When you are working with a cylindrical projection, as Leaflet does, it can be solved relatively easily with trigonometry. My solution is based on the first approach of Ivan's answer above, which is cutting the line in two parts at the 180th meridian. My solution is not perfect, as I will show below, but it is a good start.

Here is the code:

```
function addLineToMap(start, end) {
if (Math.abs(start[1] - end[1]) > 180.0) {
const start_dist_to_antimeridian = start[1] > 0 ? 180 - start[1] : 180 + start[1];
const end_dist_to_antimeridian = end[1] > 0 ? 180 - end[1] : 180 + end[1];
const lat_difference = Math.abs(start[0] - end[0]);
const alpha_angle = Math.atan(lat_difference / (start_dist_to_antimeridian + end_dist_to_antimeridian)) * (180 / Math.PI) * (start[1] > 0 ? 1 : -1);
const lat_diff_at_antimeridian = Math.tan(alpha_angle * Math.PI / 180) * start_dist_to_antimeridian;
const intersection_lat = start[0] + lat_diff_at_antimeridian;
const first_line_end = [intersection_lat, start[1] > 0 ? 180 : -180];
const second_line_start = [intersection_lat, end[1] > 0 ? 180 : -180];
L.polyline([start, first_line_end]).addTo(map);
L.polyline([second_line_start, end]).addTo(map);
} else {
L.polyline([start, end]).addTo(map);
}
}
```

This will calculate the latitude where the line crosses the 180th meridian, and draw the first line from the starting point to this latitude on the 180th meridian, and then a second one from this point to the end.

The picture below shows an example of the result.

Even though I'm fairly certain the math checks out on my calculations, there is a small kink where the two lines are separated. I'm not sure whether this is due to the rendering of the Leaflet map, or an actual error in my calculations.

The starting point is `[35.552299, 139.779999]`

and the end point is `[64.81510162, -147.8560028]`

.

The total longitudinal difference between the points is `72.364`

, and latitudinal difference is `29.263`

. Using the code below or an online calculator, the angle `α`

is `22.018`

. Taking only the distance from the starting point to the 180th meridian, and the angle `α`

, the latitudinal difference between starting point and intersection is `16.264`

. Adding the latitude of the starting point and this value, we get a latitude of 51.8166 at the 180th meridian. Drawing a straight line on a map tells me that this value should be slightly higher up, but I can't figure out why or how that is calculated.

If you want a curved line that accurately shows the curvate of the earth, I would highly recommend using Leaflet.Geodisic. It is easy to use and has a solution to the antimeridian problem built-in so you don't have to worry about it.