org.tukaani.xz.ArrayCache Maven / Gradle / Ivy
/*
* ArrayCache
*
* Author: Lasse Collin
*
* This file has been put into the public domain.
* You can do whatever you want with this file.
*/
package org.tukaani.xz;
/**
* Caches large arrays for reuse (base class and a dummy cache implementation).
*
* When compressing or decompressing many (very) small files in a row, the
* time spent in construction of new compressor or decompressor objects
* can be longer than the time spent in actual compression or decompression.
* A large part of this initialization overhead comes from allocation and
* garbage collection of large arrays.
*
* The {@code ArrayCache} API provides a way to cache large array allocations
* for reuse. It can give a major performance improvement when compressing or
* decompressing many tiny files. If you are only (de)compressing one or two
* files or the files a very big, array caching won't improve anything,
* although it won't make anything slower either.
*
* Important: The users of ArrayCache don't return the allocated arrays
* back to the cache in all situations.
* This a reason why it's called a cache instead of a pool.
* If it is important to be able to return every array back to a cache,
* {@link ResettableArrayCache} can be useful.
*
* In compressors (OutputStreams) the arrays are returned to the cache
* when a call to {@code finish()} or {@code close()} returns
* successfully (no exceptions are thrown).
*
* In decompressors (InputStreams) the arrays are returned to the cache when
* the decompression is successfully finished ({@code read} returns {@code -1})
* or {@code close()} or {@code close(boolean)} is called. This is true even
* if closing throws an exception.
*
* Raw decompressors don't support {@code close(boolean)}. With raw
* decompressors, if one wants to put the arrays back to the cache without
* closing the underlying {@code InputStream}, one can wrap the
* {@code InputStream} into {@link CloseIgnoringInputStream} when creating
* the decompressor instance. Then one can use {@code close()}.
*
* Different cache implementations can be extended from this base class.
* All cache implementations must be thread safe.
*
* This class also works as a dummy cache that simply calls {@code new}
* to allocate new arrays and doesn't try to cache anything. A statically
* allocated dummy cache is available via {@link #getDummyCache()}.
*
* If no {@code ArrayCache} is specified when constructing a compressor or
* decompressor, the default {@code ArrayCache} implementation is used.
* See {@link #getDefaultCache()} and {@link #setDefaultCache(ArrayCache)}.
*
* This is a class instead of an interface because it's possible that in the
* future we may want to cache other array types too. New methods can be
* added to this class without breaking existing cache implementations.
*
* @since 1.7
*
* @see BasicArrayCache
*/
public class ArrayCache {
/**
* Global dummy cache instance that is returned by {@code getDummyCache()}.
*/
private static final ArrayCache dummyCache = new ArrayCache();
/**
* Global default {@code ArrayCache} that is used when no other cache has
* been specified.
*/
private static volatile ArrayCache defaultCache = dummyCache;
/**
* Returns a statically-allocated {@code ArrayCache} instance.
* It can be shared by all code that needs a dummy cache.
*/
public static ArrayCache getDummyCache() {
return dummyCache;
}
/**
* Gets the default {@code ArrayCache} instance.
* This is a global cache that is used when the application
* specifies nothing else. The default is a dummy cache
* (see {@link #getDummyCache()}).
*/
public static ArrayCache getDefaultCache() {
// It's volatile so no need for synchronization.
return defaultCache;
}
/**
* Sets the default {@code ArrayCache} instance.
* Use with care. Other libraries using this package probably shouldn't
* call this function as libraries cannot know if there are other users
* of the xz package in the same application.
*/
public static void setDefaultCache(ArrayCache arrayCache) {
if (arrayCache == null)
throw new NullPointerException();
// It's volatile so no need for synchronization.
defaultCache = arrayCache;
}
/**
* Creates a new {@code ArrayCache} that does no caching
* (a dummy cache). If you need a dummy cache, you may want to call
* {@link #getDummyCache()} instead.
*/
public ArrayCache() {}
/**
* Allocates a new byte array.
*
* This implementation simply returns {@code new byte[size]}.
*
* @param size the minimum size of the array to allocate;
* an implementation may return an array that
* is larger than the given {@code size}
*
* @param fillWithZeros if true, the caller expects that the first
* {@code size} elements in the array are zero;
* if false, the array contents can be anything,
* which speeds things up when reusing a cached
* array
*/
public byte[] getByteArray(int size, boolean fillWithZeros) {
return new byte[size];
}
/**
* Puts the given byte array to the cache. The caller must no longer
* use the array.
*
* This implementation does nothing.
*/
public void putArray(byte[] array) {}
/**
* Allocates a new int array.
*
* This implementation simply returns {@code new int[size]}.
*
* @param size the minimum size of the array to allocate;
* an implementation may return an array that
* is larger than the given {@code size}
*
* @param fillWithZeros if true, the caller expects that the first
* {@code size} elements in the array are zero;
* if false, the array contents can be anything,
* which speeds things up when reusing a cached
* array
*/
public int[] getIntArray(int size, boolean fillWithZeros) {
return new int[size];
}
/**
* Puts the given int array to the cache. The caller must no longer
* use the array.
*
* This implementation does nothing.
*/
public void putArray(int[] array) {}
}