV_MEM_READ_PHYSICAL(address+4,  4, (Bit8u*) &td.dword1);
          DEV_MEM_READ_PHYSICAL(address+8,  4, (Bit8u*) &td.dword2);
          DEV_MEM_READ_PHYSICAL(address+12, 4, (Bit8u*) &td.dword3);
          bx_bool spd = (td.dword1 & (1<<29)) ? 1 : 0;
          stack[stk].next = td.dword0 & ~0xF;
          bx_bool depthbreadth = (td.dword0 & 0x0004) ? 1 : 0;     // 1 = depth first, 0 = breadth first
          stack[stk].q = (td.dword0 & 0x0002) ? 1 : 0;
          stack[stk].t = (td.dword0 & 0x0001) ? 1 : 0;
          if (td.dword1 & (1<<24)) interrupt = 1;
          if (td.dword1 & (1<<23)) {  // is it an active TD
            BX_DEBUG(("Frame: %04i (0x%04X)", BX_USB_THIS hub[0].usb_frame_num.frame_num, BX_USB_THIS hub[0].usb_frame_num.frame_num));
            if (BX_USB_THIS DoTransfer(address, queue_num, &td)) {
              // issue short packet?
              Bit16u r_actlen = (((td.dword1 & 0x7FF)+1) & 0x7FF);
              Bit16u r_maxlen = (((td.dword2>>21)+1) & 0x7FF);
              BX_DEBUG((" r_actlen = 0x%04X r_maxlen = 0x%04X", r_actlen, r_maxlen));
              if (((td.dword2 & 0xFF) == USB_TOKEN_IN) && spd && stk && (r_actlen < r_maxlen) && ((td.dword1 & 0x00FF0000) == 0)) {
                shortpacket = 1;
                td.dword1 |= (1<<29);
              }
              if (td.dword1 & (1<<22)) stalled = 1;

              DEV_MEM_WRITE_PHYSICAL(address+4, 4, (Bit8u*) &td.dword1);  // write back the status
              // copy pointer for next queue item, in to vert queue head
              if ((stk > 0) && !shortpacket && (stack[stk].d == HC_VERT))
                DEV_MEM_WRITE_PHYSICAL(lastvertaddr, 4, (Bit8u*) &td.dword0);
            }
          }

          if (stk > 0) {
            // if last TD in HORZ queue pointer, then we are done.
            if (stack[stk].t && (stack[stk].d == HC_HORZ)) break;
            // if Breadth first or last item in queue, move to next queue.
            if (!depthbreadth || stack[stk].t) {
              if (stack[stk].d == HC_HORZ) queue_num--;  // <-- really, this should never happen until we
              stk--;                                     //           support bandwidth reclamation...
            }
            if (stk < 1) break;
          } else {
            if (stack[stk].t) break;
          }

        }
      }

      // set the status register bit:0 to 1 if SPD is enabled
      // and if interrupts not masked via interrupt register, raise irq interrupt.
      if (shortpacket && BX_USB_THIS hub[0].usb_enable.short_packet) {
        fire_int = 1;
        BX_DEBUG((" [SPD] We want it to fire here (Frame: %04i)", BX_USB_THIS hub[0].usb_frame_num.frame_num));
      }

      // if one of the TD's in this frame had the ioc bit set, we need to
      //   raise an interrupt, if interrupts are not masked via interrupt register.
      //   always set the status register if IOC.
      if (interrupt && BX_USB_THIS hub[0].usb_enable.on_complete) {
        fire_int = 1;
        BX_DEBUG((" [IOC] We want it to fire here (Frame: %04i)", BX_USB_THIS hub[0].usb_frame_num.frame_num));
      }

      if (stalled && BX_USB_THIS hub[0].usb_enable.timeout_crc) {
        fire_int = 1;
        BX_DEBUG((" [stalled] We want it to fire here (Frame: %04i)", BX_USB_THIS hub[0].usb_frame_num.frame_num));
      }
    }

    // The Frame Number Register is incremented every 1ms
    BX_USB_THIS hub[0].usb_frame_num.frame_num++;
    BX_USB_THIS hub[0].usb_frame_num.frame_num &= (1024-1);

    // if we needed to fire an interrupt now, lets do it *after* we increment the frame_num register
    if (fire_int) {
      BX_USB_THIS hub[0].usb_status.interrupt = 1;
      BX_USB_THIS hub[0].usb_status.error_interrupt = stalled;
      set_irq_level(1);
    }

