The actual memory overhead implied by an object instance depends on some internal details of the JVM implementation, and may be hard to define because it can change throughout the lifetime of the object (within the garbage collector, an object can "move" between generations which use distinct memory management structures).
A very rough approximation is that each instance of any object includes two "words" (two 32-bit values on a 32-bit machine, two 64-bit values on a 64-bit machines); one of the words is more or less a pointer to the
Class instance for that object, the other holds some object state such as the monitor for that object (the one you lock with
synchronized). Then there are the object fields. For an array, the array length must be written somewhere in the object, and also the values.
At that point, have a look at the source code for the Java classes (look for a file named
src.zip in the JDK distribution). In the
String.java file, we can see that, internally, a
String instance has four fields: a reference to an array of
char values, and three
int (one is the index of the first string character within the array, the second is the string length, and the third caches the string hashcode). So, for a 32-bit machine, you can estimate that the minimal memory usage for a
String instance of n characters is the sum of:
- two 32-bit words for the
String instance object header
- four 32-bit words for the
String instance field
- three 32-bit words for the array instance header and length
- n 16-bit words for the characters themselves (a
char is 16-bit)
That's only a minimum because the
String instance only references a chunk of the internal character array, so the array memory size could be larger. On the other hand, the array of characters may be shared between several
String instances. This structures allows
String.substring() to be very fast: the new
String instance internally uses the same array , so there is no data copying involved; but it also means that if you have a big string, take a small substring of it, and store that small substring, you are actually retaining the big array in RAM as well (for a
str, you can make
new String(str) to get a new instance which will internally use a newly allocated and trimmed down array instance). On the bright side, if you have two strings, one being a substring of the other, and you store both in your cache, then you pay only once for the common internal array.
Hence, even without considering all the hidden costs implied by the GC, it is quite hard to know what "memory size for a string" means: if two
String instances share the same internal array, how do you count the "size" of each string ?
Looking at the source for
HashMap will show you that there are internal instances which are also allocated; there is an array of
HashMap.Entry instances, and one
HashMap.Entry instance for every stored value. The array size is dynamically adjusted depending on the number of entries and the configured load factor.
Since accounting for the memory size is hard, an altogether different solution is to let the GC itself decide when old cache entries should be removed. This internally uses "soft references": they are some kind of pointers which the GC may set to
null when memory becomes tight (breaking references may allow the GC to free more objects). This makes for a crude "memory-aware" cache which is automatically pruned depending on the available RAM. A useful library for that is Google's Guava and its MapMaker class.