llvm-project

Commit Graph

Author	SHA1	Message	Date
Chandler Carruth	b29a743891	[complex] Teach the other two binary operators on complex numbers (== and !=) to support mixed complex and real operand types. This requires removing an assert from SemaChecking, and adding support both to the constant evaluator and the code generator to synthesize the imaginary part when needed. This seemed somewhat cleaner than having just the comparison operators force real-to-complex conversions. I've added test cases for these operations. I'm really terrified that there were no tests in-tree which exercised this. This turned up when trying to build R after my change to the complex type lowering. llvm-svn: 219570	2014-10-11 11:03:30 +00:00
Chandler Carruth	a216cad0fc	[complex] Teach Clang to preserve different-type operands to arithmetic operators where one type is a C complex type, and to emit both the efficient and correct implementation for complex arithmetic according to C11 Annex G using this extra information. For both multiply and divide the old code was writing a long-hand reduced version of the math without any of the special handling of inf and NaN recommended by the standard here. Instead of putting more complexity here, this change does what GCC does which is to emit a libcall for the fully general case. However, the old code also failed to do the proper minimization of the set of operations when there was a mixed complex and real operation. In those cases, C provides a spec for much more minimal operations that are valid. Clang now emits the exact suggested operations. This change isn't just about performance though, without minimizing these operations, we again lose the correct handling of infinities and NaNs. It is critical that this happen in the frontend based on assymetric type operands to complex math operations. The performance implications of this change aren't trivial either. I've run a set of benchmarks in Eigen, an open source mathematics library that makes heavy use of complex. While a few have slowed down due to the libcall being introduce, most sped up and some by a huge amount: up to 100% and 140%. In order to make all of this work, also match the algorithm in the constant evaluator to the one in the runtime library. Currently it is a broken port of the simplifications from C's Annex G to the long-hand formulation of the algorithm. Splitting this patch up is very hard because none of this works without the AST change to preserve non-complex operands. Sorry for the enormous change. Follow-up changes will include support for sinking the libcalls onto cold paths in common cases and fastmath improvements to allow more aggressive backend folding. Differential Revision: http://reviews.llvm.org/D5698 llvm-svn: 219557	2014-10-11 00:57:18 +00:00

Author

SHA1

Message

Date

Chandler Carruth

b29a743891

[complex] Teach the other two binary operators on complex numbers (==

and !=) to support mixed complex and real operand types.

This requires removing an assert from SemaChecking, and adding support
both to the constant evaluator and the code generator to synthesize the
imaginary part when needed. This seemed somewhat cleaner than having
just the comparison operators force real-to-complex conversions.

I've added test cases for these operations. I'm really terrified that
there were *no* tests in-tree which exercised this.

This turned up when trying to build R after my change to the complex
type lowering.

llvm-svn: 219570

2014-10-11 11:03:30 +00:00

Chandler Carruth

a216cad0fc

[complex] Teach Clang to preserve different-type operands to arithmetic

operators where one type is a C complex type, and to emit both the
efficient and correct implementation for complex arithmetic according to
C11 Annex G using this extra information.

For both multiply and divide the old code was writing a long-hand
reduced version of the math without any of the special handling of inf
and NaN recommended by the standard here. Instead of putting more
complexity here, this change does what GCC does which is to emit
a libcall for the fully general case.

However, the old code also failed to do the proper minimization of the
set of operations when there was a mixed complex and real operation. In
those cases, C provides a spec for much more minimal operations that are
valid. Clang now emits the exact suggested operations. This change isn't
*just* about performance though, without minimizing these operations, we
again lose the correct handling of infinities and NaNs. It is critical
that this happen in the frontend based on assymetric type operands to
complex math operations.

The performance implications of this change aren't trivial either. I've
run a set of benchmarks in Eigen, an open source mathematics library
that makes heavy use of complex. While a few have slowed down due to the
libcall being introduce, most sped up and some by a huge amount: up to
100% and 140%.

In order to make all of this work, also match the algorithm in the
constant evaluator to the one in the runtime library. Currently it is
a broken port of the simplifications from C's Annex G to the long-hand
formulation of the algorithm.

Splitting this patch up is very hard because none of this works without
the AST change to preserve non-complex operands. Sorry for the enormous
change.

Follow-up changes will include support for sinking the libcalls onto
cold paths in common cases and fastmath improvements to allow more
aggressive backend folding.

Differential Revision: http://reviews.llvm.org/D5698

llvm-svn: 219557

2014-10-11 00:57:18 +00:00

2 Commits