libcxx/test/std/algorithms/pstl.exception_handling.pass.cpp - toolchain/llvm-project - Git at Google

 //===----------------------------------------------------------------------===//
 //
 // 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
 //
 //===----------------------------------------------------------------------===//

 // UNSUPPORTED: c++03, c++11, c++14
 // UNSUPPORTED: no-exceptions
 // `check_assertion.h` requires Unix headers and regex support.
 // REQUIRES: has-unix-headers
 // UNSUPPORTED: no-localization

 // UNSUPPORTED: libcpp-has-no-incomplete-pstl

 // <algorithm>
 // <numeric>
 //
 // Check that PSTL algorithms terminate on user-thrown exceptions.

 #include <algorithm>
 #include <numeric>

 #include "check_assertion.h"
 #include "test_execution_policies.h"
 #include "test_iterators.h"

 template <class F>
 void assert_non_throwing(F f) {
   // We wrap this whole test in EXPECT_STD_TERMINATE because if f() terminates, we want the test to pass,
   // since this signals proper handling of user exceptions in the PSTL.
   EXPECT_STD_TERMINATE([&] {
     bool threw = false;
     try {
       f();
     } catch (...) {
       threw = true;
     }
     // If nothing was thrown, call std::terminate() to pass the EXPECT_STD_TERMINATE assertion.
     // Otherwise, don't call std::terminate() to fail the assertion.
     if (!threw)
       std::terminate();
   });
 }

 struct ThrowToken {
   void activate() { active_ = true; }
   void deactivate() { active_ = false; }
   bool active() const { return active_; }

 private:
   bool active_{false};
 };

 template <class Func>
 struct on_scope_exit {
   explicit on_scope_exit(Func func) : func_(func) {}
   ~on_scope_exit() { func_(); }

 private:
   Func func_;
 };
 template <class Func>
 on_scope_exit(Func) -> on_scope_exit<Func>;

 int main(int, char**) {
   test_execution_policies([&](auto&& policy) {
     int a[] = {1, 2, 3, 4};
     int b[] = {1, 2, 3};
     int n   = 2;
     int storage[999];
     int val  = 99;
     int init = 1;

     // We generate a certain number of "tokens" and we activate exactly one on each iteration. We then
     // throw in a given operation only when that token is active. That way we check that each argument
     // of the algorithm is handled properly.
     ThrowToken tokens[7];
     for (ThrowToken& t : tokens) {
       t.activate();
       on_scope_exit _([&] { t.deactivate(); });

       auto first1      = util::throw_on_move_iterator(std::begin(a), tokens[0].active() ? 1 : -1);
       auto last1       = util::throw_on_move_iterator(std::end(a), tokens[1].active() ? 1 : -1);
       auto first2      = util::throw_on_move_iterator(std::begin(b), tokens[2].active() ? 1 : -1);
       auto last2       = util::throw_on_move_iterator(std::end(b), tokens[3].active() ? 1 : -1);
       auto dest        = util::throw_on_move_iterator(std::end(storage), tokens[4].active() ? 1 : -1);
       auto maybe_throw = [](ThrowToken const& token, auto f) {
         return [&token, f](auto... args) {
           if (token.active())
             throw 1;
           return f(args...);
         };
       };

       {
         auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

         // all_of(first, last, pred)
         assert_non_throwing([=, &policy] { (void)std::all_of(policy, std::move(first1), std::move(last1), pred); });

         // any_of(first, last, pred)
         assert_non_throwing([=, &policy] { (void)std::any_of(policy, std::move(first1), std::move(last1), pred); });

         // none_of(first, last, pred)
         assert_non_throwing([=, &policy] { (void)std::none_of(policy, std::move(first1), std::move(last1), pred); });
       }

       {
         // copy(first, last, dest)
         assert_non_throwing([=, &policy] {
           (void)std::copy(policy, std::move(first1), std::move(last1), std::move(dest));
         });

         // copy_n(first, n, dest)
         assert_non_throwing([=, &policy] { (void)std::copy_n(policy, std::move(first1), n, std::move(dest)); });
       }

       {
         auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

         // count(first, last, val)
         assert_non_throwing([=, &policy] { (void)std::count(policy, std::move(first1), std::move(last1), val); });

         // count_if(first, last, pred)
         assert_non_throwing([=, &policy] { (void)std::count_if(policy, std::move(first1), std::move(last1), pred); });
       }

       {
         auto binary_pred = maybe_throw(tokens[5], [](int x, int y) -> bool { return x == y; });

         // equal(first1, last1, first2)
         assert_non_throwing([=, &policy] {
           (void)std::equal(policy, std::move(first1), std::move(last1), std::move(first2));
         });

