1use nalgebra::{Vector3, Vector6};
10use std::collections::HashMap;
11
12use crate::derivatives::compute_derivatives;
13use crate::wind::WindSegment;
14use crate::BallisticInputs;
15use crate::DragModel;
16
17fn wind_vector_for_range(range_m: f64, wind_segments: &[WindSegment]) -> Vector3<f64> {
18 if range_m.is_nan() {
19 return Vector3::zeros();
20 }
21 for seg in wind_segments {
22 if range_m < seg.2 {
23 let wind_speed_mps = seg.0 * 0.2777778; let wind_angle_rad = seg.1.to_radians();
25 return Vector3::new(
26 -wind_speed_mps * wind_angle_rad.cos(),
27 0.0,
28 -wind_speed_mps * wind_angle_rad.sin(),
29 );
30 }
31 }
32 Vector3::zeros()
33}
34
35fn rk4_step(
37 state: &Vector6<f64>,
38 t: f64,
39 dt: f64,
40 params: &TrajectoryParams,
41 inputs: &BallisticInputs,
42) -> Vector6<f64> {
43 let k1 = compute_derivatives_vec(state, t, params, inputs);
45 let k2 = compute_derivatives_vec(&(state + dt * 0.5 * k1), t + dt * 0.5, params, inputs);
46 let k3 = compute_derivatives_vec(&(state + dt * 0.5 * k2), t + dt * 0.5, params, inputs);
47 let k4 = compute_derivatives_vec(&(state + dt * k3), t + dt, params, inputs);
48
49 state + (dt / 6.0) * (k1 + 2.0 * k2 + 2.0 * k3 + k4)
50}
51
52fn rk45_step(
54 state: &Vector6<f64>,
55 t: f64,
56 dt: f64,
57 params: &TrajectoryParams,
58 inputs: &BallisticInputs,
59 tol: f64,
60) -> (Vector6<f64>, f64, f64) {
61 const A21: f64 = 1.0 / 5.0;
63 const A31: f64 = 3.0 / 40.0;
64 const A32: f64 = 9.0 / 40.0;
65 const A41: f64 = 44.0 / 45.0;
66 const A42: f64 = -56.0 / 15.0;
67 const A43: f64 = 32.0 / 9.0;
68 const A51: f64 = 19372.0 / 6561.0;
69 const A52: f64 = -25360.0 / 2187.0;
70 const A53: f64 = 64448.0 / 6561.0;
71 const A54: f64 = -212.0 / 729.0;
72 const A61: f64 = 9017.0 / 3168.0;
73 const A62: f64 = -355.0 / 33.0;
74 const A63: f64 = 46732.0 / 5247.0;
75 const A64: f64 = 49.0 / 176.0;
76 const A65: f64 = -5103.0 / 18656.0;
77 const A71: f64 = 35.0 / 384.0;
78 const A73: f64 = 500.0 / 1113.0;
79 const A74: f64 = 125.0 / 192.0;
80 const A75: f64 = -2187.0 / 6784.0;
81 const A76: f64 = 11.0 / 84.0;
82
83 const B1: f64 = 35.0 / 384.0;
85 const B3: f64 = 500.0 / 1113.0;
86 const B4: f64 = 125.0 / 192.0;
87 const B5: f64 = -2187.0 / 6784.0;
88 const B6: f64 = 11.0 / 84.0;
89
90 const B1_ERR: f64 = 5179.0 / 57600.0;
92 const B3_ERR: f64 = 7571.0 / 16695.0;
93 const B4_ERR: f64 = 393.0 / 640.0;
94 const B5_ERR: f64 = -92097.0 / 339200.0;
95 const B6_ERR: f64 = 187.0 / 2100.0;
96 const B7_ERR: f64 = 1.0 / 40.0;
97
98 let k1 = compute_derivatives_vec(state, t, params, inputs);
100 let k2 = compute_derivatives_vec(&(state + dt * A21 * k1), t + dt * 0.2, params, inputs);
101 let k3 = compute_derivatives_vec(
102 &(state + dt * (A31 * k1 + A32 * k2)),
103 t + dt * 0.3,
104 params,
105 inputs,
106 );
107 let k4 = compute_derivatives_vec(
108 &(state + dt * (A41 * k1 + A42 * k2 + A43 * k3)),
109 t + dt * 0.8,
110 params,
111 inputs,
112 );
113 let k5 = compute_derivatives_vec(
114 &(state + dt * (A51 * k1 + A52 * k2 + A53 * k3 + A54 * k4)),
115 t + dt * 8.0 / 9.0,
116 params,
117 inputs,
118 );
119 let k6 = compute_derivatives_vec(
