final/docs/ReleaseNotes.rst - polly - Git at Google

 ========================
 Release Notes (upcoming)
 ========================

 In Polly 3.9 the following important changes have been incorporated.

 Polly directly available in clang/opt/bugpoint
 ----------------------------------------------

 Polly supported since a long time to be directly linked into tools such as
 opt/clang/bugpoint. Since this release, the default for a source checkout that
 contains Polly is to provide Polly directly through these tools, rather than as
 an additional module. This makes using Polly significantly easier.

 Instead of

 .. code-block:: bash

     opt -load lib/LLVMPolly.so -O3 -polly file.ll
     clang -Xclang -load -Xclang lib/LLVMPolly.so -O3 -mllvm -polly file.ll

 one can now use

 .. code-block:: bash

     opt -O3 -polly file.ll
     clang -O3 -mllvm -polly file.c


 Increased analysis coverage
 ---------------------------

 Polly's modeling has been improved to increase the applicability of Polly. The
 following code pieces are newly supported:

 Arrays accessed through different types
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 It is not uncommon that one array stores elements of different types. Polly now
 can model and optimize such code.

 .. code-block:: c

     void multiple_types(char *Short, char *Float, char *Double) {
       for (long i = 0; i < 100; i++) {
         Short[i] = *(short *)&Short[2 * i];
         Float[i] = *(float *)&Float[4 * i];
         Double[i] = *(double *)&Double[8 * i];
       }
     }


 If the accesses are not aligned with the size of the access type we model them
 as multiple accesses to an array of smaller elements. This is especially
 useful for structs containing different typed elements as accesses to them are
 represented using only one base pointer, namely the ``struct`` itself.  In the
 example below the accesses to ``s`` are all modeled as if ``s`` was a single
 char array because the accesses to ``s->A`` and ``s->B`` are not aligned with
 their respective type size (both are off-by-one due to the ``char`` field in
 the ``struct``).

 .. code-block:: c

     struct S {
       char Offset;
       int A[100];
       double B[100];
     };

     void struct_accesses(struct S *s) {
       for (long i = 0; i < 100; i++)
         s->B[i] += s->A[i];
     }


 Function calls with known side effects
 ^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

 Function calls that have only known memory effects can be represented as
 accesses in the polyhedral model. While calls without side effects were
 supported before, we now allow and model two other kinds. The first are
 intrinsic calls to ``memcpy``, ``memmove`` and ``memset``. These calls can be
 represented precisely if the pointers involved are known and the given length
 is affine. Additionally, we allow to over-approximate function calls that are
 known only to read memory, read memory accessible through pointer arguments or
 access only memory accessible through pointer arguments. See also the function
 attributes ``readonly`` and ``argmemonly`` for more information.

 Fine-grain dependences analysis
 -------------------------------

 In addition of the ScopStmt wise dependences analysis, now the "polly-dependence"
 pass provides dependences analysis at memory reference wise and memory access wise.
 The memory reference wise analysis distinguishes the accessed references in the
 same statement, and generates dependences relationships between (statement, reference)
 pairs. The memory access wise analysis distinguishes accesses in the same statement,
 and generates dependences relationships between (statement, access) pairs. These
 fine-grain dependences are enabled by "-polly-dependences-analysis-level=reference-wise"
 and "-polly-dependences-analysis-level=access-wise", respectively.

 Update of the isl math library
 ------------------------------

 We imported the latest version of the isl math library into Polly.
	========================
	Release Notes (upcoming)
	========================

	In Polly 3.9 the following important changes have been incorporated.

	Polly directly available in clang/opt/bugpoint
	----------------------------------------------

	Polly supported since a long time to be directly linked into tools such as
	opt/clang/bugpoint. Since this release, the default for a source checkout that
	contains Polly is to provide Polly directly through these tools, rather than as
	an additional module. This makes using Polly significantly easier.

	Instead of

	.. code-block:: bash

	opt -load lib/LLVMPolly.so -O3 -polly file.ll
	clang -Xclang -load -Xclang lib/LLVMPolly.so -O3 -mllvm -polly file.ll

	one can now use

	.. code-block:: bash

	opt -O3 -polly file.ll
	clang -O3 -mllvm -polly file.c


	Increased analysis coverage
	---------------------------

	Polly's modeling has been improved to increase the applicability of Polly. The
	following code pieces are newly supported:

	Arrays accessed through different types
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	It is not uncommon that one array stores elements of different types. Polly now
	can model and optimize such code.

	.. code-block:: c

	void multiple_types(char Short, char Float, char *Double) {
	for (long i = 0; i < 100; i++) {
	Short[i] = (short )&Short[2 * i];
	Float[i] = (float )&Float[4 * i];
	Double[i] = (double )&Double[8 * i];
	}
	}


	If the accesses are not aligned with the size of the access type we model them
	as multiple accesses to an array of smaller elements. This is especially
	useful for structs containing different typed elements as accesses to them are
	represented using only one base pointer, namely the ``struct`` itself. In the
	example below the accesses to ``s`` are all modeled as if ``s`` was a single
	char array because the accesses to ``s->A`` and ``s->B`` are not aligned with
	their respective type size (both are off-by-one due to the ``char`` field in
	the ``struct``).

	.. code-block:: c

	struct S {
	char Offset;
	int A[100];
	double B[100];
	};

	void struct_accesses(struct S *s) {
	for (long i = 0; i < 100; i++)
	s->B[i] += s->A[i];
	}



	Function calls with known side effects
	^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^^

	Function calls that have only known memory effects can be represented as
	accesses in the polyhedral model. While calls without side effects were
	supported before, we now allow and model two other kinds. The first are
	intrinsic calls to ``memcpy``, ``memmove`` and ``memset``. These calls can be
	represented precisely if the pointers involved are known and the given length
	is affine. Additionally, we allow to over-approximate function calls that are
	known only to read memory, read memory accessible through pointer arguments or
	access only memory accessible through pointer arguments. See also the function
	attributes ``readonly`` and ``argmemonly`` for more information.

	Fine-grain dependences analysis
	-------------------------------

	In addition of the ScopStmt wise dependences analysis, now the "polly-dependence"
	pass provides dependences analysis at memory reference wise and memory access wise.
	The memory reference wise analysis distinguishes the accessed references in the
	same statement, and generates dependences relationships between (statement, reference)
	pairs. The memory access wise analysis distinguishes accesses in the same statement,
	and generates dependences relationships between (statement, access) pairs. These
	fine-grain dependences are enabled by "-polly-dependences-analysis-level=reference-wise"
	and "-polly-dependences-analysis-level=access-wise", respectively.

	Update of the isl math library
	------------------------------

	We imported the latest version of the isl math library into Polly.