libc/benchmarks/automemcpy/include/automemcpy/FunctionDescriptor.h - llvm-project - Git at Google

 //===-- Pod structs to describe a memory function----------------*- C++ -*-===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #ifndef LLVM_LIBC_BENCHMARKS_AUTOMEMCPY_COMMON_H
 #define LLVM_LIBC_BENCHMARKS_AUTOMEMCPY_COMMON_H

 #include <climits>
 #include <cstddef>
 #include <llvm/ADT/ArrayRef.h>
 #include <llvm/ADT/Hashing.h>
 #include <llvm/ADT/Optional.h>
 #include <llvm/ADT/StringRef.h>
 #include <tuple>

 namespace llvm {
 namespace automemcpy {

 // Boilerplate code to be able to sort and hash types.
 #define COMPARABLE_AND_HASHABLE(T, ...)                                        \
   inline auto asTuple() const { return std::tie(__VA_ARGS__); }                \
   bool operator==(const T &O) const { return asTuple() == O.asTuple(); }       \
   bool operator<(const T &O) const { return asTuple() < O.asTuple(); }         \
   struct Hasher {                                                              \
     std::size_t operator()(const T &K) const {                                 \
       return llvm::hash_value(K.asTuple());                                    \
     }                                                                          \
   };

 // Represents the maximum value for the size parameter of a memory function.
 // This is an `int` so we can use it as an expression in Z3.
 // It also allows for a more readable and compact representation when storing
 // the SizeSpan in the autogenerated C++ file.
 static constexpr int kMaxSize = INT_MAX;

 // This mimics the `Arg` type in libc/src/string/memory_utils/elements.h without
 // having to depend on it.
 enum class AlignArg { _1, _2, ARRAY_SIZE };

 // Describes a range of sizes.
 // We use the begin/end representation instead of first/last to allow for empty
 // range (i.e. Begin == End)
 struct SizeSpan {
   size_t Begin = 0;
   size_t End = 0;

   COMPARABLE_AND_HASHABLE(SizeSpan, Begin, End)
 };

 // Describes a contiguous region.
 // In such a region all sizes are handled individually.
 // e.g. with Span = {0, 2};
 // if(size == 0) return Handle<0>();
 // if(size == 1) return Handle<1>();
 struct Contiguous {
   SizeSpan Span;

   COMPARABLE_AND_HASHABLE(Contiguous, Span)
 };

 // This struct represents a range of sizes over which to use an overlapping
 // strategy. An overlapping strategy of size N handles all sizes from N to 2xN.
 // The span may represent several contiguous overlaps.
 // e.g. with Span = {16, 128};
 // if(size >= 16 and size < 32) return Handle<Overlap<16>>();
 // if(size >= 32 and size < 64) return Handle<Overlap<32>>();
 // if(size >= 64 and size < 128) return Handle<Overlap<64>>();
 struct Overlap {
   SizeSpan Span;

   COMPARABLE_AND_HASHABLE(Overlap, Span)
 };

 // Describes a region using a loop handling BlockSize bytes at a time. The
 // remaining bytes of the loop are handled with an overlapping operation.
 struct Loop {
   SizeSpan Span;
   size_t BlockSize = 0;

   COMPARABLE_AND_HASHABLE(Loop, Span, BlockSize)
 };

 // Same as `Loop` but starts by aligning a buffer on `Alignment` bytes.
 // A first operation handling 'Alignment` bytes is performed followed by a
 // sequence of Loop.BlockSize bytes operation. The Loop starts processing from
 // the next aligned byte in the chosen buffer. The remaining bytes of the loop
 // are handled with an overlapping operation.
 struct AlignedLoop {
   Loop Loop;
   size_t Alignment = 0;            // Size of the alignment.
   AlignArg AlignTo = AlignArg::_1; // Which buffer to align.