120 &(state + dt * (A61 * k1 + A62 * k2 + A63 * k3 + A64 * k4 + A65 * k5)),
121 t + dt,
122 params,
123 inputs,
124 );
125 let k7 = compute_derivatives_vec(
126 &(state + dt * (A71 * k1 + A73 * k3 + A74 * k4 + A75 * k5 + A76 * k6)),
127 t + dt,
128 params,
129 inputs,
130 );
131
132 let y_new = state + dt * (B1 * k1 + B3 * k3 + B4 * k4 + B5 * k5 + B6 * k6);
134
135 let y_err = state
137 + dt * (B1_ERR * k1 + B3_ERR * k3 + B4_ERR * k4 + B5_ERR * k5 + B6_ERR * k6 + B7_ERR * k7);
138
139 let error = (y_new - y_err).norm() / (1.0 + state.norm());
141
142 let safety = 0.9;
144 let dt_new = if error < tol {
145 dt * safety * (tol / error).powf(0.2).min(2.0)
146 } else {
147 dt * safety * (tol / error).powf(0.25).max(0.1)
148 };
149
150 (y_new, dt_new, error)
151}
152
153pub struct TrajectoryParams {
155 pub mass_kg: f64,
156 pub bc: f64,
157 pub drag_model: DragModel,
158 pub wind_segments: Vec<WindSegment>,
159 pub atmos_params: (f64, f64, f64, f64),
165 pub omega_vector: Option<Vector3<f64>>,
166 pub enable_spin_drift: bool,
167 pub enable_magnus: bool,
168 pub enable_coriolis: bool,
169 pub target_distance_m: f64, pub enable_wind_shear: bool,
171 pub wind_shear_model: String,
172 pub shooter_altitude_m: f64,
173 pub is_twist_right: bool, pub shooting_angle: f64, pub bullet_diameter: f64, pub bullet_length: f64, pub twist_rate: f64, pub custom_drag_table: Option<crate::drag::DragTable>, pub bc_segments: Option<Vec<(f64, f64)>>, pub use_bc_segments: bool, pub ground_threshold: f64,
186}
187
188fn build_inputs(params: &TrajectoryParams) -> BallisticInputs {
194 let mut inputs = BallisticInputs {
195 bc_value: params.bc,
196 bc_type: params.drag_model,
197 bullet_mass: params.mass_kg, muzzle_velocity: 0.0, bullet_diameter: params.bullet_diameter, bullet_length: params.bullet_length,
201 twist_rate: params.twist_rate,
202 is_twist_right: params.is_twist_right,
203 enable_advanced_effects: params.enable_spin_drift
204 || params.enable_magnus
205 || params.enable_coriolis,
206 enable_magnus: params.enable_magnus,
207 enable_coriolis: params.enable_coriolis,
208 altitude: params.atmos_params.0,
209 temperature: params.atmos_params.1,
210 pressure: params.atmos_params.2,
211 humidity: params.atmos_params.3,
212 tipoff_yaw: 0.0,
213 target_distance: 1000.0, muzzle_angle: 0.0,
215 wind_speed: if !params.wind_segments.is_empty() {
216 params.wind_segments[0].0 * 0.2777778 } else {
218 0.0
219 },
220 wind_angle: if !params.wind_segments.is_empty() {
221 params.wind_segments[0].1.to_radians() } else {
223 0.0
224 },
225 latitude: None,
226 shooting_angle: params.shooting_angle,
227 azimuth_angle: 0.0,
228 shot_azimuth: 0.0, use_powder_sensitivity: false,
230 powder_temp_sensitivity: 0.0,
231 powder_temp: 59.0,
232 powder_temp_curve: None,
233 powder_curve_temp_c: None,
234 tipoff_decay_distance: 0.0,
235 ground_threshold: params.ground_threshold, bc_segments: params.bc_segments.clone(),
237 caliber_inches: params.bullet_diameter / 0.0254, weight_grains: params.mass_kg / 0.00006479891,
239 use_bc_segments: params.use_bc_segments,
240 bullet_id: None,
241 bc_segments_data: None,
