An arbitrary Long is about 19.5 ASCII digits long, but only 8 bytes long, so you'll gain a savings of a factor of ~2 if you write it in binary. Now, it may be that most of the values are not actually taking all 8 bytes, in which case you could define some compression scheme yourself.
In any case, you are probably best off writing block data using java.nio.ByteBuffer and friends. Binary data is most efficiently read in blocks, and you might want your file to be randomly accessible, in which case you want your data to look something like so:
<some unique binary header that lets you check the file type>
<int saying how many records you have>
<offset of the first record>
<offset of the second record>
...
<offset of the last record>
<int><int><length of vector><long><long>...<long>
<int><int><length of vector><long><long>...<long>
...
<int><int><length of vector><long><long>...<long>
This is a particularly convenient format for reading and writing using ByteBuffer because you know in advance how big everything is going to be. So you can
val fos = new FileOutputStream(myFileName)
val fc = fos.getChannel // java.nio.channel.FileChannel
val header = ByteBuffer.allocate(28)
header.put("This is my cool header!!".getBytes)
header.putInt(data.length)
fc.write(header)
val offsets = ByteBuffer.allocate(8*data.length)
data.foldLeft(28L+8*data.length){ (n,d) =>
offsets.putLong(n)
n = n + 12 + d.vector.length*8
}
fc.write(offsets)
...
and on the way back in
val fis = new FileInputStream(myFileName)
val fc = fis.getChannel
val header = ByteBuffer.allocate(28)
fc.read(header)
val hbytes = new Array[Byte](24)
header.get(hbytes)
if (new String(hbytes) != "This is my cool header!!") ???
val nrec = header.getInt
val offsets = ByteBuffer.allocate(8*nrec)
fc.read(offsets)
val offsetArray = offsets.getLongs(nrec) // See below!
...
There are some handy methods on ByteBuffer that are absent, but you can add them on with implicits (here for Scala 2.10; with 2.9 make it a plain class, drop the extends AnyVal, and supply an implicit conversion from ByteBuffer to RichByteBuffer):
implicit class RichByteBuffer(val b: java.nio.ByteBuffer) extends AnyVal {
def getBytes(n: Int) = { val a = new Array[Byte](n); b.get(a); a }
def getShorts(n: Int) = { val a = new Array[Short](n); var i=0; while (i<n) { a(i)=b.getShort(); i+=1 } ; a }
def getInts(n: Int) = { val a = new Array[Int](n); var i=0; while (i<n) { a(i)=b.getInt(); i+=1 } ; a }
def getLongs(n: Int) = { val a = new Array[Long](n); var i=0; while (i<n) { a(i)=b.getLong(); i+=1 } ; a }
def getFloats(n: Int) = { val a = new Array[Float](n); var i=0; while (i<n) { a(i)=b.getFloat(); i+=1 } ; a }
def getDoubles(n: Int) = { val a = new Array[Double](n); var i=0; while (i<n) { a(i)=b.getDouble(); i+=1 } ; a }
}
Anyway, the reason to do things this way is that you'll end up with decent performance, which is also a consideration when you have tens of gigabytes of data (which it sounds like you have given hundreds of thousands of vectors of length up to ten thousand).
If your problem is actually much smaller, then don't worry so much about it--pack it into XML or use JSON or some custom text solution (or use DataOutputStream and DataInputStream, which don't perform as well and won't give you random access).
If your problem is actually bigger, you can define two lists of longs; first, the ones that will fit in an Int, say, and then the ones that actually need a full Long (with indices so you know where they are). Data compression is a very case-specific task--assuming you don't just want to use java.util.zip--so without a lot more knowledge about what the data looks like, it's hard to know what to recommend beyond just storing it as a weakly hierarchical binary file as I've described above.