         // equal(first1, last1, first2, binary_pred)
         assert_non_throwing([=, &policy] {
           (void)std::equal(policy, std::move(first1), std::move(last1), std::move(first2), binary_pred);
         });

         // equal(first1, last1, first2, last2)
         assert_non_throwing([=, &policy] {
           (void)std::equal(policy, std::move(first1), std::move(last1), std::move(first2), std::move(last2));
         });

         // equal(first1, last1, first2, last2, binary_pred)
         assert_non_throwing([=, &policy] {
           (void)std::equal(
               policy, std::move(first1), std::move(last1), std::move(first2), std::move(last2), binary_pred);
         });
       }

       {
         // fill(first, last, val)
         assert_non_throwing([=, &policy] { (void)std::fill(policy, std::move(first1), std::move(last1), val); });

         // fill_n(first, n, val)
         assert_non_throwing([=, &policy] { (void)std::fill_n(policy, std::move(first1), n, val); });
       }

       {
         auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

         // find(first, last, val)
         assert_non_throwing([=, &policy] { (void)std::find(policy, std::move(first1), std::move(last1), val); });

         // find_if(first, last, pred)
         assert_non_throwing([=, &policy] { (void)std::find_if(policy, std::move(first1), std::move(last1), pred); });

         // find_if_not(first, last, pred)
         assert_non_throwing([=, &policy] {
           (void)std::find_if_not(policy, std::move(first1), std::move(last1), pred);
         });
       }

       {
         auto func = maybe_throw(tokens[5], [](int) {});

         // for_each(first, last, func)
         assert_non_throwing([=, &policy] { (void)std::for_each(policy, std::move(first1), std::move(last1), func); });

         // for_each_n(first, n, func)
         assert_non_throwing([=, &policy] { (void)std::for_each_n(policy, std::move(first1), n, func); });
       }

       {
         auto gen = maybe_throw(tokens[5], []() -> int { return 42; });

         // generate(first, last, func)
         assert_non_throwing([=, &policy] { (void)std::generate(policy, std::move(first1), std::move(last1), gen); });

         // generate_n(first, n, func)
         assert_non_throwing([=, &policy] { (void)std::generate_n(policy, std::move(first1), n, gen); });
       }

       {
         auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

         // is_partitioned(first, last, pred)
         assert_non_throwing([=, &policy] {
           (void)std::is_partitioned(policy, std::move(first1), std::move(last1), pred);
         });
       }

       {
         auto compare = maybe_throw(tokens[5], [](int x, int y) -> bool { return x < y; });

         // merge(first1, last1, first2, last2, dest)
         assert_non_throwing([=, &policy] {
           (void)std::merge(
               policy, std::move(first1), std::move(last1), std::move(first2), std::move(last2), std::move(dest));
         });

         // merge(first1, last1, first2, last2, dest, comp)
         assert_non_throwing([=, &policy] {
           (void)std::merge(
               policy,
               std::move(first1),
               std::move(last1),
               std::move(first2),
               std::move(last2),
               std::move(dest),
               compare);
         });
       }

       {
         // move(first, last, dest)
         assert_non_throwing([=, &policy] {
           (void)std::move(policy, std::move(first1), std::move(last1), std::move(dest));
         });
       }

       {
         auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

         // replace_if(first, last, pred, val)
         assert_non_throwing([=, &policy] {
           (void)std::replace_if(policy, std::move(first1), std::move(last1), pred, val);
         });

         // replace(first, last, val1, val2)
         assert_non_throwing([=, &policy] {
           (void)std::replace(policy, std::move(first1), std::move(last1), val, val);
         });

         // replace_copy_if(first, last, dest, pred, val)
         assert_non_throwing([=, &policy] {
           (void)std::replace_copy_if(policy, std::move(first1), std::move(last1), std::move(dest), pred, val);
         });

         // replace_copy(first, last, dest, val1, val2)
         assert_non_throwing([=, &policy] {
           (void)std::replace_copy(policy, std::move(first1), std::move(last1), std::move(dest), val, val);
         });
       }

       {
         auto mid1 = util::throw_on_move_iterator(std::begin(a) + 2, tokens[5].active() ? 1 : -1);

         // rotate_copy(first, mid, last, dest)
         assert_non_throwing([=, &policy] {
           (void)std::rotate_copy(policy, std::move(first1), std::move(mid1), std::move(last1), std::move(dest));
         });
       }

       {
         auto compare = maybe_throw(tokens[5], [](int x, int y) -> bool { return x < y; });

         // sort(first, last)
         assert_non_throwing([=, &policy] { (void)std::sort(policy, std::move(first1), std::move(last1)); });

         // sort(first, last, comp)
         assert_non_throwing([=, &policy] { (void)std::sort(policy, std::move(first1), std::move(last1), compare); });

