TL;DR due to modern computer architecture, ArrayList
will be significantly more efficient for nearly any possible use-case - and therefore LinkedList
should be avoided except some very unique and extreme cases.
In theory, LinkedList has an O(1) for the add(E element)
Also adding an element in the mid of a list should be very efficient.
Practice is very different, as LinkedList is a Cache Hostile Data structure. From performance POV - there are very little cases where LinkedList
could be better performing than the Cache-friendly ArrayList
.
Here are results of a benchmark testing inserting elements in random locations. As you can see - the array list if much more efficient, although in theory each insert in the middle of the list will require "move" the n later elements of the array (lower values are better):

Working on a later generation hardware (bigger, more efficient caches) - the results are even more conclusive:

LinkedList takes much more time to accomplish the same job. source Source Code
There are two main reasons for this:
Mainly - that the nodes of the LinkedList
are scattered randomly across the memory. RAM ("Random Access Memory") isn't really random and blocks of memory need to be fetched to cache. This operation takes time, and when such fetches happen frequently - the memory pages in the cache need to be replaced all the time -> Cache misses -> Cache is not efficient.
ArrayList
elements are stored on continuous memory - which is exactly what the modern CPU architecture is optimizing for.
Secondary LinkedList
required to hold back/forward pointers, which means 3 times the memory consumption per value stored compared to ArrayList
.
DynamicIntArray, btw, is a custom ArrayList implementation holding Int
(primitive type) and not Objects - hence all data is really stored adjacently - hence even more efficient.
A key elements to remember is that the cost of fetching memory block, is more significant than the cost accessing a single memory cell. That's why reader 1MB of sequential memory is up to x400 times faster than reading this amount of data from different blocks of memory:
Latency Comparison Numbers (~2012)
----------------------------------
L1 cache reference 0.5 ns
Branch mispredict 5 ns
L2 cache reference 7 ns 14x L1 cache
Mutex lock/unlock 25 ns
Main memory reference 100 ns 20x L2 cache, 200x L1 cache
Compress 1K bytes with Zippy 3,000 ns 3 us
Send 1K bytes over 1 Gbps network 10,000 ns 10 us
Read 4K randomly from SSD* 150,000 ns 150 us ~1GB/sec SSD
Read 1 MB sequentially from memory 250,000 ns 250 us
Round trip within same datacenter 500,000 ns 500 us
Read 1 MB sequentially from SSD* 1,000,000 ns 1,000 us 1 ms ~1GB/sec SSD, 4X memory
Disk seek 10,000,000 ns 10,000 us 10 ms 20x datacenter roundtrip
Read 1 MB sequentially from disk 20,000,000 ns 20,000 us 20 ms 80x memory, 20X SSD
Send packet CA->Netherlands->CA 150,000,000 ns 150,000 us 150 ms
Source: Latency Numbers Every Programmer Should Know
Just to make the point even clearer, please check the benchmark of adding elements to the beginning of the list. This is a use-case where, in-theory, the LinkedList
should really shine, and ArrayList
should present poor or even worse-case results:

Note: this is a benchmark of the C++ Std lib, but my previous experience shown the C++ and Java results are very similar. Source Code
Copying a sequential bulk of memory is an operation optimized by the modern CPUs - changing theory and actually making, again, ArrayList
/Vector
much more efficient
Credits: All benchmarks posted here are created by Kjell Hedström. Even more data can be found on his blog