[bachelor-thesis/roomba_tests.git] / main.cc

/**
 * @file main.cc
 * @date 27 Nov 2010
 * Copyright © 2010 Roland Hieber
 *
 * Permission is hereby granted, free of charge, to any person obtaining
 * copy of this software and associated documentation files (the "Software"),
 * to deal in the Software without restriction, including without limitation
 * the rights to use, copy, modify, merge, publish, distribute, sublicense,
 * and/or sell copies of the Software, and to permit persons to whom the
 * Software is furnished to do so, subject to the following conditions:
 *
 * The above copyright notice and this permission notice shall be included in
 * all copies or substantial portions of the Software.
 *
 * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
 * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
 * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
 * AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
 * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
 * OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
 * THE SOFTWARE.
 */

#include "svnrevision.h"
#include <iostream>
#include <stdint.h>
#include <external_interface/pc/pc_os_model.h>
#include <external_interface/pc/pc_com_uart.h>
#include <external_interface/pc/pc_timer.h>
#include <intermediate/robot/roomba/roomba.h>
#include <intermediate/robot/controlled_motion.h>
#include <QApplication>
#include <QInputDialog>

using namespace std;

#if QT_VERSION < 0x040500
#define getInt QInputDialog::getInteger
#else // QT_VERSION > 0x040500
#define getInt QInputDialog::getInt
#endif // QT_VERSION
// UART port on which we communicate with the Roomba
char uart[] = "/dev/ttyUSB0";

typedef wiselib::PCOsModel OsModel;
typedef wiselib::StandaloneMath Math;
typedef wiselib::PCComUartModel<OsModel, uart> RoombaUart;
typedef wiselib::RoombaModel<OsModel, RoombaUart> Roomba;
typedef wiselib::ControlledMotion<OsModel, Roomba> ControlledMotion;

/**
 * Global stuff we need
 */
OsModel::Os os;
OsModel::Timer::self_t timer;
Roomba roomba;
RoombaUart roomba_uart(os);
ControlledMotion ctrl_motion;
char * roomba_id;
char * ground_type;

/**
 * Sensor data we need, filled in callback
 */
struct SensorData {

  SensorData() :
    capacity(0), charge(0), charging(0), current(0), temperature(0),
      voltage(0), diff_left_ticks(0), diff_right_ticks(0) {
  }

  uint16_t capacity, charge;
  uint8_t charging;
  int16_t current;
  int8_t temperature;
  uint16_t voltage;
  /** raw encoder counts; i.e. overflown, not consecutive */
  int raw_left_ticks, raw_right_ticks;
  /** absolute encoder counts; i.e. not overflown, but consecutive */
  int diff_left_ticks, diff_right_ticks;
} sensor_data;

/**
 * Returns the difference between two unsigned short values. The calculated
 * value is always smaller or equal to 0x8000.
 * This is useful if you have an overflowing counter and you want to determine
 * when you have to "wrap over" the value.
 */
int nearestDiff(unsigned short last, unsigned short current) {
  int d = current - last;
  if(d < -0x8000) { // overflow in positive direction
    d = (0x10000 - last + current);
  }
  if(d >= 0x8000) { // overflow in negative direction
    d = -(0x10000 - current + last);
  }
}

/**
 * Callback that fills the sensor data when data is available
 */
struct DataAvailable {
  int latest_ticks_left_, latest_ticks_right_;

  DataAvailable() :
    latest_ticks_left_(0), latest_ticks_right_(0) {
  }

  void cb(int state) {
    if(state != Roomba::DATA_AVAILABLE) {
      return;
    }
    sensor_data.capacity = roomba().capacity;
    sensor_data.charge = roomba().charge;
    sensor_data.charging = roomba().charging;
    sensor_data.current = roomba().current;
    sensor_data.voltage = roomba().voltage;
    sensor_data.raw_left_ticks = roomba().left_encoder_counts;
    sensor_data.raw_right_ticks = roomba().right_encoder_counts;
    sensor_data.diff_left_ticks += nearestDiff(latest_ticks_left_,
      roomba().left_encoder_counts);
    latest_ticks_left_ = roomba().left_encoder_counts;
    sensor_data.diff_right_ticks += nearestDiff(latest_ticks_right_,
      roomba().right_encoder_counts);
    latest_ticks_right_ = roomba().right_encoder_counts;
  }
} data_available;

/**
 * return battery status as QString
 */
QString chargeText() {
  return QString("Battery: %1%\nPress Cancel to exit.\n\n").arg(int(float(
    sensor_data.charge) / float(sensor_data.capacity) * 100.0));
}

/**
 * return log text for global values
 */
QString logText() {
  return QString("svn=%1 roomba_id=%2 ground_type=%3 diff_left_ticks=%4 "
    "diff_right_ticks=%5 raw_ticks_left=%6 raw_ticks_right=%7 batt_charge=%8 "
    "batt_capacity=%9 batt_voltage=%10 batt_current=%11").arg(SVNREVISION).arg(
    roomba_id).arg(ground_type).arg(sensor_data.diff_left_ticks).arg(
    sensor_data.diff_right_ticks).arg(sensor_data.raw_left_ticks).arg(
    sensor_data.raw_right_ticks).arg(sensor_data.charge).arg(
    sensor_data.capacity).arg(sensor_data.voltage).arg(sensor_data.current);
}

