CartesianBenchmarks.h source code [libcxx/benchmarks/CartesianBenchmarks.h]

1	//===----------------------------------------------------------------------===//
2	//
3	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4	// See https://llvm.org/LICENSE.txt for license information.
5	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6	//
7	//===----------------------------------------------------------------------===//
8
9	#include <string>
10	#include <tuple>
11	#include <type_traits>
12	#include <vector>
13
14	#include "benchmark/benchmark.h"
15	#include "test_macros.h"
16
17	namespace internal {
18
19	template <class D, class E, size_t I>
20	struct EnumValue : std::integral_constant<E, static_cast<E>(I)> {
21	static std::string name() { return std::string("_") + D::Names[I]; }
22	};
23
24	template <class D, class E, size_t... Idxs>
25	constexpr auto makeEnumValueTuple(std::index_sequence<Idxs...>) {
26	return std::make_tuple(EnumValue<D, E, Idxs>{}...);
27	}
28
29	template <class B>
30	static auto skip(const B& Bench, int) -> decltype(Bench.skip()) {
31	return Bench.skip();
32	}
33	template <class B>
34	static auto skip(const B& Bench, char) {
35	return false;
36	}
37
38	template <class B, class Args, size_t... Is>
39	void makeBenchmarkFromValuesImpl(const Args& A, std::index_sequence<Is...>) {
40	for (auto& V : A) {
41	B Bench{std::get<Is>(V)...};
42	if (!internal::skip(Bench, `0`)) {
43	benchmark::RegisterBenchmark(Bench.name().c_str(), [=](benchmark::State& S) { Bench.run(S); });
44	}
45	}
46	}
47
48	template <class B, class... Args>
49	void makeBenchmarkFromValues(const std::vector<std::tuple<Args...> >& A) {
50	makeBenchmarkFromValuesImpl<B>(A, std::index_sequence_for<Args...>());
51	}
52
53	template <template <class...> class B, class Args, class... U>
54	void makeBenchmarkImpl(const Args& A, std::tuple<U...> t) {
55	makeBenchmarkFromValues<B<U...> >(A);
56	}
57
58	template <template <class...> class B, class Args, class... U, class... T, class... Tuples>
59	void makeBenchmarkImpl(const Args& A, std::tuple<U...>, std::tuple<T...>, Tuples... rest) {
60	(internal::makeBenchmarkImpl<B>(A, std::tuple<U..., T>(), rest...), ...);
61	}
62
63	template <class R, class T>
64	void allValueCombinations(R& Result, const T& Final) {
65	return Result.push_back(Final);
66	}
67
68	template <class R, class T, class V, class... Vs>
69	void allValueCombinations(R& Result, const T& Prev, const V& Value, const Vs&... Values) {
70	for (const auto& E : Value) {
71	allValueCombinations(Result, std::tuple_cat(Prev, std::make_tuple(E)), Values...);
72	}
73	}
74
75	} // namespace internal
76
77	// CRTP class that enables using enum types as a dimension for
78	// makeCartesianProductBenchmark below.
79	// The type passed to `B` will be a std::integral_constant<E, e>, with the
80	// additional static function `name()` that returns the stringified name of the
81	// label.
82	//
83	// Eg:
84	// enum class MyEnum { A, B };
85	// struct AllMyEnum : EnumValuesAsTuple<AllMyEnum, MyEnum, 2> {
86	// static constexpr absl::string_view Names[] = {"A", "B"};
87	// };
88	template <class Derived, class EnumType, size_t NumLabels>
89	using EnumValuesAsTuple =
90	decltype(internal::makeEnumValueTuple<Derived, EnumType>(std::make_index_sequence<NumLabels>{}));
91
92	// Instantiates B<T0, T1, ..., TN> where <Ti...> are the combinations in the
93	// cartesian product of `Tuples...`, and pass (arg0, ..., argN) as constructor
94	// arguments where `(argi...)` are the combination in the cartesian product of
95	// the runtime values of `A...`.
96	// B<T...> requires:
97	// - std::string name(args...): The name of the benchmark.
98	// - void run(benchmark::State&, args...): The body of the benchmark.
99	// It can also optionally provide:
100	// - bool skip(args...): When `true`, skips the combination. Default is false.
101	//
102	// Returns int to facilitate registration. The return value is unspecified.
103	template <template <class...> class B, class... Tuples, class... Args>
104	int makeCartesianProductBenchmark(const Args&... A) {
105	std::vector<std::tuple<typename Args::value_type...> > V;
106	internal::allValueCombinations(V, std::tuple<>(), A...);
107	internal::makeBenchmarkImpl<B>(V, std::tuple<>(), Tuples()...);
108	return `0`;
109	}
110
111	template <class B, class... Args>
112	int makeCartesianProductBenchmark(const Args&... A) {
113	std::vector<std::tuple<typename Args::value_type...> > V;
114	internal::allValueCombinations(V, std::tuple<>(), A...);
115	internal::makeBenchmarkFromValues<B>(V);
116	return `0`;
117	}
118
119	// When `opaque` is true, this function hides the runtime state of `value` from
120	// the optimizer.
121	// It returns `value`.
122	template <class T>
123	TEST_ALWAYS_INLINE inline T maybeOpaque(T value, bool opaque) {
124	if (opaque)
125	benchmark::DoNotOptimize(value);
126	return value;
127	}
128

source code of libcxx/benchmarks/CartesianBenchmarks.h