openmp/docs/remarks/OMP110.rst - llvm-project - Git at Google

 .. _omp110:

 Moving globalized variable to the stack. [OMP110]
 =================================================

 This optimization remark indicates that a globalized variable was moved back to
 thread-local stack memory on the device. This occurs when the optimization pass
 can determine that a globalized variable cannot possibly be shared between
 threads and globalization was ultimately unnecessary. Using stack memory is the
 best-case scenario for data globalization as the variable can now be stored in
 fast register files on the device. This optimization requires full visibility of
 each variable.

 Globalization typically occurs when a pointer to a thread-local variable escapes
 the current scope. The compiler needs to be pessimistic and assume that the
 pointer could be shared between multiple threads according to the OpenMP
 standard. This is expensive on target offloading devices that do not allow
 threads to share data by default. Instead, this data must be moved to memory
 that can be shared, such as shared or global memory. This optimization moves the
 data back from shared or global memory to thread-local stack memory if the data
 is not actually shared between the threads.

 Examples
 --------

 A trivial example of globalization occurring can be seen with this example. The
 compiler sees that a pointer to the thread-local variable ``x`` escapes the
 current scope and must globalize it even though it is not actually necessary.
 Fortunately, this optimization can undo this by looking at its usage.

 .. code-block:: c++

   void use(int *x) { }

   void foo() {
     int x;
     use(&x);
   }

   int main() {
   #pragma omp target parallel
     foo();
   }

 .. code-block:: console

   $ clang++ -fopenmp -fopenmp-targets=nvptx64 omp110.cpp -O1 -Rpass=openmp-opt
   omp110.cpp:6:7: remark: Moving globalized variable to the stack. [OMP110]
     int x;
         ^

 A less trivial example can be seen using C++'s complex numbers. In this case the
 overloaded arithmetic operators cause pointers to the complex numbers to escape
 the current scope, but they can again be removed once the usage is visible.

 .. code-block:: c++

   #include <complex>

   using complex = std::complex<double>;

   void zaxpy(complex *X, complex *Y, const complex D, int N) {
   #pragma omp target teams distribute parallel for firstprivate(D)
     for (int i = 0; i < N; ++i)
       Y[i] = D * X[i] + Y[i];
   }

 .. code-block:: console

   $ clang++ -fopenmp -fopenmp-targets=nvptx64 omp110.cpp -O1 -Rpass=openmp-opt
   In file included from omp110.cpp:1:
   In file included from /usr/bin/clang/lib/clang/13.0.0/include/openmp_wrappers/complex:27:
   /usr/include/c++/8/complex:328:20: remark: Moving globalized variable to the stack. [OMP110]
         complex<_Tp> __r = __x;
                      ^
   /usr/include/c++/8/complex:388:20: remark: Moving globalized variable to the stack. [OMP110]
         complex<_Tp> __r = __x;
                      ^

 Diagnostic Scope
 ----------------

 OpenMP target offloading optimization remark.
	.. _omp110:

	Moving globalized variable to the stack. [OMP110]
	=================================================

	This optimization remark indicates that a globalized variable was moved back to
	thread-local stack memory on the device. This occurs when the optimization pass
	can determine that a globalized variable cannot possibly be shared between
	threads and globalization was ultimately unnecessary. Using stack memory is the
	best-case scenario for data globalization as the variable can now be stored in
	fast register files on the device. This optimization requires full visibility of
	each variable.

	Globalization typically occurs when a pointer to a thread-local variable escapes
	the current scope. The compiler needs to be pessimistic and assume that the
	pointer could be shared between multiple threads according to the OpenMP
	standard. This is expensive on target offloading devices that do not allow
	threads to share data by default. Instead, this data must be moved to memory
	that can be shared, such as shared or global memory. This optimization moves the
	data back from shared or global memory to thread-local stack memory if the data
	is not actually shared between the threads.

	Examples
	--------

	A trivial example of globalization occurring can be seen with this example. The
	compiler sees that a pointer to the thread-local variable ``x`` escapes the
	current scope and must globalize it even though it is not actually necessary.
	Fortunately, this optimization can undo this by looking at its usage.

	.. code-block:: c++

	void use(int *x) { }

	void foo() {
	int x;
	use(&x);
	}

	int main() {
	#pragma omp target parallel
	foo();
	}

	.. code-block:: console

	$ clang++ -fopenmp -fopenmp-targets=nvptx64 omp110.cpp -O1 -Rpass=openmp-opt
	omp110.cpp:6:7: remark: Moving globalized variable to the stack. [OMP110]
	int x;
	^

	A less trivial example can be seen using C++'s complex numbers. In this case the
	overloaded arithmetic operators cause pointers to the complex numbers to escape
	the current scope, but they can again be removed once the usage is visible.

	.. code-block:: c++

	#include <complex>

	using complex = std::complex<double>;

	void zaxpy(complex X, complex Y, const complex D, int N) {
	#pragma omp target teams distribute parallel for firstprivate(D)
	for (int i = 0; i < N; ++i)
	Y[i] = D * X[i] + Y[i];
	}

	.. code-block:: console

	$ clang++ -fopenmp -fopenmp-targets=nvptx64 omp110.cpp -O1 -Rpass=openmp-opt
	In file included from omp110.cpp:1:
	In file included from /usr/bin/clang/lib/clang/13.0.0/include/openmp_wrappers/complex:27:
	/usr/include/c++/8/complex:328:20: remark: Moving globalized variable to the stack. [OMP110]
	complex<_Tp> __r = __x;
	^
	/usr/include/c++/8/complex:388:20: remark: Moving globalized variable to the stack. [OMP110]
	complex<_Tp> __r = __x;
	^

	Diagnostic Scope
	----------------

	OpenMP target offloading optimization remark.