# “moving furniture”: collision resolution in 2d space (non-rotating shrinkable 2d rectangles)

In 2d space we have a collection of rectangles.

Here's a picture:

Vertical line on the right is non-moveable "wall". Arrow on the left shows direction of movement. I need to move leftmost rectangle to the right.

1. Rectangles cannot rotate.
2. Rectangles are not allowed to overlap horizontally.
3. Rectangle can shrink (horizontally) down to a certain minimum width (which is set individually to each rectangle)
4. Rectangles can only move horizontally (left/right) and shrink horizontally.
5. Leftmost rectangle (pointed at by arrow) cannot shrink.
6. Widths and coordinates are stored as integers.

I need to move leftmost rectangle to the right by X units, pushing everything in its way to the right.

There are two problems:

1. I need to determine how far I can move leftmost rectangle to the right (it might not be possible to move for X units).
2. Move rect by X units (or if it is not possible to move by X units, move by maximum possible amount, smaller than X) and get new coordinates and sizes for every rectangle in the system.

You cannot use Y coordinate and height of rectangle for anything, instead every rectangle has a list (implemented as pointers) of rectangles it will hit if you keep moving it to the right, you can only retrieve x coordinate, width, and minimum width. This data model cannot be changed. (technically, reppresenting this as a set of rectangles in 2d is simplification)

Important: Children from different levels and branches can have the same rectangle in the "potential collision" list. Here's initial picture with pointers displayed as red lines:

How can I do it?

I know a dumb way (that'll work) to solve this problem: iteratively. I.e.

1. Memorize current state of the system. If state of the system is already memorized, forget previously memorized state.
2. Push leftmost rect by 1 unit.
3. Recursively resolve collisions (if any).
4. If collision could not be resolved, return memorized state of the system.
5. If collisions could be resolved, and we already moved by X units, return current state of the system.
6. Otherwise, go to 1.

This WILL solve the problem, but such iterative solution can be slow if X is large. Is there any better way to solve it?

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