static void
SetVSpeed(InfoBoxData &data, fixed value)
{
TCHAR buffer[32];
FormatUserVerticalSpeed(value, buffer, false);
data.SetValue(buffer[0] == _T('+') ? buffer + 1 : buffer);
data.SetValueUnit(Units::current.vertical_speed_unit);
}
void
InfoBoxContentTemperatureForecast::Update(InfoBoxData &data)
{
auto temperature = CommonInterface::GetComputerSettings().forecast_temperature;
data.SetValue(_T("%2.1f"), temperature.ToUser());
data.SetValueUnit(Units::current.temperature_unit);
}
void
UpdateInfoBoxTaskSpeedHour(InfoBoxData &data)
{
const WindowStats &window =
CommonInterface::Calculated().task_stats.last_hour;
if (negative(window.duration)) {
data.SetInvalid();
return;
}
data.SetValue(_T("%2.0f"), Units::ToUserTaskSpeed(window.speed));
data.SetValueUnit(Units::current.task_speed_unit);
}
void
UpdateInfoBoxTemperature(InfoBoxData &data)
{
const NMEAInfo &basic = CommonInterface::Basic();
if (!basic.temperature_available) {
data.SetInvalid();
return;
}
// Set Value
data.SetValue(_T("%2.1f"), basic.temperature.ToUser());
data.SetValueUnit(Units::current.temperature_unit);
}
void
InfoBoxContentTemperature::Update(InfoBoxData &data)
{
const NMEAInfo &basic = XCSoarInterface::Basic();
if (!basic.temperature_available) {
data.SetInvalid();
return;
}
// Set Value
data.SetValue(_T("%2.1f"),
Units::ToUserTemperature(basic.temperature));
data.SetValueUnit(Units::current.temperature_unit);
}
void
UpdateInfoBoxHeadWind(InfoBoxData &data)
{
const DerivedInfo &info = CommonInterface::Calculated();
if (!info.head_wind_available) {
data.SetInvalid();
return;
}
// Set Value
data.SetValue(_T("%2.0f"),
Units::ToUserWindSpeed(info.head_wind));
// Set Unit
data.SetValueUnit(Units::current.wind_speed_unit);
}
void
UpdateInfoBoxTaskSpeedInstant(InfoBoxData &data)
{
const TaskStats &task_stats = CommonInterface::Calculated().task_stats;
if (!task_stats.task_valid || !task_stats.IsPirkerSpeedAvailable()) {
data.SetInvalid();
return;
}
// Set Value
data.SetValue(_T("%2.0f"),
Units::ToUserTaskSpeed(task_stats.get_pirker_speed()));
// Set Unit
data.SetValueUnit(Units::current.task_speed_unit);
}
void
InfoBoxContentTaskSpeedInstant::Update(InfoBoxData &data)
{
const TaskStats &task_stats = XCSoarInterface::Calculated().task_stats;
if (!task_stats.task_valid || !task_stats.IsPirkerSpeedAvailable()) {
data.SetInvalid();
return;
}
// Set Value
SetValueFromFixed(data, _T("%2.0f"),
Units::ToUserTaskSpeed(task_stats.get_pirker_speed()));
// Set Unit
data.SetValueUnit(Units::current.task_speed_unit);
}
void
InfoBoxContentTaskSpeed::Update(InfoBoxData &data)
{
const TaskStats &task_stats = XCSoarInterface::Calculated().task_stats;
if (!task_stats.task_valid || !task_stats.total.travelled.IsDefined()) {
data.SetInvalid();
return;
}
// Set Value
SetValueFromFixed(data, _T("%2.0f"),
Units::ToUserTaskSpeed(task_stats.total.travelled.get_speed()));
// Set Unit
data.SetValueUnit(Units::current.task_speed_unit);
}
void
UpdateInfoBoxTaskSpeed(InfoBoxData &data)
{
const TaskStats &task_stats = CommonInterface::Calculated().task_stats;
if (!task_stats.task_valid || !task_stats.total.travelled.IsDefined()) {
data.SetInvalid();
return;
}
// Set Value
data.SetValue(_T("%2.0f"),
Units::ToUserTaskSpeed(task_stats.total.travelled.GetSpeed()));
// Set Unit
data.SetValueUnit(Units::current.task_speed_unit);
}
void
UpdateInfoBoxHeadWindSimplified(InfoBoxData &data)
{
const NMEAInfo &basic = CommonInterface::Basic();
if (!basic.ground_speed_available || !basic.airspeed_available) {
data.SetInvalid();
return;
}
fixed value = basic.true_airspeed - basic.ground_speed;
// Set Value
data.SetValue(_T("%2.0f"), Units::ToUserWindSpeed(value));
// Set Unit
data.SetValueUnit(Units::current.wind_speed_unit);
}
void
InfoBoxContentTaskSpeedAchieved::Update(InfoBoxData &data)
{
const TaskStats &task_stats = XCSoarInterface::Calculated().task_stats;
if (!task_stats.task_valid ||
!task_stats.total.remaining_effective.IsDefined()) {
data.SetInvalid();
return;
}
// Set Value
data.SetValue(_T("%2.0f"),
Units::ToUserTaskSpeed(task_stats.total.remaining_effective.get_speed()));
// Set Unit
data.SetValueUnit(Units::current.task_speed_unit);
}
void
InfoBoxContentNextMC0AltitudeDiff::Update(InfoBoxData &data)
{
const TaskStats &task_stats = XCSoarInterface::Calculated().task_stats;
const GlideResult &next_solution = task_stats.current_leg.solution_mc0;