/**
 * drive iterations. logs values to stdout.
 */
void drive(Roomba& roomba, ControlledMotion& ctrl_motion) {
  int input_distance = 0, deviation_x = 0, deviation_y = 0, velocity = 100;
  bool ok = false;

  while(true) {

    // new distance to drive
    input_distance = getInt(0, "Input distance", chargeText()
      + "Input new distance in mm:", input_distance,
      numeric_limits<int>::min(), numeric_limits<int>::max(), 1, &ok);
    if(!ok) {
      break;
    }
    // new velocity
    velocity = getInt(0, "Input velocity", chargeText()
      + "Input drive velocity in mm/sec:", velocity, -500, 500, 10, &ok);
    if(!ok) {
      break;
    }
    ctrl_motion.move_distance(input_distance, velocity);
    roomba.wait_for_stop();

    // measured deviation
    deviation_x = getInt(0, "Input x deviation", chargeText()
      + "Input travelled distance on x axis in mm:", deviation_x,
      numeric_limits<int>::min(), numeric_limits<int>::max(), 1, &ok);
    if(!ok) {
      break;
    }
    deviation_y = getInt(0, "Input y deviation", chargeText()
      + "Input travelled distance on y axis in mm:", deviation_y,
      numeric_limits<int>::min(), numeric_limits<int>::max(), 1, &ok);
    if(!ok) {
      break;
    }
    cout << logText().toAscii().constData() << " move=straight input_distance="
      << input_distance << " velocity=" << velocity << " internal_distance="
      << roomba.distance() << " deviation_x=" << deviation_x << " deviation_y="
      << deviation_y << endl;

    // reset, because we only need the difference between two drive commands
    sensor_data.diff_left_ticks = 0;
    sensor_data.diff_right_ticks = 0;
  }
}

/**
 * turn iterations. logs values to stdout.
 */
void turn(Roomba& roomba, ControlledMotion& ctrl_motion) {
  int cur_angle = 0, turn_angle = 0, measured_angle = 0, velocity = 100;
  bool ok = false;

  // current angle
  cur_angle = getInt(0, "Input current orientation", chargeText()
    + "Input current orientation in degree:", cur_angle, 0, 359, 1, &ok);
  if(!ok) {
    return;
  }

  while(true) {
    // new turn velocity
    velocity = getInt(0, "Input velocity", chargeText()
      + "Input turn velocity in mm/sec:", velocity, -500, 500, 10, &ok);
    if(!ok) {
      break;
    }

    // angle to turn about
    turn_angle = getInt(0, "Input turn angle", chargeText()
      + "Input angle in degree to turn about:", turn_angle,
      numeric_limits<int>::min() + 360, numeric_limits<int>::max() - 360, 1,
      &ok);
    if(!ok) {
      break;
    }

    ctrl_motion.turn_about(Math::degrees_to_radians(turn_angle), velocity);
    roomba.wait_for_stop();

    // new current angle
    measured_angle = getInt(0, "Input measured angle", chargeText() + QString(
      "Orientation should be %1 degree now.\n\n").arg((cur_angle + turn_angle)
      % 360) + "Input measured angle in degree the Roomba has "
      "turned:", turn_angle, 0, numeric_limits<int>::max(), 1, &ok);
    if(!ok) {
      break;
    }

    cout << logText().toAscii().constData() << " move=turn turn_angle="
      << turn_angle << " measured_angle=" << measured_angle << " velocity="
      << velocity << " internal_angle=" << roomba.angle() << endl;

    // reset, because we only need the difference between two turns
    sensor_data.diff_left_ticks = 0;
    sensor_data.diff_right_ticks = 0;

    // new orientation
    cur_angle = (cur_angle + measured_angle) % 360;
  }
}

/**
 * main function
 */
int main(int argc, char ** argv) {

  if(argc < 4) {
    cerr << "Usage: " << argv[0]
      << " --turn|-t|--drive|-d roomba-id ground-type" << endl;
    exit(-1);
  }

  // init stuff
  QApplication app(argc, argv);

  roomba_uart.set_baudrate(19200);
  roomba_uart.enable_serial_comm();
  roomba.init(roomba_uart, timer, Roomba::POSITION
    | Roomba::BATTERY_AND_TEMPERATURE);

  cerr << "Got roomba at " << roomba_uart.address() << endl;

  roomba.reset_distance();
  roomba.reset_angle();
  ctrl_motion.init(roomba);

  // we do not want the probably corrupted data from roomba(), instead we fill
  // our own values when data is available
  roomba.register_state_callback<DataAvailable, &DataAvailable::cb> (
    &data_available);

  // fill it once
  roomba.notify_state_receivers(Roomba::DATA_AVAILABLE);

  // actual tests
  roomba_id = argv[2];
  ground_type = argv[3];
  if(strcmp(argv[1], "--turn") == 0 || strcmp(argv[1], "-t") == 0) {
    turn(roomba, ctrl_motion);
  } else if(strcmp(argv[1], "--drive") == 0 || strcmp(argv[1], "-d") == 0) {
    drive(roomba, ctrl_motion);
  }
}