- Created by Paul Sharp, last modified on Apr 01, 2022
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Introduction
This page deals with vectorization and optimization of Radioss Fortran code. This is a fundamental aspect of the code that needs to be well understood and learned by new Radioss programmers. Breaking performance of current code is not allowed. Furthermore, new functionality should be developed taking into account the same level of care regarding performance.
Vectorization deals with the execution of computational loops. It allows a computer to compute several loop indexes during the same cycle leveraging vector registers. This concept was first introduced on vector supercomputers (CRAY, NEC, FUJITSU…)
Nonetheless, though there are no more vector supercomputers, vectorization is reintroduced on modern CPUs like Xeon processor with AVX and AVX512
For instance, AVX512 first introduced into Intel Xeon Phi Knights Landing and Xeon Skylake allows the handling of 8x 64-bit double precision real at the same time or 16x single precision
Vectorization
Vector Length
Most computations in Radioss, like element or contact forces, are performed by packets of MVSIZ
. This parameter is adjustable to match so-called vector length. This parameter is also important for cache locality. It is optimized by parallel development team according to hardware characteristics
New treatments need to respect this programming model which is to split the loop over number of elements or nodes by packets of MVSIZ
. This will ensure optimal vector length and cache size as well as minimal local storage (local arrays of size MVSIZ
instead of number of elements or nodes)
Loop Control
| It is recommended to minimize the use of Every time a test does not depend on loop index value, it is asked to perform it outside of such loop |
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Loop Size
Inside a loop it is recommended to keep the number of instructions reasonable. 20 instructions or less is good. Very long loops should be split to keep cache efficiency
Most compilers will be able to fuse short loops, while they will probably fail to vectorize long complex loops
Data Dependency
The loop below is not vectorized due to possible dependence (same value of INDEX(I)
for different I
):
DO I = 1, N K = INDEX(I) A(K) = B(K) B(K) = 2*A(K) END DO
In case of no true dependence, vectorization needs to be forced by adding a compiler directive
To keep portability across different platforms and compilers, an architecture specific include file exists named vectorize.inc that manages vectorization directives. The programmer just needs to add this include file just before the DO
loop:
#include "vectorize.inc" DO I = 1, N K = INDEX(I) A(K) = B(K) B(K) = 2*A(K) END DO
Notice there is another include file named simd.inc which makes unconditional vectorization, even if a true dependence is detected by the compiler. It is recommended to only use vectorise.inc which is more conservative regarding correctness
For Intel compiler:
vectorize.inc corresponds to !DIR$ IVDEP
simd.inc corresponds to !DIR$ SIMD
Procedure CALL
Calling a procedure inside a loop inhibits vectorization therefore it is not authorized
Inside Radioss, there are vectorized versions of procedures, basically the loop is put inside the procedure rather than outside:
VALPVEC
to replaceJACOBIEW
VINTER
to replaceFINTER
Nested Loops
In practice, only the inner most loop will be vectorized. So the inner most loop needs to be the largest one.
For fixed size loops it is possible to unroll them by hand or to use Fortran90 enhancement. Then the compiler is able to vectorize the outer loop
Unroll by hand is not enough on AVX512 or SSE architectures
Only Fortran 90 syntax helps in this case
Example Nested Loop with NEL >> DIM
DO I = 1, NEL DO J=1, DIM A(I,J) = B(I,J) + C(I,J) END DO END DO
To be transformed to:
DO J=1, DIM DO I = 1, NEL A(I,J) = B(I,J) + C(I,J) END DO END DO
Or using Fortran90 notation:
DO I=1,NEL A(I,:DIM)=B(I,:DIM) + C(I,:DIM) END DO
Or for this simple case:
A(:NEL,:DIM)=B(:NEL,:DIM) + C(:NEL,:DIM)
Arithmetic Functions
Power
Never use real variable for integer power because of the cost of real power arithmetic. Take
care to not use real variable defined in constant.inc when integer is enough
| Allowed |
| Forbidden as DEUX is a |
| here there is no other choice as a real power arithmetic is required |
Div
For invariant, it is advised to multiply by invert instead of doing a division by a constant inside a loop
Arrays
Fortran90 Array Operations
Use of Fortran90 array operations is encouraged as long as code readability is kept, by always specifying array bounds to avoid confusion between variable and array arithmetic.
Example:
INTEGER, DIMENSION(NUMNOD) :: A, B, C A = B + C
! confusion between variable and array operation
A(:NUMNOD) = B(:NUMNOD) + C(:NUMNOD)
! default lower bound:1
Multidimensional Arrays
Data Locality
Large arrays over a number of nodes or elements are defined to maximize data locality and have therefore the smallest dimension first, like in the example below:
X(3,NUMNOD), V(3,NUMNOD), A(3,NUMNOD)
Leading Dimension for Vectorization
For vectorization on Xeon, it is better to have leading dimension first. So, depending on array size and access pattern a compromise needs to be found:
For large arrays like X, V, A, it is better to keep locality
For data structure of few times
MVSIZ
, like new element buffer arrays or temporary arrays of size x timesMVSIZ
, having largest dimension first is better:
HOUR (MVSIZ,5)
better than HOUR(5,MVSIZ)
According to test with recent Intel compiler, Fortran90 array notation can also improve code generated:
A(I,1:3) = B(I,1:3) + C(I,1:3)
no need to unroll loop
Structure Of Arrays
Use structure of arrays (left example) rather than arrays of structure (right example)
Correct | Incorrect |
---|---|
TYPE GRID_STRUCT_ my_real :: x(100),y(100),z(100) END TYPE GRID_STRUCT_
| TYPE POINT_STRUCT_ my_real :: x, y, z END TYPE POINT_STRUCT_
|
TYPE(GRID_STRUCT_) MESH; ! a grid of 3 arrays x, y, z of size 100
| TYPE(POINT_STRUCT_) P(100); ! an array of size 100 of 3 scalars x, y, z |
Warning On Large Array Initialization
Especially inside Radioss Starter it is common to find code using large array flag over NUMNOD
initialized to zero many times which is time consuming
Here is a method to avoid such an issue: left is original poorly performing code, right is optimized version
Original (Poor Performance) | Optimized Code |
---|---|
DO I=1, IX_TIMES !IX_TIMES set to 0 TAG(1:NUMNOD)=0 DO J=1,FEW_ITEMS N = INDEX(I,J) IF(TAG(N) == 0)THEN ! but few values change TAG(N)=1 ! additional treatments… END IF END DO END DO
| ! single init to 0 TAG(1:NUMNOD)=0 DO I=1, IX_TIMES DO J=1,FEW_ITEMS N = INDEX(I,J) IF(TAG(N) == 0)THEN TAG(N)=1 ! additional treatments… END IF END DO ! set to 0 only if needed DO J=1 , FEW_ITEMS N = INDEX(I,J) TAG(N) = 0 END DO END DO |
Additional Fortran90 Restrictions Regarding Efficiency
Operator Overloading
Usage of object oriented feature like operator overloading, while it is efficient in code writing and clarity is not recommended due to lack of performance efficiency
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