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https://github.com/dcs-retribution/dcs-retribution.git
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4eadce7563
We can always estimate a startup time now. Remove the nullability from the result, cleanup the callsites, and eliminate TotEstimator.mission_start_time since it no longer does anything useful.
100 lines
3.4 KiB
Python
100 lines
3.4 KiB
Python
from __future__ import annotations
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import math
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from datetime import timedelta
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from typing import TYPE_CHECKING
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from dcs.mapping import Point
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from game.utils import (
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Distance,
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SPEED_OF_SOUND_AT_SEA_LEVEL,
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Speed,
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mach,
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meters,
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)
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if TYPE_CHECKING:
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from .flight import Flight
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from .package import Package
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class GroundSpeed:
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@classmethod
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def for_flight(cls, flight: Flight, altitude: Distance) -> Speed:
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# TODO: Expose both a cruise speed and target speed.
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# The cruise speed can be used for ascent, hold, join, and RTB to save
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# on fuel, but mission speed will be fast enough to keep the flight
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# safer.
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# DCS's max speed is in kph at 0 MSL.
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max_speed = flight.unit_type.max_speed
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if max_speed > SPEED_OF_SOUND_AT_SEA_LEVEL:
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# Aircraft is supersonic. Limit to mach 0.85 to conserve fuel and
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# account for heavily loaded jets.
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return mach(0.85, altitude)
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# For subsonic aircraft, assume the aircraft can reasonably perform at
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# 80% of its maximum, and that it can maintain the same mach at altitude
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# as it can at sea level. This probably isn't great assumption, but
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# might. be sufficient given the wiggle room. We can come up with
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# another heuristic if needed.
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cruise_mach = max_speed.mach() * 0.85
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return mach(cruise_mach, altitude)
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class TravelTime:
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@staticmethod
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def between_points(a: Point, b: Point, speed: Speed) -> timedelta:
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error_factor = 1.05
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distance = meters(a.distance_to_point(b))
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return timedelta(hours=distance.nautical_miles / speed.knots * error_factor)
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# TODO: Most if not all of this should move into FlightPlan.
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class TotEstimator:
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def __init__(self, package: Package) -> None:
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self.package = package
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def earliest_tot(self) -> timedelta:
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if not self.package.flights:
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return timedelta(0)
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earliest_tot = max(
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(self.earliest_tot_for_flight(f) for f in self.package.flights)
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)
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# Trim microseconds. DCS doesn't handle sub-second resolution for tasks,
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# and they're not interesting from a mission planning perspective so we
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# don't want them in the UI.
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#
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# Round up so we don't get negative start times.
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return timedelta(seconds=math.ceil(earliest_tot.total_seconds()))
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@staticmethod
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def earliest_tot_for_flight(flight: Flight) -> timedelta:
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"""Estimate the fastest time from mission start to the target position.
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For BARCAP flights, this is time to the racetrack start. This ensures that
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they are on station at the same time any other package members reach
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their ingress point.
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For other mission types this is the time to the mission target.
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Args:
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flight: The flight to get the earliest TOT time for.
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Returns:
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The earliest possible TOT for the given flight in seconds. Returns 0
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if an ingress point cannot be found.
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"""
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# Clear the TOT, calculate the startup time. Negating the result gives
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# the earliest possible start time.
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orig_tot = flight.package.time_over_target
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try:
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flight.package.time_over_target = timedelta()
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time = flight.flight_plan.startup_time()
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finally:
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flight.package.time_over_target = orig_tot
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return -time
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