242 use_enhanced_spin_drift: params.enable_spin_drift,
243 use_form_factor: false,
244 manufacturer: None,
245 bullet_model: None,
246 enable_wind_shear: false,
247 wind_shear_model: "none".to_string(),
248 use_cluster_bc: false,
249 bullet_cluster: None,
250 custom_drag_table: params.custom_drag_table.clone(),
251 bc_type_str: None,
252 enable_pitch_damping: false,
253 enable_precession_nutation: false,
254 enable_aerodynamic_jump: false,
262 use_rk4: true,
263 use_adaptive_rk45: false,
264 enable_trajectory_sampling: false,
265 sample_interval: 10.0,
266 sight_height: 0.0,
267 muzzle_height: 0.0,
268 target_height: 0.0,
269 };
270
271 if inputs.use_bc_segments && inputs.bc_segments_data.is_none() && inputs.bc_segments.is_none() {
278 inputs.bc_segments_data =
279 crate::derivatives::estimate_bc_segments_for(&inputs, inputs.bc_value);
280 }
281 inputs
282}
283
284fn compute_derivatives_vec(
286 state: &Vector6<f64>,
287 t: f64,
288 params: &TrajectoryParams,
289 inputs: &BallisticInputs,
290) -> Vector6<f64> {
291 let pos = Vector3::new(state[0], state[1], state[2]);
292 let vel = Vector3::new(state[3], state[4], state[5]);
293
294 let wind_vector = if !params.wind_segments.is_empty() {
296 if params.enable_wind_shear && params.wind_shear_model != "none" {
297 crate::wind_shear::get_wind_at_position(
298 &pos,
299 ¶ms.wind_segments,
300 params.enable_wind_shear,
301 ¶ms.wind_shear_model,
302 params.shooter_altitude_m,
303 )
304 } else {
305 wind_vector_for_range(pos.x, ¶ms.wind_segments)
306 }
307 } else {
308 Vector3::zeros()
309 };
310
311 let deriv_result = compute_derivatives(
314 pos,
315 vel,
316 inputs,
317 wind_vector,
318 params.atmos_params,
319 params.bc,
320 params.omega_vector,
321 t,
322 );
323
324 Vector6::new(
325 deriv_result[0],
326 deriv_result[1],
327 deriv_result[2],
328 deriv_result[3],
329 deriv_result[4],
330 deriv_result[5],
331 )
332}
333
334pub fn integrate_trajectory(
336 initial_state: [f64; 6],
337 t_span: (f64, f64),
338 params: TrajectoryParams,
339 method: &str,
340 tolerance: f64,
341 max_step: f64,
342) -> Vec<(f64, Vector6<f64>)> {
343 let mut state = Vector6::new(
344 initial_state[0],
345 initial_state[1],
346 initial_state[2],
347 initial_state[3],
348 initial_state[4],
349 initial_state[5],
350 );
351
352 let mut t = t_span.0;
353 let t_end = t_span.1;
354 let mut dt = (t_end - t) / 1000.0; let mut trajectory = Vec::with_capacity(10000);
357 trajectory.push((t, state));
358
359 let inputs = build_inputs(¶ms);
362
363 match method {
364 "RK4" => {
365 dt = dt.min(max_step).min(0.001); while t < t_end {
369 if t + dt > t_end {
370 dt = t_end - t;
371 }
372
373 let new_state = rk4_step(&state, t, dt, ¶ms, &inputs);
374
375 if state[0] < params.target_distance_m && new_state[0] >= params.target_distance_m {
377 let alpha = (params.target_distance_m - state[0]) / (new_state[0] - state[0]);
379 let dt_to_target = dt * alpha;
380
381 let final_state = rk4_step(&state, t, dt_to_target, ¶ms, &inputs);
383
384 let mut corrected_state = final_state;
386 if corrected_state[0] > params.target_distance_m {
387 corrected_state[0] = params.target_distance_m;
