LLVM has two vectorizers: The Loop Vectorizer, which operates on Loops, and the SLP Vectorizer. These vectorizers focus on different optimization opportunities and use different techniques. The SLP vectorizer merges multiple scalars that are found in the code into vectors while the Loop Vectorizer widens instructions in loops to operate on multiple consecutive iterations.
Both the Loop Vectorizer and the SLP Vectorizer are enabled by default.
The Loop Vectorizer is enabled by default, but it can be disabled through clang using the command line flag:
$ clang ... -fno-vectorize file.c
The loop vectorizer uses a cost model to decide on the optimal vectorization factor and unroll factor. However, users of the vectorizer can force the vectorizer to use specific values. Both ‘clang’ and ‘opt’ support the flags below.
Users can control the vectorization SIMD width using the command line flag “-force-vector-width”.
$ clang -mllvm -force-vector-width=8 ...
$ opt -loop-vectorize -force-vector-width=8 ...
Users can control the unroll factor using the command line flag “-force-vector-interleave”
$ clang -mllvm -force-vector-interleave=2 ...
$ opt -loop-vectorize -force-vector-interleave=2 ...
The #pragma clang loop directive allows loop vectorization hints to be specified for the subsequent for, while, do-while, or c++11 range-based for loop. The directive allows vectorization and interleaving to be enabled or disabled. Vector width as well as interleave count can also be manually specified. The following example explicitly enables vectorization and interleaving:
#pragma clang loop vectorize(enable) interleave(enable)
while(...) {
...
}
The following example implicitly enables vectorization and interleaving by specifying a vector width and interleaving count:
#pragma clang loop vectorize_width(2) interleave_count(2)
for(...) {
...
}
See the Clang language extensions for details.
Many loops cannot be vectorized including loops with complicated control flow, unvectorizable types, and unvectorizable calls. The loop vectorizer generates optimization remarks which can be queried using command line options to identify and diagnose loops that are skipped by the loop-vectorizer.
Optimization remarks are enabled using:
-Rpass=loop-vectorize identifies loops that were successfully vectorized.
-Rpass-missed=loop-vectorize identifies loops that failed vectorization and indicates if vectorization was specified.
-Rpass-analysis=loop-vectorize identifies the statements that caused vectorization to fail. If in addition -fsave-optimization-record is provided, multiple causes of vectorization failure may be listed (this behavior might change in the future).
Consider the following loop:
#pragma clang loop vectorize(enable)
for (int i = 0; i < Length; i++) {
switch(A[i]) {
case 0: A[i] = i*2; break;
case 1: A[i] = i; break;
default: A[i] = 0;
}
}
The command line -Rpass-missed=loop-vectorized prints the remark:
no_switch.cpp:4:5: remark: loop not vectorized: vectorization is explicitly enabled [-Rpass-missed=loop-vectorize]
And the command line -Rpass-analysis=loop-vectorize indicates that the switch statement cannot be vectorized.
no_switch.cpp:4:5: remark: loop not vectorized: loop contains a switch statement [-Rpass-analysis=loop-vectorize]
switch(A[i]) {
^
To ensure line and column numbers are produced include the command line options -gline-tables-only and -gcolumn-info. See the Clang user manual for details
The LLVM Loop Vectorizer has a number of features that allow it to vectorize complex loops.
The Loop Vectorizer supports loops with an unknown trip count. In the loop below, the iteration start and finish points are unknown, and the Loop Vectorizer has a mechanism to vectorize loops that do not start at zero. In this example, ‘n’ may not be a multiple of the vector width, and the vectorizer has to execute the last few iterations as scalar code. Keeping a scalar copy of the loop increases the code size.
void bar(float *A, float* B, float K, int start, int end) {
for (int i = start; i < end; ++i)
A[i] *= B[i] + K;
}
In the example below, if the pointers A and B point to consecutive addresses, then it is illegal to vectorize the code because some elements of A will be written before they are read from array B.
Some programmers use the ‘restrict’ keyword to notify the compiler that the pointers are disjointed, but in our example, the Loop Vectorizer has no way of knowing that the pointers A and B are unique. The Loop Vectorizer handles this loop by placing code that checks, at runtime, if the arrays A and B point to disjointed memory locations. If arrays A and B overlap, then the scalar version of the loop is executed.
void bar(float *A, float* B, float K, int n) {
for (int i = 0; i < n; ++i)
A[i] *= B[i] + K;
}
In this example the sum variable is used by consecutive iterations of the loop. Normally, this would prevent vectorization, but the vectorizer can detect that ‘sum’ is a reduction variable. The variable ‘sum’ becomes a vector of integers, and at the end of the loop the elements of the array are added together to create the correct result. We support a number of different reduction operations, such as addition, multiplication, XOR, AND and OR.
int foo(int *A, int *B, int n) {
unsigned sum = 0;
for (int i = 0; i < n; ++i)
sum += A[i] + 5;
return sum;
}
We support floating point reduction operations when -ffast-math is used.