    BX_USB_THIS busy = 0;  // ready to do next frame item
  }  // end run schedule

  // if host turned off the schedule, set the halted bit in the status register
  // Note: Can not use an else from the if() above since the host can changed this bit
  //  while we are processing a frame.
  if (BX_USB_THIS hub[0].usb_command.schedule == 0)
    BX_USB_THIS hub[0].usb_status.host_halted = 1;

  // TODO:
  //  If in Global_Suspend mode and any of usb_port[i] bits 6,3, or 1 are set,
  //    we need to issue a Global_Resume (set the global resume bit).
  //    However, since we don't do anything, let's not.
}

bx_bool bx_pciusb_c::DoTransfer(Bit32u address, Bit32u queue_num, struct TD *td) {

  int i, len = 0, ret = 0;
  usb_device_t *dev = NULL;

  Bit16u maxlen = (td->dword2 >> 21);
  Bit8u  addr   = (td->dword2 >> 8) & 0x7F;
  Bit8u  endpt  = (td->dword2 >> 15) & 0x0F;
  Bit8u  pid    =  td->dword2 & 0xFF;

  BX_DEBUG(("QH%03i:TD found at address: 0x%08X", queue_num, address));
  BX_DEBUG(("  %08X   %08X   %08X   %08X", td->dword0, td->dword1, td->dword2, td->dword3));

  // check TD to make sure it is valid
  // A max length 0x500 to 0x77E is illegal
  if (((td->dword2 >> 21) >= 0x500) && ((td->dword2 >> 21) != 0x7FF)) {
    BX_ERROR(("error at 11111111111"));
    return 1;  // error = consistency check failure
  }

  //if (td->dword0 & 0x8) return 1; // error = reserved bits in dword0 set
  // other error checks here

  // find device address
  bx_bool at_least_one = 0;
  for (i=0; i<USB_NUM_PORTS; i++) {
    if (BX_USB_THIS hub[0].usb_port[i].device != NULL) {
      if (BX_USB_THIS hub[0].usb_port[i].device->get_connected()) {
        at_least_one = 1;
        if (BX_USB_THIS hub[0].usb_port[i].device->get_address() == addr) {
          dev = BX_USB_THIS hub[0].usb_port[i].device;
          break;
        }
      }
    }
  }
  if (!at_least_one) {
    BX_USB_THIS set_status(td, 1, 0, 0, 0, (pid==USB_TOKEN_SETUP)?1:0, 0, 0x007); // an 8 byte packet was received, but stalled
    return 1;
  }
  if (dev == NULL) {
    if ((pid == USB_TOKEN_OUT) && (maxlen == 0x7FF) && (addr == 0)) {
      // This is the "keep awake" packet that Windows sends once a schedule cycle.
      // For now, let it pass through to the code below.
    } else {
      BX_PANIC(("Device not found for addr: %i", addr));
      BX_USB_THIS set_status(td, 1, 0, 0, 0, (pid==USB_TOKEN_SETUP)?1:0, 0, 0x007); // an 8 byte packet was received, but stalled
      return 1;  // device not found
    }
  }

  // the device should remain in a stall state until the next setup packet is recieved
  // For some reason, this doesn't work yet.
  //if (dev && dev->in_stall && (pid != USB_TOKEN_SETUP))
  //  return FALSE;

  maxlen++;
  maxlen &= 0x7FF;

  if (dev != NULL) {
    BX_USB_THIS usb_packet.pid = pid;
    BX_USB_THIS usb_packet.devaddr = addr;
    BX_USB_THIS usb_packet.devep = endpt;
    BX_USB_THIS usb_packet.data = device_buffer;
    BX_USB_THIS usb_packet.len = maxlen;
    switch (pid) {
      case USB_TOKEN_OUT:
      case USB_TOKEN_SETUP:
        if (maxlen > 0) {
          DEV_MEM_READ_PHYSICAL_BLOCK(td->dword3, maxlen, device_buffer);
        }
        ret = dev->handle_packet(&BX_USB_THIS usb_packet);
        len = maxlen;
        break;
      case USB_TOKEN_IN:
        ret = dev->handle_packet(&BX_USB_THIS usb_packet);
        if (ret >= 0) {
          len = ret;
          if (len > maxlen) {
            len = maxlen;
            ret = USB_RET_BABBLE;
          }
          if (len > 0) {
            DEV_MEM_WRITE_PHYSICAL_BLOCK(td->dword3, len, device_buffer);
          }
        } else {
          len = 0;
        }
        break;
      default:
        BX_USB_THIS hub[i].usb_status.host_error = 1;
        BX_USB_THIS set_irq_level(1);
    }
    if (ret >= 0) {
      BX_USB_THIS set_status(td, 0, 0, 0, 0, 0, 0, len-1);
    } else {
      BX_USB_THIS set_status(td, 1, 0, 0, 0, 0, 0, 0x007); // stalled
    }
    return 1;
  }
  return 0;
}