388 }
389
390 trajectory.push((t + dt_to_target, corrected_state));
391 break; }
393
394 state = new_state;
395 t += dt;
396 trajectory.push((t, state));
397
398 if state[0] >= params.target_distance_m {
400 let mut final_state = state;
403 final_state[0] = params.target_distance_m; trajectory.push((t, final_state));
405 break;
406 }
407
408 if state[1] < params.ground_threshold {
411 break;
412 }
413 }
414 }
415 "RK45" | _ => {
416 let mut last_save_x = 0.0; let save_interval_m = params.target_distance_m / 50.0; let effective_max_step =
423 if params.enable_wind_shear && params.wind_shear_model != "none" {
424 if params.target_distance_m > 800.0 {
426 0.01 } else {
428 0.02 }
430 } else {
431 max_step };
433
434 dt = dt.min(effective_max_step).max(0.0001); let max_iterations = 100000; let mut iteration_count = 0;
440
441 while t < t_end && iteration_count < max_iterations {
442 iteration_count += 1;
443
444 if t + dt > t_end {
446 dt = t_end - t;
447 }
448
449 let (new_state, dt_new, _error) =
450 rk45_step(&state, t, dt, ¶ms, &inputs, tolerance);
451
452 if state[0] < params.target_distance_m && new_state[0] >= params.target_distance_m {
454 let alpha = (params.target_distance_m - state[0]) / (new_state[0] - state[0]);
456 let dt_to_target = dt * alpha;
457
458 let (final_state, _, _) =
460 rk45_step(&state, t, dt_to_target, ¶ms, &inputs, tolerance);
461
462 let mut corrected_state = final_state;
464 if corrected_state[0] > params.target_distance_m {
465 corrected_state[0] = params.target_distance_m;
466 }
467
468 trajectory.push((t + dt_to_target, corrected_state));
469 break; }
471
472 state = new_state;
474 t += dt;
475
476 if state[0] - last_save_x >= save_interval_m || state[0] >= params.target_distance_m
478 {
479 trajectory.push((t, state));
481 last_save_x = state[0];
482 }
483
484 dt = dt_new.min(effective_max_step).max(0.0001); if state[0] >= params.target_distance_m {
489 let mut final_state = state;
492 final_state[0] = params.target_distance_m; trajectory.push((t, final_state));
494 break;
495 }
496
497 if state[1] < params.ground_threshold {
500 break;
501 }
502 }
503
504 if iteration_count >= max_iterations {
506 eprintln!(
507 "WARNING: Trajectory integration hit maximum iteration limit ({} iterations)",
508 max_iterations
509 );
510 eprintln!(" Final time: {}, Target time: {}", t, t_end);
511 eprintln!(
512 " Final position: downrange(x)={}, Target: {}m",
513 state[0], params.target_distance_m
514 );
515 }
516 }
517 }
518
519 trajectory
520}
521
522pub fn solve_trajectory_rust(
524 initial_state: [f64; 6],
525 t_span: (f64, f64),
526 mass_kg: f64,
527 bc: f64,
528 drag_model: DragModel,
529 wind_segments: Vec<WindSegment>,
530 atmos_params: (f64, f64, f64, f64),
531 omega_vector: Option<Vec<f64>>,
532 enable_spin_drift: bool,
533 enable_magnus: bool,
534 enable_coriolis: bool,
535 method: String,
536 tolerance: f64,
537 max_step: f64,
538 target_distance_m: f64,
539) -> Vec<HashMap<String, f64>> {
540 let omega_vec = omega_vector.map(|v| Vector3::new(v[0], v[1], v[2]));
541
542 let params = TrajectoryParams {
543 mass_kg,
544 bc,
545 drag_model,