   COMPARABLE_AND_HASHABLE(AlignedLoop, Loop, Alignment, AlignTo)
 };

 // Some processors offer special instruction to handle the memory function
 // completely, we refer to such instructions as accelerators.
 struct Accelerator {
   SizeSpan Span;

   COMPARABLE_AND_HASHABLE(Accelerator, Span)
 };

 // The memory functions are assembled out of primitives that can be implemented
 // with regular scalar operations (SCALAR), with the help of vector or bitcount
 // instructions (NATIVE) or by deferring it to the compiler (BUILTIN).
 enum class ElementTypeClass {
   SCALAR,
   NATIVE,
   BUILTIN,
 };

 // A simple enum to categorize which function is being implemented.
 enum class FunctionType {
   MEMCPY,
   MEMCMP,
   BCMP,
   MEMSET,
   BZERO,
 };

 // This struct describes the skeleton of the implementation, it does not go into
 // every detail but is enough to uniquely identify the implementation.
 struct FunctionDescriptor {
   FunctionType Type;
   Optional<Contiguous> Contiguous;
   Optional<Overlap> Overlap;
   Optional<Loop> Loop;
   Optional<AlignedLoop> AlignedLoop;
   Optional<Accelerator> Accelerator;
   ElementTypeClass ElementClass;

   COMPARABLE_AND_HASHABLE(FunctionDescriptor, Type, Contiguous, Overlap, Loop,
                           AlignedLoop, Accelerator, ElementClass)

   inline size_t id() const { return llvm::hash_value(asTuple()); }
 };

 // Same as above but with the function name.
 struct NamedFunctionDescriptor {
   StringRef Name;
   FunctionDescriptor Desc;
 };

 template <typename T> llvm::hash_code hash_value(const ArrayRef<T> &V) {
   return llvm::hash_combine_range(V.begin(), V.end());
 }
 template <typename T> llvm::hash_code hash_value(const T &O) {
   return llvm::hash_value(O.asTuple());
 }

 } // namespace automemcpy
 } // namespace llvm

 #endif /* LLVM_LIBC_BENCHMARKS_AUTOMEMCPY_COMMON_H */
	//===-- Pod structs to describe a memory function----------------- C++ --===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#ifndef LLVM_LIBC_BENCHMARKS_AUTOMEMCPY_COMMON_H
	#define LLVM_LIBC_BENCHMARKS_AUTOMEMCPY_COMMON_H

	#include <climits>
	#include <cstddef>
	#include <llvm/ADT/ArrayRef.h>
	#include <llvm/ADT/Hashing.h>
	#include <llvm/ADT/Optional.h>
	#include <llvm/ADT/StringRef.h>
	#include <tuple>

	namespace llvm {
	namespace automemcpy {

	// Boilerplate code to be able to sort and hash types.
	#define COMPARABLE_AND_HASHABLE(T, ...) \
	inline auto asTuple() const { return std::tie(__VA_ARGS__); } \
	bool operator==(const T &O) const { return asTuple() == O.asTuple(); } \
	bool operator<(const T &O) const { return asTuple() < O.asTuple(); } \
	struct Hasher { \
	std::size_t operator()(const T &K) const { \
	return llvm::hash_value(K.asTuple()); \
	} \
	};

	// Represents the maximum value for the size parameter of a memory function.
	// This is an `int` so we can use it as an expression in Z3.
	// It also allows for a more readable and compact representation when storing
	// the SizeSpan in the autogenerated C++ file.
	static constexpr int kMaxSize = INT_MAX;

	// This mimics the `Arg` type in libc/src/string/memory_utils/elements.h without
	// having to depend on it.
	enum class AlignArg { _1, _2, ARRAY_SIZE };

	// Describes a range of sizes.
	// We use the begin/end representation instead of first/last to allow for empty
	// range (i.e. Begin == End)
	struct SizeSpan {
	size_t Begin = 0;
	size_t End = 0;

	COMPARABLE_AND_HASHABLE(SizeSpan, Begin, End)
	};