// If the request fails, set the stall bit ????
void bx_pciusb_c::set_status(struct TD *td, bx_bool stalled, bx_bool data_buffer_error, bx_bool babble,
                             bx_bool nak, bx_bool crc_time_out, bx_bool bitstuff_error, Bit16u act_len)
{
  // clear out the bits we can modify and/or want zero
  td->dword1 &= 0xDF00F800;

  // now set the bits according to the passed param's
  td->dword1 |= stalled           ? (1<<22) : 0; // stalled
  td->dword1 |= data_buffer_error ? (1<<21) : 0; // data buffer error
  td->dword1 |= babble            ? (1<<20) : 0; // babble
  td->dword1 |= nak               ? (1<<19) : 0; // nak
  td->dword1 |= crc_time_out      ? (1<<18) : 0; // crc/timeout
  td->dword1 |= bitstuff_error    ? (1<<17) : 0; // bitstuff error
  td->dword1 |= (act_len & 0x7FF);               // actual length
  if (stalled || data_buffer_error || babble || nak || crc_time_out || bitstuff_error)
    td->dword1 &= ~((1<<28) | (1<<27));  // clear the c_err field in there was an error
}

// pci configuration space read callback handler
Bit32u bx_pciusb_c::pci_read_handler(Bit8u address, unsigned io_len)
{
  Bit32u value = 0;

  if (io_len > 4 || io_len == 0) {
    BX_ERROR(("Experimental USB PCI read register 0x%02x, len=%u !",
             (unsigned) address, (unsigned) io_len));
    return 0xffffffff;
  }

  const char* pszName = "                  ";
  switch (address) {
    case 0x00: if (io_len == 2) {
                 pszName = "(vendor id)       ";
               } else if (io_len == 4) {
                 pszName = "(vendor + device) ";
               }
      break;
    case 0x04: if (io_len == 2) {
                 pszName = "(command)         ";
               } else if (io_len == 4) {
                 pszName = "(command+status)  ";
               }
      break;
    case 0x08: if (io_len == 1) {
                 pszName = "(revision id)     ";
               } else if (io_len == 4) {
                 pszName = "(rev.+class code) ";
               }
      break;
    case 0x0c: pszName = "(cache line size) "; break;
    case 0x20: pszName = "(base address)    "; break;
    case 0x28: pszName = "(cardbus cis)     "; break;
    case 0x2c: pszName = "(subsys. vendor+) "; break;
    case 0x30: pszName = "(rom base)        "; break;
    case 0x3c: pszName = "(interrupt line+) "; break;
    case 0x3d: pszName = "(interrupt pin)   "; break;
  }

  // This odd code is to display only what bytes actually were read.
  char szTmp[9];
  char szTmp2[3];
  szTmp[0] = '\0';
  szTmp2[0] = '\0';
  for (unsigned i=0; i<io_len; i++) {
    value |= (BX_USB_THIS hub[0].pci_conf[address+i] << (i*8));
    sprintf(szTmp2, "%02x", (BX_USB_THIS hub[0].pci_conf[address+i]));
    strrev(szTmp2);
    strcat(szTmp, szTmp2);
  }
  strrev(szTmp);
  BX_DEBUG(("USB PCI read  register 0x%02x %svalue 0x%s", address, pszName, szTmp));
  return value;
}


// pci configuration space write callback handler
void bx_pciusb_c::pci_write_handler(Bit8u address, Bit32u value, unsigned io_len)
{
  Bit8u value8, oldval;
  bx_bool baseaddr_change = 0;

  if (((address >= 0x10) && (address < 0x20)) ||
      ((address > 0x23) && (address < 0x34)))
    return;