546 wind_segments,
547 atmos_params,
548 omega_vector: omega_vec,
549 enable_spin_drift,
550 enable_magnus,
551 enable_coriolis,
552 target_distance_m,
553 enable_wind_shear: false, wind_shear_model: "none".to_string(),
555 shooter_altitude_m: 0.0,
556 is_twist_right: true, shooting_angle: 0.0, bullet_diameter: 0.0078232,
561 bullet_length: 0.031496,
562 twist_rate: 10.0,
563 custom_drag_table: None, bc_segments: None, use_bc_segments: false,
566 ground_threshold: -1000.0, };
568
569 let trajectory =
570 integrate_trajectory(initial_state, t_span, params, &method, tolerance, max_step);
571
572 trajectory
574 .into_iter()
575 .map(|(t, state)| {
576 let mut point = HashMap::new();
577 point.insert("t".to_string(), t);
578 point.insert("x".to_string(), state[0]);
579 point.insert("y".to_string(), state[1]);
580 point.insert("z".to_string(), state[2]);
581 point.insert("vx".to_string(), state[3]);
582 point.insert("vy".to_string(), state[4]);
583 point.insert("vz".to_string(), state[5]);
584 point
585 })
586 .collect()
587}
588
589#[cfg(test)]
590mod tests {
591 use super::*;
592
593 fn create_test_params(target_distance_m: f64) -> TrajectoryParams {
594 TrajectoryParams {
595 mass_kg: 0.01134, bc: 0.442,
597 bullet_diameter: 0.0078232, bullet_length: 0.031496, twist_rate: 10.0,
600 drag_model: DragModel::G7,
601 wind_segments: vec![],
602 atmos_params: (0.0, 59.0, 29.92, 0.0),
603 omega_vector: None,
604 enable_spin_drift: false,
605 enable_magnus: false,
606 enable_coriolis: false,
607 target_distance_m,
608 enable_wind_shear: false,
609 wind_shear_model: "none".to_string(),
610 shooter_altitude_m: 0.0,
611 is_twist_right: true,
612 shooting_angle: 0.0,
613 custom_drag_table: None,
614 bc_segments: None,
615 use_bc_segments: false,
616 ground_threshold: -1000.0,
617 }
618 }
619
620 #[test]
621 fn test_mba954_ground_threshold_honored() {
622 let initial_state = [0.0, 0.0, 0.0, 300.0, -30.0, 0.0]; let mut shallow = create_test_params(1_000_000.0); shallow.ground_threshold = -20.0; let mut deep = create_test_params(1_000_000.0);
630 deep.ground_threshold = -1000.0; let t_shallow =
633 integrate_trajectory(initial_state, (0.0, 60.0), shallow, "RK4", 1e-6, 0.001);
634 let t_deep = integrate_trajectory(initial_state, (0.0, 60.0), deep, "RK4", 1e-6, 0.001);
635
636 assert!(
637 t_shallow.len() < t_deep.len(),
638 "shallow ground_threshold (-20) should terminate earlier than deep (-1000): \
639 shallow={}, deep={}",
640 t_shallow.len(),
641 t_deep.len()
642 );
643 }
644
645 #[test]
646 fn test_integrate_trajectory_basic() {
647 let initial_state = [0.0, -0.038, 0.0, 821.52, 48.61, 0.0];
650
651 let params = TrajectoryParams {
652 mass_kg: 0.01134, bc: 0.442,
654 bullet_diameter: 0.0078232, bullet_length: 0.031496, twist_rate: 10.0,
657 drag_model: DragModel::G7,
658 wind_segments: vec![(0.0, 90.0, 914.4)],
659 atmos_params: (0.0, 59.0, 29.92, 0.0),
660 omega_vector: None,
661 enable_spin_drift: false,
662 enable_magnus: false,
663 enable_coriolis: false,
664 target_distance_m: 914.4, enable_wind_shear: false,
666 wind_shear_model: "none".to_string(),
667 shooter_altitude_m: 0.0,