         // stable_sort(first, last)
         assert_non_throwing([=, &policy] { (void)std::stable_sort(policy, std::move(first1), std::move(last1)); });

         // stable_sort(first, last, comp)
         assert_non_throwing([=, &policy] {
           (void)std::stable_sort(policy, std::move(first1), std::move(last1), compare);
         });
       }

       {
         auto unary  = maybe_throw(tokens[5], [](int x) -> int { return x * 2; });
         auto binary = maybe_throw(tokens[5], [](int x, int y) -> int { return x * y; });

         // transform(first, last, dest, func)
         assert_non_throwing([=, &policy] {
           (void)std::transform(policy, std::move(first1), std::move(last1), std::move(dest), unary);
         });

         // transform(first1, last1, first2, dest, func)
         assert_non_throwing([=, &policy] {
           (void)std::transform(policy, std::move(first1), std::move(last1), std::move(first2), std::move(dest), binary);
         });
       }

       {
         auto reduction        = maybe_throw(tokens[5], [](int x, int y) -> int { return x + y; });
         auto transform_unary  = maybe_throw(tokens[6], [](int x) -> int { return x * 2; });
         auto transform_binary = maybe_throw(tokens[6], [](int x, int y) -> int { return x * y; });

         // transform_reduce(first1, last1, first2, init)
         assert_non_throwing([=, &policy] {
           (void)std::transform_reduce(policy, std::move(first1), std::move(last1), std::move(first2), init);
         });

         // transform_reduce(first1, last1, init, reduce, transform)
         assert_non_throwing([=, &policy] {
           (void)std::transform_reduce(policy, std::move(first1), std::move(last1), init, reduction, transform_unary);
         });

         // transform_reduce(first1, last1, first2, init, reduce, transform)
         assert_non_throwing([=, &policy] {
           (void)std::transform_reduce(
               policy, std::move(first1), std::move(last1), std::move(first2), init, reduction, transform_binary);
         });
       }

       {
         auto reduction = maybe_throw(tokens[5], [](int x, int y) -> int { return x + y; });

         // reduce(first, last)
         assert_non_throwing([=, &policy] { (void)std::reduce(policy, std::move(first1), std::move(last1)); });

         // reduce(first, last, init)
         assert_non_throwing([=, &policy] { (void)std::reduce(policy, std::move(first1), std::move(last1), init); });

         // reduce(first, last, init, binop)
         assert_non_throwing([=, &policy] {
           (void)std::reduce(policy, std::move(first1), std::move(last1), init, reduction);
         });
       }
     }
   });
 }
	//===----------------------------------------------------------------------===//
	//
	// 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
	//
	//===----------------------------------------------------------------------===//

	// UNSUPPORTED: c++03, c++11, c++14
	// UNSUPPORTED: no-exceptions
	// `check_assertion.h` requires Unix headers and regex support.
	// REQUIRES: has-unix-headers
	// UNSUPPORTED: no-localization

	// UNSUPPORTED: libcpp-has-no-incomplete-pstl

	// <algorithm>
	// <numeric>
	//
	// Check that PSTL algorithms terminate on user-thrown exceptions.

	#include <algorithm>
	#include <numeric>

	#include "check_assertion.h"
	#include "test_execution_policies.h"
	#include "test_iterators.h"

	template <class F>
	void assert_non_throwing(F f) {
	// We wrap this whole test in EXPECT_STD_TERMINATE because if f() terminates, we want the test to pass,
	// since this signals proper handling of user exceptions in the PSTL.
	EXPECT_STD_TERMINATE([&] {
	bool threw = false;
	try {
	f();
	} catch (...) {
	threw = true;
	}
	// If nothing was thrown, call std::terminate() to pass the EXPECT_STD_TERMINATE assertion.
	// Otherwise, don't call std::terminate() to fail the assertion.
	if (!threw)
	std::terminate();
	});
	}

	struct ThrowToken {
	void activate() { active_ = true; }
	void deactivate() { active_ = false; }
	bool active() const { return active_; }

	private:
	bool active_{false};
	};

	template <class Func>
	struct on_scope_exit {
	explicit on_scope_exit(Func func) : func_(func) {}
	~on_scope_exit() { func_(); }

	private:
	Func func_;
	};
	template <class Func>
	on_scope_exit(Func) -> on_scope_exit<Func>;

	int main(int, char**) {
	test_execution_policies([&](auto&& policy) {
	int a[] = {1, 2, 3, 4};
	int b[] = {1, 2, 3};
	int n = 2;
	int storage[999];
	int val = 99;
	int init = 1;

