void
TaskPropertiesPanel::InitView()
{
WndProperty* wp;
static gcc_constexpr_data StaticEnumChoice start_max_height_ref_list[] = {
{ (unsigned)HeightReferenceType::AGL, N_("AGL"), N_("Reference AGL for start maximum height rule (above start point).") },
{ (unsigned)HeightReferenceType::MSL, N_("MSL"), N_("Reference MSL for start maximum height rule (above sea level).") },
{ 0 }
};
LoadFormProperty(form, _T("prpStartHeightRef"), start_max_height_ref_list,
(unsigned)HeightReferenceType::AGL);
static gcc_constexpr_data StaticEnumChoice finish_min_height_ref_list[] = {
{ (unsigned)HeightReferenceType::AGL, N_("AGL"), N_("Reference AGL for finish minimum height rule (above finish point).") },
{ (unsigned)HeightReferenceType::MSL, N_("MSL"), N_("Reference MSL for finish minimum height rule (above sea level).") },
{ 0 }
};
LoadFormProperty(form, _T("prpFinishHeightRef"), finish_min_height_ref_list,
(unsigned)HeightReferenceType::AGL);
wp = (WndProperty *)form.FindByName(_T("prpTaskType"));
if (wp) {
const std::vector<TaskFactoryType> factory_types =
ordered_task->GetFactoryTypes();
DataFieldEnum* dfe = (DataFieldEnum*)wp->GetDataField();
dfe->EnableItemHelp(true);
for (unsigned i = 0; i < factory_types.size(); i++) {
dfe->addEnumText(OrderedTaskFactoryName(factory_types[i]),
(unsigned)factory_types[i], OrderedTaskFactoryDescription(
factory_types[i]));
if (factory_types[i] == ordered_task->get_factory_type())
dfe->Set((unsigned)factory_types[i]);
}
wp->RefreshDisplay();
}
}
void
TaskDefaultsConfigPanel::Prepare(ContainerWindow &parent, const PixelRect &rc)
{
WndProperty *wp;
const ComputerSettings &settings_computer = XCSoarInterface::GetComputerSettings();
const TaskBehaviour &task_behaviour = settings_computer.task;
OrderedTask temptask(task_behaviour);
temptask.SetFactory(TaskFactoryType::RACING);
RowFormWidget::Prepare(parent, rc);
wp = AddEnum(_("Start point"),
_("Default start type for new tasks you create."),
this);
if (wp) {
const auto point_types = temptask.GetFactory().GetValidStartTypes();
DataFieldEnum* dfe = (DataFieldEnum*)wp->GetDataField();
dfe->EnableItemHelp(true);
for (auto i = point_types.begin(), end = point_types.end();
i != end; ++i) {
const AbstractTaskFactory::LegalPointType type = *i;
dfe->addEnumText(OrderedTaskPointName(type), (unsigned)type,
OrderedTaskPointDescription(type));
if (type == task_behaviour.sector_defaults.start_type)
dfe->Set((unsigned)type);
}
wp->RefreshDisplay();
}
AddFloat(Caption_GateWidth, _("Default radius or gate width of the start zone for new tasks."),
_T("%.1f %s"), _T("%.1f"), fixed(0.1), fixed(100), fixed(1.0), true, UnitGroup::DISTANCE,
task_behaviour.sector_defaults.start_radius);
AddSpacer();
wp = AddEnum(_("Finish point"),
_("Default finish type for new tasks you create."),
this);
if (wp) {
const auto point_types = temptask.GetFactory().GetValidFinishTypes();
DataFieldEnum* dfe = (DataFieldEnum*)wp->GetDataField();
dfe->EnableItemHelp(true);
for (auto i = point_types.begin(), end = point_types.end();
i != end; ++i) {
const AbstractTaskFactory::LegalPointType type = *i;
dfe->addEnumText(OrderedTaskPointName(type), (unsigned)type,
OrderedTaskPointDescription(type));
if (type == task_behaviour.sector_defaults.finish_type)
dfe->Set((unsigned)type);
}
wp->RefreshDisplay();
}
AddFloat(Caption_GateWidth, _("Default radius or gate width of the finish zone in new tasks."),
_T("%.1f %s"), _T("%.1f"), fixed(0.1), fixed(100), fixed(1.0), true, UnitGroup::DISTANCE,
task_behaviour.sector_defaults.finish_radius);
AddSpacer();
wp = AddEnum(_("Turn point"), _("Default turn point type for new tasks you create."));
if (wp) {
const auto point_types = temptask.GetFactory().GetValidIntermediateTypes();
DataFieldEnum* dfe = (DataFieldEnum*)wp->GetDataField();
