Two words: premature optimization.
You are concerned about performance. But considering that you want to make a Minecraft clone, this means that the game world can very well be represented by a three-dimensional array. Accessing those is reasonably fast in all of the mentioned programming languages; the game logic should take much more time to execute than accessing millions of array entries. So why optimize a part that will not take the majority of the computation time anyway - even before you wrote a minimally working version?
You might want to create a Java interface or a Scala trait that represents the game world. It offers methods to get and store the contents of game world blocks. Later on, you can also add bulk methods to furtherly optimize performance; for example one that will check if all blocks in a given cube are empty, or count the number of wood blocks, something along those lines. But in the beginning, better leave out those methods, or make trivial implementations that rely on calling the abstract methods repeatedly. You can optimize them later.
Then you can provide a very simple Java/Scala implementation of that interface, which actually uses a three-dimensional array. An alternative would be a map whose keys are coordinates, and the values are block states. The advantage would be that there would be no real limit to the size of the game world, and empty blocks would not take up any memory (for coordinates with empty blocks, there is no entry in the map). The disadvantage can obviously be the performance.
At that point, you might want to consider packing the data more tightly, if it consumes too much memory. You can use bit sets. When you reach that stage, it actually makes sense to use JNI to inject some code written in C or C++ into the JVM. So you keep the game logic in Java/Scala, and do the memory packing and lookup in C.
There is no real point in creating a common "script" source that can create a Java/Scala and a C/C++ version of the native part of the code; the native C/C++ functions would rely heavily on optimizations that cannot be directly translated into Java. When you want to start the server in "pure Java/Scala mode", i.e. without the JNI functions, simply use the other classes that you created in the step before. They might be a little slower, but they are pure JVM byte code. And since you kept them simple, there is no danger that you have to extend them wildly or introduce new bugs into them. At least, the overhead of creating or adapting a cross-programming-language code generator is far, far bigger than keeping two separate code bases, especially when the Java/Scala implementation is really simple.
Of course, bit packing only gets you this far. You might want to notice that some parts of the game world are almost completely empty (especially those above the surface), and others contain huge areas filled with blocks of the same types (like underground areas that consist almost solely out of stone). Maintaining a huge memory structure with that much redundancy is really a waste of memory. So you will probably consider packing the game world in a tree, where each node stands for a big cubical area of the game world, and the children subdivide it further, down to leaves that describe the contents of just one specific game world coordinate. When one node has only children of the same content type, you do not need to store the children. Simply cut the tree at this point and have the node say, "You don't need to look further. I am full of water, so every coordinate that is inside of me points to a water tile." - This will greatly reduce the memory usage. Only the parts of the game world that are actually complex will consume a lot of memory, and rightly so. The more boring parts of the world occupy only a few nodes in the tree. This is good. And since it is a tree, traversing it from the top to a leaf takes logarithmic time in average. This is very good! - Of course, you have to keep the tree mutable. If a boring part of the world that is represented by only one node changes, you need to break open that node and split it into two or more children. Should it become simple again afterwards, you can join the children again and cut the tree.
One thing you might notice at this point is: Memory packing and access optimization is not really an issue here any more. A tree like this cannot be reasonably optimized by using native functions for the storage and lookup methods. If you can gain more than, say, 10% out of such an optimization, this would be highly improbable and hugely impressive. (More probably though, this might mean that the Java/Scala counterparts were badly optimized.) Such a minimal speed gain does not justify the huge extra effort that needs to be put into it. Rather put a better CPU into the machine and enjoy the time you saved by eating ice cream, watching Dr. House or continuing to enhance the game further and make it more interesting and attractive for the players. By creating something valuable that will really improve the product.
But this still is not it. If I remember correctly, the initial state of a Minecraft world is procedurally generated. Using fractal algorithms, you can really create endless territories that feel complex and natural in the blink of an eye. So instead of pre-computing the contents of the game world and storing it in a huge datastructure, you might want to use the world generation procedure as a lookup method: Instead of looking up the contents of a coordinate from memory, simply calculate it using the algorithm. In this way, the initial state of the world can be fully stored in four bytes: the seed value of the algorithm.
Of course, the world will not always stay in this state. When the player (or something else) changes the world, then this is something that you need to store. So you store only the world's seed value and the changes made to it. Whenever you look up the contents of a coordinate, try to find it in the changed tile storage. When it's there, use that information. When it's not there, default to the procedural world generation algorithm. This will make your memory consumption decrease enormously. And since the changes to the world are relatively small and contain huge empty areas, it should be relatively easy for you to write a data structure that stores those changes quickly and efficiently. Again, writing native code for this would not yield a significant performance gain and is not worth the effort.
Something else can be optimized though: the procedural world generation algorithm. This is the one key component that you might want to write in C or C++. It should be relatively small and not much code, but it is math intensive and will be called very often. So optimize it good and make a small JNI library out of it. This will give you a huge performance boost that is worth the effort. (Of course, you might want to do a Java/Scala implementation first. If that's already fast enough, then there is no need to get into the JNI trouble.)
If your world generation procedure should still be too slow, then you can implement a cache for it. The cache can even preemptively generate some of the player's surroundings when the JVM has some lazy time.
I laid out this development process for you as an iteration of several ideas, one better than the previous one. Image you would have started writing libraries of optimized C/C++ code already at the first stage. It would have been a waste of time; you could have thrown it all away in the later stages. An efficient array storage that employs bit packing, written in C, is a nice thing, but it is of absolutely no use when you reorganize your world into a binary space partitioned tree.
So, don't overdo it. When you cannot create a minimally working (yet slow and unoptimized) version in Java/Scala alone, then you cannot create an optimized version in C/C++ or some cross-compiling scripting language as well. Do simple versions first, then do performance tests, and only optimize when there is a real need. Don't start off your project by making concepts for optimizations first. Optimizations of this kind should be the last things that you will be working on.