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162 lines
4.7 KiB
162 lines
4.7 KiB
from __future__ import annotations
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import json
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import math
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from typing import Any, Dict, List, Optional, Tuple
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from common.numpy_fast import clip
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from common.params import Params
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EARTH_MEAN_RADIUS = 6371007.2
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class Coordinate:
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def __init__(self, latitude: float, longitude: float) -> None:
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self.latitude = latitude
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self.longitude = longitude
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@classmethod
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def from_mapbox_tuple(cls, t: Tuple[float, float]) -> Coordinate:
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return cls(t[1], t[0])
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def as_dict(self) -> Dict[str, float]:
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return {'latitude': self.latitude, 'longitude': self.longitude}
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def __str__(self) -> str:
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return f"({self.latitude}, {self.longitude})"
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def __eq__(self, other) -> bool:
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if not isinstance(other, Coordinate):
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return False
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return (self.latitude == other.latitude) and (self.longitude == other.longitude)
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def __sub__(self, other: Coordinate) -> Coordinate:
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return Coordinate(self.latitude - other.latitude, self.longitude - other.longitude)
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def __add__(self, other: Coordinate) -> Coordinate:
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return Coordinate(self.latitude + other.latitude, self.longitude + other.longitude)
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def __mul__(self, c: float) -> Coordinate:
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return Coordinate(self.latitude * c, self.longitude * c)
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def dot(self, other: Coordinate) -> float:
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return self.latitude * other.latitude + self.longitude * other.longitude
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def distance_to(self, other: Coordinate) -> float:
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# Haversine formula
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dlat = math.radians(other.latitude - self.latitude)
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dlon = math.radians(other.longitude - self.longitude)
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haversine_dlat = math.sin(dlat / 2.0)
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haversine_dlat *= haversine_dlat
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haversine_dlon = math.sin(dlon / 2.0)
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haversine_dlon *= haversine_dlon
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y = haversine_dlat \
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+ math.cos(math.radians(self.latitude)) \
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* math.cos(math.radians(other.latitude)) \
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* haversine_dlon
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x = 2 * math.asin(math.sqrt(y))
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return x * EARTH_MEAN_RADIUS
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def minimum_distance(a: Coordinate, b: Coordinate, p: Coordinate):
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if a.distance_to(b) < 0.01:
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return a.distance_to(p)
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ap = p - a
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ab = b - a
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t = clip(ap.dot(ab) / ab.dot(ab), 0.0, 1.0)
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projection = a + ab * t
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return projection.distance_to(p)
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def distance_along_geometry(geometry: List[Coordinate], pos: Coordinate) -> float:
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if len(geometry) <= 2:
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return geometry[0].distance_to(pos)
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# 1. Find segment that is closest to current position
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# 2. Total distance is sum of distance to start of closest segment
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# + all previous segments
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total_distance = 0.0
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total_distance_closest = 0.0
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closest_distance = 1e9
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for i in range(len(geometry) - 1):
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d = minimum_distance(geometry[i], geometry[i + 1], pos)
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if d < closest_distance:
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closest_distance = d
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total_distance_closest = total_distance + geometry[i].distance_to(pos)
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total_distance += geometry[i].distance_to(geometry[i + 1])
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return total_distance_closest
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def coordinate_from_param(param: str, params: Optional[Params] = None) -> Optional[Coordinate]:
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if params is None:
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params = Params()
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json_str = params.get(param)
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if json_str is None:
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return None
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pos = json.loads(json_str)
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if 'latitude' not in pos or 'longitude' not in pos:
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return None
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return Coordinate(pos['latitude'], pos['longitude'])
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def string_to_direction(direction: str) -> str:
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for d in ['left', 'right', 'straight']:
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if d in direction:
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return d
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return 'none'
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def parse_banner_instructions(instruction: Any, banners: Any, distance_to_maneuver: float = 0.0) -> None:
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if not len(banners):
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return
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current_banner = banners[0]
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# A segment can contain multiple banners, find one that we need to show now
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for banner in banners:
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if distance_to_maneuver < banner['distanceAlongGeometry']:
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current_banner = banner
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# Only show banner when close enough to maneuver
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instruction.showFull = distance_to_maneuver < current_banner['distanceAlongGeometry']
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# Primary
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p = current_banner['primary']
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if 'text' in p:
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instruction.maneuverPrimaryText = p['text']
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if 'type' in p:
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instruction.maneuverType = p['type']
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if 'modifier' in p:
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instruction.maneuverModifier = p['modifier']
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# Secondary
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if 'secondary' in current_banner:
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instruction.maneuverSecondaryText = current_banner['secondary']['text']
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# Lane lines
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if 'sub' in current_banner:
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lanes = []
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for component in current_banner['sub']['components']:
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if component['type'] != 'lane':
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continue
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lane = {
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'active': component['active'],
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'directions': [string_to_direction(d) for d in component['directions']],
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}
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if 'active_direction' in component:
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lane['activeDirection'] = string_to_direction(component['active_direction'])
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lanes.append(lane)
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instruction.lanes = lanes
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