dfe->EnableItemHelp(true);
for (auto i = point_types.begin(), end = point_types.end();
i != end; ++i) {
const AbstractTaskFactory::LegalPointType type = *i;
dfe->addEnumText(OrderedTaskPointName(type), (unsigned)type,
OrderedTaskPointDescription(type));
if (type == task_behaviour.sector_defaults.turnpoint_type) {
dfe->Set((unsigned)type);
}
}
wp->RefreshDisplay();
}
AddFloat(Caption_Radius, _("Default radius of turnpoint cylinders and sectors in new tasks."),
_T("%.1f %s"), _T("%.1f"), fixed(0.1), fixed(100), fixed(1.0), true, UnitGroup::DISTANCE,
task_behaviour.sector_defaults.turnpoint_radius);
AddSpacer();
wp = AddEnum(_("Task"), _("Default task type for new tasks you create."));
if (wp) {
const std::vector<TaskFactoryType> factory_types =
temptask.GetFactoryTypes();
DataFieldEnum* dfe = (DataFieldEnum*)wp->GetDataField();
dfe->EnableItemHelp(true);
for (unsigned i = 0; i < factory_types.size(); i++) {
dfe->addEnumText(OrderedTaskFactoryName(factory_types[i]),
(unsigned)factory_types[i], OrderedTaskFactoryDescription(
factory_types[i]));
if (factory_types[i] == task_behaviour.task_type_default)
dfe->Set((unsigned)factory_types[i]);
}
wp->RefreshDisplay();
}
AddTime(_("AAT min. time"), _("Default AAT min. time for new AAT tasks."),
60, 10 * 60 * 60, 60, (unsigned)task_behaviour.ordered_defaults.aat_min_time);
AddTime(_("Optimisation margin"),
_("Safety margin for AAT task optimisation. Optimisation "
"seeks to complete the task at the minimum time plus this margin time."),
0, 30 * 60, 60, (unsigned)task_behaviour.optimise_targets_margin);
SetExpertRow(AATTimeMargin);
SetStartLabel();
SetFinishLabel();
}
void
TaskDefaultsConfigPanel::Init(WndForm *_wf)
{
assert(_wf != NULL);
wf = _wf;
WndProperty *wp;
const SETTINGS_COMPUTER &settings_computer = XCSoarInterface::SettingsComputer();
OrderedTask* temptask = protected_task_manager->task_blank();
temptask->set_factory(TaskBehaviour::FACTORY_RT);
wp = (WndProperty*)wf->FindByName(_T("prpStartType"));
if (wp) {
const AbstractTaskFactory::LegalPointVector point_types =
temptask->get_factory().getValidStartTypes();
DataFieldEnum* dfe = (DataFieldEnum*)wp->GetDataField();
dfe->EnableItemHelp(true);
for (unsigned i = 0; i < point_types.size(); i++) {
dfe->addEnumText(OrderedTaskPointName(point_types[i]), (unsigned)point_types[i],
OrderedTaskPointDescription(point_types[i]));
if (point_types[i] == settings_computer.sector_defaults.start_type)
dfe->Set((unsigned)point_types[i]);
}
wp->RefreshDisplay();
}
LoadFormProperty(*wf, _T("prpStartRadius"), ugDistance,
settings_computer.sector_defaults.start_radius);
wp = (WndProperty*)wf->FindByName(_T("prpFinishType"));
if (wp) {
const AbstractTaskFactory::LegalPointVector point_types =
temptask->get_factory().getValidFinishTypes();
DataFieldEnum* dfe = (DataFieldEnum*)wp->GetDataField();
dfe->EnableItemHelp(true);
for (unsigned i = 0; i < point_types.size(); i++) {
dfe->addEnumText(OrderedTaskPointName(point_types[i]), (unsigned)point_types[i],
OrderedTaskPointDescription(point_types[i]));
if (point_types[i] == settings_computer.sector_defaults.finish_type)
dfe->Set((unsigned)point_types[i]);
}
wp->RefreshDisplay();
}
LoadFormProperty(*wf, _T("prpFinishRadius"), ugDistance,
settings_computer.sector_defaults.finish_radius);
wp = (WndProperty*)wf->FindByName(_T("prpTurnpointType"));
if (wp) {
const AbstractTaskFactory::LegalPointVector point_types =
temptask->get_factory().getValidIntermediateTypes();
DataFieldEnum* dfe = (DataFieldEnum*)wp->GetDataField();
dfe->EnableItemHelp(true);
for (unsigned i = 0; i < point_types.size(); i++) {
dfe->addEnumText(OrderedTaskPointName(point_types[i]),
(unsigned)point_types[i],
OrderedTaskPointDescription(point_types[i]));