  // This odd code is to display only what bytes actually were written.
  char szTmp[9];
  char szTmp2[3];
  szTmp[0] = '\0';
  szTmp2[0] = '\0';
  if (io_len <= 4) {
    for (unsigned i=0; i<io_len; i++) {
      value8 = (value >> (i*8)) & 0xFF;
      oldval = BX_USB_THIS hub[0].pci_conf[address+i];
      switch (address+i) {
        case 0x04:
          value8 &= 0x05;
          BX_USB_THIS hub[0].pci_conf[address+i] = value8;
          sprintf(szTmp2, "%02x", value8);
          break;
        case 0x3d: //
        case 0x3e: //
        case 0x3f: //
        case 0x05: // disallowing write to command hi-byte
        case 0x06: // disallowing write to status lo-byte (is that expected?)
          strcpy(szTmp2, "..");
          break;
        case 0x3c:
          if (value8 != oldval) {
            BX_INFO(("new irq line = %d", value8));
            BX_USB_THIS hub[0].pci_conf[address+i] = value8;
          }
          sprintf(szTmp2, "%02x", value8);
          break;
        case 0x20:
          value8 = (value8 & 0xfc) | 0x01;
        case 0x21:
        case 0x22:
        case 0x23:
          baseaddr_change |= (value8 != oldval);
        default:
          BX_USB_THIS hub[0].pci_conf[address+i] = value8;
          sprintf(szTmp2, "%02x", value8);
      }
      strrev(szTmp2);
      strcat(szTmp, szTmp2);
    }
    if (baseaddr_change) {
      if (DEV_pci_set_base_io(BX_USB_THIS_PTR, read_handler, write_handler,
                             &BX_USB_THIS hub[0].base_ioaddr,
                             &BX_USB_THIS hub[0].pci_conf[0x20],
                             32, &usb_iomask[0], "USB Hub #1")) {
         BX_INFO(("new base address: 0x%04x", BX_USB_THIS hub[0].base_ioaddr));
      }
    }
  }
  strrev(szTmp);
  BX_DEBUG(("USB PCI write register 0x%02x                   value 0x%s", address, szTmp));
}

bx_bool bx_pciusb_c::usb_mouse_enabled_changed(bx_bool enabled)
{
  if (BX_USB_THIS mousedev != NULL) {
    if (enabled) mousedev->handle_reset();
    return 1;
  }
  return 0;
}

void bx_pciusb_c::usb_set_connect_status(Bit8u port, int type, bx_bool connected)
{
  char pname[BX_PATHNAME_LEN];
  char fname[BX_PATHNAME_LEN];

  if (BX_USB_THIS hub[0].usb_port[port].device != NULL) {
    if (BX_USB_THIS hub[0].usb_port[port].device->get_type() == type) {
      if (connected) {
        if (!BX_USB_THIS hub[0].usb_port[port].device->get_connected()) {
          BX_USB_THIS hub[0].usb_port[port].low_speed =
            (BX_USB_THIS hub[0].usb_port[port].device->get_speed() == USB_SPEED_LOW);
        }
        if (BX_USB_THIS hub[0].usb_port[port].low_speed) {
          BX_USB_THIS hub[0].usb_port[port].line_dminus = 1;  //  dminus=1 & dplus=0 = low speed  (at idle time)
          BX_USB_THIS hub[0].usb_port[port].line_dplus = 0;   //  dminus=0 & dplus=1 = high speed (at idle time)
        } else {
          BX_USB_THIS hub[0].usb_port[port].line_dminus = 0;  //  dminus=1 & dplus=0 = low speed  (at idle time)
          BX_USB_THIS hub[0].usb_port[port].line_dplus = 1;   //  dminus=0 & dplus=1 = high speed (at idle time)
        }
        BX_USB_THIS hub[0].usb_port[port].status = 1;       //
        BX_USB_THIS hub[0].usb_port[port].connect_changed = 1;
        BX_USB_THIS hub[0].usb_port[port].able_changed = 1;

        // if in suspend state, signal resume
        if (BX_USB_THIS hub[0].usb_command.suspend) {
          BX_USB_THIS hub[0].usb_port[port].resume = 1;
          BX_USB_THIS hub[0].usb_status.resume = 1;
          if (BX_USB_THIS hub[0].usb_enable.resume) {
            BX_USB_THIS hub[0].usb_status.interrupt = 1;
            set_irq_level(1);
          }
        }