if (!task_stats.task_valid || !next_solution.IsDefined()) {
data.SetInvalid();
return;
}
// Set Value
TCHAR tmp[32];
Units::FormatUserAltitude(next_solution.altitude_difference, tmp, 32, false);
data.SetValue(tmp);
// Set Unit
data.SetValueUnit(Units::current.altitude_unit);
}
void
InfoBoxContentWindSpeed::Update(InfoBoxData &data)
{
const DerivedInfo &info = CommonInterface::Calculated();
if (!info.wind_available) {
data.SetInvalid();
return;
}
// Set Value
data.SetValue(_T("%2.0f"),
Units::ToUserWindSpeed(info.wind.norm));
// Set Unit
data.SetValueUnit(Units::current.wind_speed_unit);
// Set Comment
data.SetComment(info.wind.bearing);
}
void
InfoBoxContentTaskAASpeedMin::Update(InfoBoxData &data)
{
const CommonStats &common_stats = XCSoarInterface::Calculated().common_stats;
const TaskStats &task_stats = XCSoarInterface::Calculated().task_stats;
if (!common_stats.ordered_has_targets ||
!task_stats.task_valid || !positive(common_stats.aat_speed_min)) {
data.SetInvalid();
return;
}
// Set Value
data.SetValue(_T("%2.0f"),
Units::ToUserTaskSpeed(common_stats.aat_speed_min));
// Set Unit
data.SetValueUnit(Units::current.task_speed_unit);
}
void
InfoBoxContentFinalAltitudeRequire::Update(InfoBoxData &data)
{
const TaskStats &task_stats = XCSoarInterface::Calculated().task_stats;
if (!task_stats.task_valid ||
!task_stats.total.solution_remaining.IsOk()) {
data.SetInvalid();
return;
}
// Set Value
TCHAR tmp[32];
Units::FormatUserAltitude(task_stats.total.solution_remaining.GetRequiredAltitude(),
tmp, 32, false);
data.SetValue(tmp);
// Set Unit
data.SetValueUnit(Units::current.altitude_unit);
}
void
UpdateInfoBoxTaskAASpeedMax(InfoBoxData &data)
{
const auto &calculated = CommonInterface::Calculated();
const TaskStats &task_stats = calculated.ordered_task_stats;
const CommonStats &common_stats = calculated.common_stats;
if (!task_stats.has_targets || !positive(common_stats.aat_speed_max)) {
data.SetInvalid();
return;
}
// Set Value
data.SetValue(_T("%2.0f"),
Units::ToUserTaskSpeed(common_stats.aat_speed_max));
// Set Unit
data.SetValueUnit(Units::current.task_speed_unit);
}
void
InfoBoxContentNextAltitudeRequire::Update(InfoBoxData &data)
{
// pilots want this to be assuming terminal flight to this wp
const TaskStats &task_stats = XCSoarInterface::Calculated().task_stats;
const GlideResult &next_solution = XCSoarInterface::Calculated().common_stats.next_solution;
if (!task_stats.task_valid || !next_solution.IsAchievable()) {
data.SetInvalid();
return;
}
// Set Value
TCHAR tmp[32];
Units::FormatUserAltitude(next_solution.GetRequiredAltitude(), tmp, 32, false);
data.SetValue(tmp);
// Set Unit
data.SetValueUnit(Units::current.altitude_unit);
}
void
InfoBoxContentNextAltitudeArrival::Update(InfoBoxData &data)
{
// pilots want this to be assuming terminal flight to this wp
const TaskStats &task_stats = XCSoarInterface::Calculated().task_stats;
const GlideResult next_solution = XCSoarInterface::Calculated().common_stats.next_solution;
if (!task_stats.task_valid || !next_solution.IsFinalGlide()) {
data.SetInvalid();
return;
}
// Set Value
TCHAR tmp[32];
fixed alt = next_solution.GetArrivalAltitude(XCSoarInterface::Basic().nav_altitude);
Units::FormatUserAltitude(alt, tmp, 32, false);
data.SetValue(tmp);
// Set Unit
data.SetValueUnit(Units::current.altitude_unit);
}
void
UpdateInfoBoxCircleDiameter(InfoBoxData &data)
{
if (!CommonInterface::Basic().airspeed_available.IsValid()) {
data.SetInvalid();
return;
}
const Angle turn_rate =
CommonInterface::Calculated().turn_rate_heading_smoothed.Absolute();
// deal with div zero and small turn rates
if (turn_rate < Angle::Degrees(1)) {
data.SetInvalid();
return;
}
const fixed circle_diameter = CommonInterface::Basic().true_airspeed
/ turn_rate.Radians()
* fixed(2); // convert turn rate to radians/s and double it to get estimated circle diameter
if (circle_diameter > fixed (2000)){ // arbitrary estimated that any diameter bigger than 2km will not be interesting
data.SetInvalid();
return;
}
TCHAR buffer[32];
Unit unit = FormatSmallUserDistance(buffer, circle_diameter, false, 0);
data.SetValue (buffer);
data.SetValueUnit(unit);
const fixed circle_duration =
Angle::FullCircle().Native() / turn_rate.Native();
StaticString<16> duration_buffer;
duration_buffer.Format(_T("%u s"), int(circle_duration));
_tcscpy (buffer, duration_buffer);
data.SetComment (buffer);
}
