When passing two arrays from java to c++ through JNI, there are three obstacles against using c++ intrinsics(or asm-inline) to boost performance.
1)JNI calling has an overhead(as expected, 20 cycles to 100 cycles)
2)Arrays are passed as mis-aligned(needed 32B or 16B alignement) so one needs to shift whole two arrays to make them aligned then in the end shift-back to old position.
3)Creating a new array to send the results to java(example: vector multiplication C=A*B) If we supply an array from java, it will be mis-aligned too! So we need to create a new aligned array in c++ which slows down the whole process.
Rather than shifting two arrays, we can make a single bigger array to concatenate two arrays but that would be slow too.
What is the point of using JNI for performance if we can use only (less-data,more-compute) structs?
--Using pure c++(no intrinsic) in JNI makes just %10-%20 faster then pure java.
--Using intrinsics increased the multiplications/s by %70 but slow array copying is still in effect. Only %50 chance that java moves its arrays into a 32B aligned position.
GetPrimitiveArrayCritical instead of
GetArrayElements() gave another %250 performance to the dot-product of big vectors(256k elements). Which must be the result of shutting gc-down for the moment of JNI work and non-copy-accessing.
--Using Direct Byte Buffer instead of primitive arrays is %40(5x-6x on top of pure java) faster on my machine. Also lets me choose a custom offset in it with help of native-address chooser to make it 32B aligned. So we can have 32B aligned sub-set of a direct buffer(in "C" space) but not a primitive array.
-- Dividing a big buffer into 8 parts and into 8 java threads, made the calculation another %40 faster compared to single directbytebuffer(This may be close to limit of my ram since I only do a single multiplication per element)
Total speed ratio of latest case vs java's loop-unrolled multiplication for single thread was nearly 6x, after I applied multithreading it increased to 8x(not much because of memory bandwidth, not the compute limit) for this particular dot-product.
What can you add to overcome three difficulties above?
How can we pass 32B-aligned arrays from java to c++ through JNI?