        if ((type == USB_DEV_TYPE_DISK) &&
            (!BX_USB_THIS hub[0].usb_port[port].device->get_connected())) {
          if (port == 0) {
            strcpy(pname, BXPN_USB1_PORT1);
          } else {
            strcpy(pname, BXPN_USB1_PORT2);
          }
          strcpy(fname, SIM->get_param_string(pname)->getptr() + 5);
          if (!((usb_msd_device_t*)BX_USB_THIS hub[0].usb_port[port].device)->init(fname)) {
            usb_set_connect_status(port, USB_DEV_TYPE_DISK, 0);
          } else {
            BX_INFO(("HD on USB port #%d: '%s'", port+1, fname));
          }
        }
      } else {
        BX_USB_THIS hub[0].usb_port[port].status = 0;
        BX_USB_THIS hub[0].usb_port[port].connect_changed = 1;
        BX_USB_THIS hub[0].usb_port[port].enabled = 0;
        BX_USB_THIS hub[0].usb_port[port].able_changed = 1;
        BX_USB_THIS hub[0].usb_port[port].low_speed = 0;
        BX_USB_THIS hub[0].usb_port[port].line_dminus = 0;  //  dminus=1 & dplus=0 = low speed  (at idle time)
        BX_USB_THIS hub[0].usb_port[port].line_dplus = 0;   //  dminus=0 & dplus=1 = high speed (at idle time)
        if ((type == USB_DEV_TYPE_MOUSE) ||
            (type == USB_DEV_TYPE_TABLET)) {
          if (BX_USB_THIS hub[0].usb_port[port].device == BX_USB_THIS mousedev) {
            BX_USB_THIS mousedev = NULL;
          }
        } else if (type == USB_DEV_TYPE_KEYPAD) {
          if (BX_USB_THIS hub[0].usb_port[port].device == BX_USB_THIS keybdev) {
            BX_USB_THIS keybdev = NULL;
          }
        }
        if (BX_USB_THIS hub[0].usb_port[port].device != NULL) {
          delete BX_USB_THIS hub[0].usb_port[port].device;
          BX_USB_THIS hub[0].usb_port[port].device = NULL;
          sprintf(pname, "pciusb.hub1.port%d.device", port+1);
          bx_list_c *devlist = (bx_list_c*)SIM->get_param(pname, SIM->get_bochs_root());
          devlist->clear();
        }
      }
    }
  }
}

bx_bool bx_pciusb_c::usb_mouse_enq(int delta_x, int delta_y, int delta_z, unsigned button_state)
{
  if (BX_USB_THIS mousedev != NULL) {
    mousedev->mouse_enq(delta_x, delta_y, delta_z, button_state);
    return 1;
  }
  return 0;
}

bx_bool bx_pciusb_c::usb_key_enq(Bit8u *scan_code)
{
  if (BX_USB_THIS keybdev != NULL) {
    return keybdev->key_enq(scan_code);
  }
  return 0;
}

// Send an internal message to a USB device
void bx_pciusb_c::usb_send_msg(usb_device_t *dev, int msg)
{
    USBPacket p;
    memset(&p, 0, sizeof(p));
    p.pid = msg;
    dev->handle_packet(&p);
}

// USB runtime parameter handler
const char *bx_pciusb_c::usb_param_handler(bx_param_string_c *param, int set,
                                           const char *oldval, const char *val, int maxlen)
{
  usbdev_type type = USB_DEV_TYPE_NONE;

  // handler for USB runtime parameters
  if (set) {
    char pname[BX_PATHNAME_LEN];
    param->get_param_path(pname, BX_PATHNAME_LEN);
    if (!strcmp(pname, BXPN_USB1_PORT1)) {
      BX_INFO(("USB port #1 experimental device change"));
      if (!strcmp(val, "none") && BX_USB_THIS hub[0].usb_port[0].status) {
        if (BX_USB_THIS hub[0].usb_port[0].device != NULL) {
          type = BX_USB_THIS hub[0].usb_port[0].device->get_type();
        }
        usb_set_connect_status(0, type, 0);
      } else if (strcmp(val, "none") && !BX_USB_THIS hub[0].usb_port[0].status) {
        init_device(0, val);
      }
    } else if (!strcmp(pname, BXPN_USB1_PORT2)) {
      BX_INFO(("USB port #2 experimental device change"));
      if (!strcmp(val, "none") && BX_USB_THIS hub[0].usb_port[1].status) {
        if (BX_USB_THIS hub[0].usb_port[1].device != NULL) {
          type = BX_USB_THIS hub[0].usb_port[1].device->get_type();
        }
        usb_set_connect_status(1, type, 0);
      } else if (strcmp(val, "none") && !BX_USB_THIS hub[0].usb_port[1].status) {
        init_device(1, val);
      }
    } else {
      BX_PANIC(("usb_param_handler called with unexpected parameter '%s'", pname));
    }
  }
  return val;
}

#endif // BX_SUPPORT_PCI && BX_SUPPORT_PCIUSB