	// Describes a contiguous region.
	// In such a region all sizes are handled individually.
	// e.g. with Span = {0, 2};
	// if(size == 0) return Handle<0>();
	// if(size == 1) return Handle<1>();
	struct Contiguous {
	SizeSpan Span;

	COMPARABLE_AND_HASHABLE(Contiguous, Span)
	};

	// This struct represents a range of sizes over which to use an overlapping
	// strategy. An overlapping strategy of size N handles all sizes from N to 2xN.
	// The span may represent several contiguous overlaps.
	// e.g. with Span = {16, 128};
	// if(size >= 16 and size < 32) return Handle<Overlap<16>>();
	// if(size >= 32 and size < 64) return Handle<Overlap<32>>();
	// if(size >= 64 and size < 128) return Handle<Overlap<64>>();
	struct Overlap {
	SizeSpan Span;

	COMPARABLE_AND_HASHABLE(Overlap, Span)
	};

	// Describes a region using a loop handling BlockSize bytes at a time. The
	// remaining bytes of the loop are handled with an overlapping operation.
	struct Loop {
	SizeSpan Span;
	size_t BlockSize = 0;

	COMPARABLE_AND_HASHABLE(Loop, Span, BlockSize)
	};

	// Same as `Loop` but starts by aligning a buffer on `Alignment` bytes.
	// A first operation handling 'Alignment` bytes is performed followed by a
	// sequence of Loop.BlockSize bytes operation. The Loop starts processing from
	// the next aligned byte in the chosen buffer. The remaining bytes of the loop
	// are handled with an overlapping operation.
	struct AlignedLoop {
	Loop Loop;
	size_t Alignment = 0; // Size of the alignment.
	AlignArg AlignTo = AlignArg::_1; // Which buffer to align.

	COMPARABLE_AND_HASHABLE(AlignedLoop, Loop, Alignment, AlignTo)
	};

	// Some processors offer special instruction to handle the memory function
	// completely, we refer to such instructions as accelerators.
	struct Accelerator {
	SizeSpan Span;

	COMPARABLE_AND_HASHABLE(Accelerator, Span)
	};

	// The memory functions are assembled out of primitives that can be implemented
	// with regular scalar operations (SCALAR), with the help of vector or bitcount
	// instructions (NATIVE) or by deferring it to the compiler (BUILTIN).
	enum class ElementTypeClass {
	SCALAR,
	NATIVE,
	BUILTIN,
	};

	// A simple enum to categorize which function is being implemented.
	enum class FunctionType {
	MEMCPY,
	MEMCMP,
	BCMP,
	MEMSET,
	BZERO,
	};

	// This struct describes the skeleton of the implementation, it does not go into
	// every detail but is enough to uniquely identify the implementation.
	struct FunctionDescriptor {
	FunctionType Type;
	Optional<Contiguous> Contiguous;
	Optional<Overlap> Overlap;
	Optional<Loop> Loop;
	Optional<AlignedLoop> AlignedLoop;
	Optional<Accelerator> Accelerator;
	ElementTypeClass ElementClass;

	COMPARABLE_AND_HASHABLE(FunctionDescriptor, Type, Contiguous, Overlap, Loop,
	AlignedLoop, Accelerator, ElementClass)

	inline size_t id() const { return llvm::hash_value(asTuple()); }
	};

	// Same as above but with the function name.
	struct NamedFunctionDescriptor {
	StringRef Name;
	FunctionDescriptor Desc;
	};

	template <typename T> llvm::hash_code hash_value(const ArrayRef<T> &V) {
	return llvm::hash_combine_range(V.begin(), V.end());
	}
	template <typename T> llvm::hash_code hash_value(const T &O) {
	return llvm::hash_value(O.asTuple());
	}

	} // namespace automemcpy
	} // namespace llvm

	#endif /* LLVM_LIBC_BENCHMARKS_AUTOMEMCPY_COMMON_H */