668 is_twist_right: true,
669 shooting_angle: 0.0,
670 custom_drag_table: None,
671 bc_segments: None,
672 use_bc_segments: false,
673 ground_threshold: -1000.0,
674 };
675
676 println!("Running integrate_trajectory test...");
677 println!("Initial state: {:?}", initial_state);
678 println!("Target distance: {} m", params.target_distance_m);
679
680 let trajectory =
681 integrate_trajectory(initial_state, (0.0, 10.0), params, "RK45", 1e-6, 0.01);
682
683 println!("Trajectory has {} points", trajectory.len());
684
685 assert!(
687 trajectory.len() > 1,
688 "Trajectory should have more than 1 point, but has {}",
689 trajectory.len()
690 );
691
692 if let Some((_, final_state)) = trajectory.last() {
694 println!("Final state: downrange(x)={}", final_state[0]);
695 assert!(
696 final_state[0] > 0.0,
697 "Final x should be positive (bullet moved downrange)"
698 );
699 assert!(
700 final_state[0] >= 900.0,
701 "Final x should be near target distance"
702 );
703 }
704 }
705
706 #[test]
707 fn test_rk4_vs_rk45_consistency() {
708 let initial_state = [0.0, 0.0, 0.0, 800.0, 30.0, 0.0]; let target_distance = 500.0;
711
712 let params_rk4 = create_test_params(target_distance);
713 let params_rk45 = create_test_params(target_distance);
714
715 let trajectory_rk4 =
716 integrate_trajectory(initial_state, (0.0, 5.0), params_rk4, "RK4", 1e-6, 0.001);
717 let trajectory_rk45 =
718 integrate_trajectory(initial_state, (0.0, 5.0), params_rk45, "RK45", 1e-6, 0.01);
719
720 assert!(!trajectory_rk4.is_empty());
722 assert!(!trajectory_rk45.is_empty());
723
724 let (_, final_rk4) = trajectory_rk4.last().unwrap();
725 let (_, final_rk45) = trajectory_rk45.last().unwrap();
726
727 let rk4_z = final_rk4[0];
729 let rk45_z = final_rk45[0];
730 let diff_percent = ((rk4_z - rk45_z) / rk45_z).abs() * 100.0;
731
732 assert!(
733 diff_percent < 1.0,
734 "RK4 and RK45 final positions differ by {}%: RK4={}, RK45={}",
735 diff_percent,
736 rk4_z,
737 rk45_z
738 );
739 }
740
741 #[test]
742 fn test_ground_impact_detection() {
743 let initial_state = [0.0, 100.0, 0.0, 300.0, -50.0, 0.0]; let mut params = create_test_params(10000.0); params.target_distance_m = 10000.0;
748
749 let trajectory =
750 integrate_trajectory(initial_state, (0.0, 20.0), params, "RK45", 1e-6, 0.01);
751
752 let (_, final_state) = trajectory.last().unwrap();
754
755 assert!(
757 final_state[1] <= -900.0,
758 "Should hit ground, but y={}",
759 final_state[1]
760 );
761 assert!(
762 final_state[0] < 10000.0,
763 "Should not reach target, but z={}",
764 final_state[0]
765 );
766 }
767
768 #[test]
769 fn test_target_distance_reached() {
770 let initial_state = [0.0, 0.0, 0.0, 800.0, 20.0, 0.0]; let target_distance = 300.0;
772
773 let params = create_test_params(target_distance);
774
775 let trajectory =
776 integrate_trajectory(initial_state, (0.0, 5.0), params, "RK45", 1e-6, 0.01);
777
778 let (_, final_state) = trajectory.last().unwrap();
779
780 assert!(
782 (final_state[0] - target_distance).abs() < 1.0,
783 "Should reach target at {}m, but stopped at {}m",
784 target_distance,
785 final_state[0]
786 );
787 }
788
789 #[test]