In this example the value of the induction variable i is saved into an array. The Loop Vectorizer knows to vectorize induction variables.
void bar(float *A, float* B, float K, int n) {
for (int i = 0; i < n; ++i)
A[i] = i;
}
The Loop Vectorizer is able to “flatten” the IF statement in the code and generate a single stream of instructions. The Loop Vectorizer supports any control flow in the innermost loop. The innermost loop may contain complex nesting of IFs, ELSEs and even GOTOs.
int foo(int *A, int *B, int n) {
unsigned sum = 0;
for (int i = 0; i < n; ++i)
if (A[i] > B[i])
sum += A[i] + 5;
return sum;
}
This example uses the “accumulate” function of the standard c++ library. This loop uses C++ iterators, which are pointers, and not integer indices. The Loop Vectorizer detects pointer induction variables and can vectorize this loop. This feature is important because many C++ programs use iterators.
int baz(int *A, int n) {
return std::accumulate(A, A + n, 0);
}
The Loop Vectorizer can vectorize loops that count backwards.
int foo(int *A, int *B, int n) {
for (int i = n; i > 0; --i)
A[i] +=1;
}
The Loop Vectorizer can vectorize code that becomes a sequence of scalar instructions that scatter/gathers memory.
int foo(int * A, int * B, int n) {
for (intptr_t i = 0; i < n; ++i)
A[i] += B[i * 4];
}
In many situations the cost model will inform LLVM that this is not beneficial and LLVM will only vectorize such code if forced with “-mllvm -force-vector-width=#”.
The Loop Vectorizer can vectorize programs with mixed types. The Vectorizer cost model can estimate the cost of the type conversion and decide if vectorization is profitable.
int foo(int *A, char *B, int n, int k) {
for (int i = 0; i < n; ++i)
A[i] += 4 * B[i];
}
Access to global structures can also be vectorized, with alias analysis being used to make sure accesses don’t alias. Run-time checks can also be added on pointer access to structure members.
Many variations are supported, but some that rely on undefined behaviour being ignored (as other compilers do) are still being left un-vectorized.
struct { int A[100], K, B[100]; } Foo;
int foo() {
for (int i = 0; i < 100; ++i)
Foo.A[i] = Foo.B[i] + 100;
}
The Loop Vectorize can vectorize intrinsic math functions. See the table below for a list of these functions.
pow | exp | exp2 |
sin | cos | sqrt |
log | log2 | log10 |
fabs | floor | ceil |
fma | trunc | nearbyint |
fmuladd |
The loop vectorizer knows about special instructions on the target and will vectorize a loop containing a function call that maps to the instructions. For example, the loop below will be vectorized on Intel x86 if the SSE4.1 roundps instruction is available.
void foo(float *f) {
for (int i = 0; i != 1024; ++i)
f[i] = floorf(f[i]);
}
Modern processors feature multiple execution units, and only programs that contain a high degree of parallelism can fully utilize the entire width of the machine. The Loop Vectorizer increases the instruction level parallelism (ILP) by performing partial-unrolling of loops.
In the example below the entire array is accumulated into the variable ‘sum’. This is inefficient because only a single execution port can be used by the processor. By unrolling the code the Loop Vectorizer allows two or more execution ports to be used simultaneously.
int foo(int *A, int *B, int n) {
unsigned sum = 0;
for (int i = 0; i < n; ++i)
sum += A[i];
return sum;
}
The Loop Vectorizer uses a cost model to decide when it is profitable to unroll loops. The decision to unroll the loop depends on the register pressure and the generated code size.
This section shows the execution time of Clang on a simple benchmark: gcc-loops. This benchmarks is a collection of loops from the GCC autovectorization page by Dorit Nuzman.
The chart below compares GCC-4.7, ICC-13, and Clang-SVN with and without loop vectorization at -O3, tuned for “corei7-avx”, running on a Sandybridge iMac. The Y-axis shows the time in msec. Lower is better. The last column shows the geomean of all the kernels.
And Linpack-pc with the same configuration. Result is Mflops, higher is better.
The goal of SLP vectorization (a.k.a. superword-level parallelism) is to combine similar independent instructions into vector instructions. Memory accesses, arithmetic operations, comparison operations, PHI-nodes, can all be vectorized using this technique.
For example, the following function performs very similar operations on its inputs (a1, b1) and (a2, b2). The basic-block vectorizer may combine these into vector operations.
void foo(int a1, int a2, int b1, int b2, int *A) {
A[0] = a1*(a1 + b1)/b1 + 50*b1/a1;
A[1] = a2*(a2 + b2)/b2 + 50*b2/a2;
}
The SLP-vectorizer processes the code bottom-up, across basic blocks, in search of scalars to combine.
The SLP Vectorizer is enabled by default, but it can be disabled through clang using the command line flag:
$ clang -fno-slp-vectorize file.c
LLVM has a second basic block vectorization phase which is more compile-time intensive (The BB vectorizer). This optimization can be enabled through clang using the command line flag:
$ clang -fslp-vectorize-aggressive file.c