if (point_types[i] == settings_computer.sector_defaults.turnpoint_type) {
dfe->Set((unsigned)point_types[i]);
}
}
wp->RefreshDisplay();
}
LoadFormProperty(*wf, _T("prpTurnpointRadius"), ugDistance,
settings_computer.sector_defaults.turnpoint_radius);
wp = (WndProperty*)wf->FindByName(_T("prpTaskType"));
if (wp) {
const std::vector<TaskBehaviour::Factory_t> factory_types =
temptask->get_factory_types();
DataFieldEnum* dfe = (DataFieldEnum*)wp->GetDataField();
dfe->EnableItemHelp(true);
for (unsigned i = 0; i < factory_types.size(); i++) {
dfe->addEnumText(OrderedTaskFactoryName(factory_types[i]),
(unsigned)factory_types[i], OrderedTaskFactoryDescription(
factory_types[i]));
if (factory_types[i] == settings_computer.task_type_default)
dfe->Set((unsigned)factory_types[i]);
}
wp->RefreshDisplay();
}
LoadFormProperty(*wf, _T("prpAATMinTime"),
(unsigned)(settings_computer.ordered_defaults.aat_min_time / 60));
LoadFormProperty(*wf, _T("prpAATTimeMargin"),
(unsigned)(settings_computer.optimise_targets_margin / 60));
delete temptask;
}
void
TaskPropertiesPanel::Prepare(ContainerWindow &parent, const PixelRect &rc)
{
AddTime(_("AAT min. time"), _("Minimum AAT task time in minutes."),
0, 36000, 60, 180);
AddFloat(_("Start max. speed"),
_("Maximum speed allowed in start observation zone. Set to 0 for no limit."),
_T("%.0f %s"), _T("%.0f"),
fixed_zero, fixed(300), fixed(5), false, fixed_zero);
AddFloat(_("Start max. height"),
_("Maximum height based on start height reference (AGL or MSL) while starting the task. Set to 0 for no limit."),
_T("%.0f %s"), _T("%.0f"),
fixed_zero, fixed(10000), fixed(25), false, fixed_zero);
static gcc_constexpr_data StaticEnumChoice start_max_height_ref_list[] = {
{ (unsigned)HeightReferenceType::AGL, N_("AGL"), N_("Reference AGL for start maximum height rule (above start point).") },
{ (unsigned)HeightReferenceType::MSL, N_("MSL"), N_("Reference MSL for start maximum height rule (above sea level).") },
{ 0 }
};
AddEnum(_("Start height ref."),
_("Reference used for start max height rule\n"
"[MSL] Reference is altitude above mean sea level\n"
"[AGL] Reference is the height above the start point"),
start_max_height_ref_list);
AddFloat(_("Finish min. height"),
_("Minimum height based on finish height reference (AGL or MSL) while finishing the task. Set to 0 for no limit."),
_T("%.0f %s"), _T("%.0f"),
fixed_zero, fixed(10000), fixed(25), false, fixed_zero);
static gcc_constexpr_data StaticEnumChoice finish_min_height_ref_list[] = {
{ (unsigned)HeightReferenceType::AGL, N_("AGL"), N_("Reference AGL for finish minimum height rule (above finish point).") },
{ (unsigned)HeightReferenceType::MSL, N_("MSL"), N_("Reference MSL for finish minimum height rule (above sea level).") },
{ 0 }
};
AddEnum(_("Finish height ref."),
_("Reference used for finish min height rule\n"
"[MSL] Reference is altitude above mean sea level\n"
"[AGL] Reference is the height above the finish point"),
finish_min_height_ref_list);
AddBoolean(_("FAI start / finish rules"),
_("If enabled, has no max start height or max start speed and requires the minimum height above ground for finish to be greater than 1000m below the start height."),
false, this);
DataFieldEnum *dfe = new DataFieldEnum(NULL);
dfe->SetListener(this);
dfe->EnableItemHelp(true);
const std::vector<TaskFactoryType> factory_types =
ordered_task->GetFactoryTypes();
for (unsigned i = 0; i < factory_types.size(); i++) {
dfe->addEnumText(OrderedTaskFactoryName(factory_types[i]),
(unsigned)factory_types[i],
OrderedTaskFactoryDescription(factory_types[i]));
if (factory_types[i] == ordered_task->GetFactoryType())
dfe->Set((unsigned)factory_types[i]);
}
Add(_("Task type"), _("Sets the behaviour for the current task."), dfe);
}