790 fn test_wind_affects_trajectory() {
791 let initial_state = [0.0, 0.0, 0.0, 800.0, 30.0, 0.0]; let target_distance = 500.0;
796
797 let params_no_wind = create_test_params(target_distance);
799
800 let mut params_headwind = create_test_params(target_distance);
802 params_headwind.wind_segments = vec![(72.0, 0.0, 500.0)]; let trajectory_no_wind = integrate_trajectory(
805 initial_state,
806 (0.0, 5.0),
807 params_no_wind,
808 "RK45",
809 1e-6,
810 0.01,
811 );
812 let trajectory_headwind = integrate_trajectory(
813 initial_state,
814 (0.0, 5.0),
815 params_headwind,
816 "RK45",
817 1e-6,
818 0.01,
819 );
820
821 assert!(
823 !trajectory_no_wind.is_empty(),
824 "No-wind trajectory should complete"
825 );
826 assert!(
827 !trajectory_headwind.is_empty(),
828 "Headwind trajectory should complete"
829 );
830
831 let (time_no_wind, final_no_wind) = trajectory_no_wind.last().unwrap();
832 let (time_headwind, final_headwind) = trajectory_headwind.last().unwrap();
833
834 let drop_no_wind = final_no_wind[1];
837 let drop_headwind = final_headwind[1];
838
839 println!("No wind: time={}, drop={}", time_no_wind, drop_no_wind);
842 println!("Headwind: time={}, drop={}", time_headwind, drop_headwind);
843
844 assert!(
846 (final_no_wind[0] - target_distance).abs() < 10.0,
847 "No-wind should reach target"
848 );
849 assert!(
850 (final_headwind[0] - target_distance).abs() < 10.0,
851 "Headwind should reach target"
852 );
853 }
854
855 #[test]
856 fn test_solve_trajectory_rust_output_format() {
857 let initial_state = [0.0, 0.0, 0.0, 800.0, 30.0, 0.0]; let result = solve_trajectory_rust(
860 initial_state,
861 (0.0, 2.0),
862 0.01134, 0.442, DragModel::G7, vec![], (0.0, 59.0, 29.92, 0.0), None, false, false, false, "RK45".to_string(), 1e-6, 0.01, 500.0, );
876
877 assert!(!result.is_empty());
879
880 let first_point = &result[0];
881 assert!(first_point.contains_key("t"));
882 assert!(first_point.contains_key("x"));
883 assert!(first_point.contains_key("y"));
884 assert!(first_point.contains_key("z"));
885 assert!(first_point.contains_key("vx"));
886 assert!(first_point.contains_key("vy"));
887 assert!(first_point.contains_key("vz"));
888 }
889
890 #[test]
891 fn test_left_vs_right_twist() {
892 let initial_state = [0.0, 0.0, 0.0, 800.0, 30.0, 0.0]; let target_distance = 500.0;
894
895 let mut params_right = create_test_params(target_distance);
896 params_right.is_twist_right = true;
897 params_right.enable_spin_drift = true;
898
899 let mut params_left = create_test_params(target_distance);
900 params_left.is_twist_right = false;
901 params_left.enable_spin_drift = true;
902
903 let trajectory_right =
904 integrate_trajectory(initial_state, (0.0, 5.0), params_right, "RK45", 1e-6, 0.01);
905 let trajectory_left =
906 integrate_trajectory(initial_state, (0.0, 5.0), params_left, "RK45", 1e-6, 0.01);
907
908 assert!(!trajectory_right.is_empty());
910 assert!(!trajectory_left.is_empty());
911
912 let (_, final_right) = trajectory_right.last().unwrap();
914 let (_, final_left) = trajectory_left.last().unwrap();
915
916 assert!((final_right[2] - final_left[2]).abs() < 10.0);
918 }
919}