The technique generates thread-safe code in that it protects your java variables from read/write interruptions from multiple threads. However, that doesn't mean that your code is correct. Sometimes synchronization applies to sequences of execution that aren't well represented by a single method. Imagine a routine that accepts a rectangle and sets the width and length equal to 5. Imagine another routine on a different thread that accepts a rectangle and sets the width equal to 3 and the length equal to 6. Even though setWidth and setLength are synchronized, thread one can set the width, thread two can set the width and the length, and thread one can set the length. Now the rectangle has width 5 and length 6. This is not correct according to either thread. Note, if the rectangle was immutable, this particular problem wouldn't happen.
Here's an example that comes up in larger systems. Imagine a distributed system where you need to synchronize two files on two machines. You need to obtain some sort of synchronization lock on each file. If many different threads are in contention for different files, you need a mechanism to establish who gets the lock. There are a variety of schemes for handling this, so it isn't an unknown problem, but you can see that it isn't just as simple as two private variables in a single object.
Now, your follow-up: what are the downsides? If you have an immutable resource, there's probably no need to protect against multiple reads by different threads. As a consequence, the additional overhead of the synchronization code is unnecessary. Your program, while correct, is slower than another correct program implemented with the same algorithms just because of unnecessary synchronization.