I don't know of a server-side library that'll do the job for you. I can however give you some pointers on how to implement one yourself.
The basic approach to clustering is simply to calculate the distance between your markers and when two of them are close enough you replace them with a single marker located at the mid-point between the two.
Instead of just having a limitation on how close to each other markers may be, you may also (or instead) choose to limit the number of clusters/markers you want as a result.
To accomplish this you could calculate the distance between all pairs of markers, sort them, and then merge from the top until you only have as many markers/clusters as you wish.
To refine the mid-point positioning when forming a cluster you may take into account the number of actual markers represented by each of the two to be merged. Think of that number as a weight and the line between the two markers as a scale. Then instead of always choosing the mid-point, choose the point that would balance the scale.
I'd guess that this simple form of clustering is good enough if you have a limited number of markers. If your data set (# of markers and their position) is roughly static you can calculate clustering on the server once in a while, cache it, and server clients directly from the cache.
However, if you need to support large scale scenarios potentially with markers all over the world you'll need a more sophisticated approach.
The mentioned cluster algorithm does not scale. In fact its computation cost would typically grow exponentially with the number of markers.
To remedy this you could split the world into partitions and calculate clustering and serve clients from each partition. This would indeed support scaling since the workload can be split and performed by several (roughly) independent servers.
The question then is how to find a good partitioning scheme. You may also want to consider providing different clustering of markers at different zoom levels, and your partitioning scheme should incorporate this as well to allow scaling.
Google divide the map into tiles with x, y and z-coordinates, where x and y are the horizontal and vertical position of the tile starting from the north-west corner of the map, and where z is the zoom level.
At the minimum zoom level (zero) the entire map consist of a single tile. (all tiles are 256x256 pixels). At the next zoom level that tile is divided into four sub tiles. This continues, so that in zoom level 2 each of those four tiles has been divided into four sub tiles, which gives us a total of 16 tiles. Zoom level 3 has 64 tiles, level 4 has 256 tiles, and so on. (The number of tiles on any zoom level can be expressed as
Using this partitioning scheme you could calculate clustering per tile starting at the lowest zoom level (highest z-coordinate), bubbling up until you reach the top.
The set of markers to be clustered for a single tile is the union of all markers (some of which may represent clusters) of its four sub tiles.
This gives you a limited computational cost and also gives you a nice way of chunking up the data to be sent to the client. Instead of requesting all markers for a given zoom level (which would not scale) clients can request markers on a tile-by-tile basis as they are loaded into the map.
There is however a flaw in this approach: Consider two adjacent tiles, one to the left and one to the right. If the left tile contains a marker/cluster at its far right side and the right tile contains a marker/cluster at its far left side, then those two markers/clusters should be merged but won't be since we're performing the clustering mechanism for each tile individually.
To remedy this you could post-process tiles after they have been clustered so that you merge markers/clusters that lay on the each of the four edges, taking into account each of the eight adjacent tiles for a given tile. This post-merging mechanism will only work if we can assume that no single cluster is large enough to affect the surrounding markers which are not in the same sub tile. This is, however, a reasonable assumption.
As a final note: With the scaled out approach you'll have clients making several small requests. These requests will have locality (i.e. tiles are not randomly requested, but instead tiles that are geographically close to each other are also typically accessed together).
To improve lookup/query performance you would benefit from using search keys (representing the tiles) that also have this locality property (since this would store data for adjacent tiles in adjacent data blocks on disk - improving read time and cache utilization).
You can form such a key using the tile/sub tile partitioning scheme. Let the top tile (the single one spanning the entire map) have the empty string as key. Next, let each of its sub tiles have the keys A, B, C and D. The next level would have keys AA, AB, AC, AD, BA, BC, ..., DC, DD.
Apply this recursively and you'll end up with a partitioning key that identifies your tiles, allows quick transformation to x,y,z-coordinates and has the locality property. This key naming scheme is sometimes called a Quad Key stemming from the fact that the partitioning scheme forms a Quad Tree. The locality property is the same as you get when using a Z-order curve to map a 2D-value into a 1D-value.
Please let me know if you need more details.