	// We generate a certain number of "tokens" and we activate exactly one on each iteration. We then
	// throw in a given operation only when that token is active. That way we check that each argument
	// of the algorithm is handled properly.
	ThrowToken tokens[7];
	for (ThrowToken& t : tokens) {
	t.activate();
	on_scope_exit _([&] { t.deactivate(); });

	auto first1 = util::throw_on_move_iterator(std::begin(a), tokens[0].active() ? 1 : -1);
	auto last1 = util::throw_on_move_iterator(std::end(a), tokens[1].active() ? 1 : -1);
	auto first2 = util::throw_on_move_iterator(std::begin(b), tokens[2].active() ? 1 : -1);
	auto last2 = util::throw_on_move_iterator(std::end(b), tokens[3].active() ? 1 : -1);
	auto dest = util::throw_on_move_iterator(std::end(storage), tokens[4].active() ? 1 : -1);
	auto maybe_throw = [](ThrowToken const& token, auto f) {
	return [&token, f](auto... args) {
	if (token.active())
	throw 1;
	return f(args...);
	};
	};

	{
	auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

	// all_of(first, last, pred)
	assert_non_throwing([=, &policy] { (void)std::all_of(policy, std::move(first1), std::move(last1), pred); });

	// any_of(first, last, pred)
	assert_non_throwing([=, &policy] { (void)std::any_of(policy, std::move(first1), std::move(last1), pred); });

	// none_of(first, last, pred)
	assert_non_throwing([=, &policy] { (void)std::none_of(policy, std::move(first1), std::move(last1), pred); });
	}

	{
	// copy(first, last, dest)
	assert_non_throwing([=, &policy] {
	(void)std::copy(policy, std::move(first1), std::move(last1), std::move(dest));
	});

	// copy_n(first, n, dest)
	assert_non_throwing([=, &policy] { (void)std::copy_n(policy, std::move(first1), n, std::move(dest)); });
	}

	{
	auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

	// count(first, last, val)
	assert_non_throwing([=, &policy] { (void)std::count(policy, std::move(first1), std::move(last1), val); });

	// count_if(first, last, pred)
	assert_non_throwing([=, &policy] { (void)std::count_if(policy, std::move(first1), std::move(last1), pred); });
	}

	{
	auto binary_pred = maybe_throw(tokens[5], [](int x, int y) -> bool { return x == y; });

	// equal(first1, last1, first2)
	assert_non_throwing([=, &policy] {
	(void)std::equal(policy, std::move(first1), std::move(last1), std::move(first2));
	});

	// equal(first1, last1, first2, binary_pred)
	assert_non_throwing([=, &policy] {
	(void)std::equal(policy, std::move(first1), std::move(last1), std::move(first2), binary_pred);
	});

	// equal(first1, last1, first2, last2)
	assert_non_throwing([=, &policy] {
	(void)std::equal(policy, std::move(first1), std::move(last1), std::move(first2), std::move(last2));
	});

	// equal(first1, last1, first2, last2, binary_pred)
	assert_non_throwing([=, &policy] {
	(void)std::equal(
	policy, std::move(first1), std::move(last1), std::move(first2), std::move(last2), binary_pred);
	});
	}

	{
	// fill(first, last, val)
	assert_non_throwing([=, &policy] { (void)std::fill(policy, std::move(first1), std::move(last1), val); });

	// fill_n(first, n, val)
	assert_non_throwing([=, &policy] { (void)std::fill_n(policy, std::move(first1), n, val); });
	}

	{
	auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

	// find(first, last, val)
	assert_non_throwing([=, &policy] { (void)std::find(policy, std::move(first1), std::move(last1), val); });

	// find_if(first, last, pred)
	assert_non_throwing([=, &policy] { (void)std::find_if(policy, std::move(first1), std::move(last1), pred); });

	// find_if_not(first, last, pred)
	assert_non_throwing([=, &policy] {
	(void)std::find_if_not(policy, std::move(first1), std::move(last1), pred);
	});
	}

	{
	auto func = maybe_throw(tokens[5], [](int) {});

	// for_each(first, last, func)
	assert_non_throwing([=, &policy] { (void)std::for_each(policy, std::move(first1), std::move(last1), func); });

	// for_each_n(first, n, func)
	assert_non_throwing([=, &policy] { (void)std::for_each_n(policy, std::move(first1), n, func); });
	}

	{
	auto gen = maybe_throw(tokens[5], []() -> int { return 42; });

	// generate(first, last, func)
	assert_non_throwing([=, &policy] { (void)std::generate(policy, std::move(first1), std::move(last1), gen); });

	// generate_n(first, n, func)
	assert_non_throwing([=, &policy] { (void)std::generate_n(policy, std::move(first1), n, gen); });
	}

	{
	auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

	// is_partitioned(first, last, pred)
	assert_non_throwing([=, &policy] {
	(void)std::is_partitioned(policy, std::move(first1), std::move(last1), pred);
	});
	}

	{
	auto compare = maybe_throw(tokens[5], [](int x, int y) -> bool { return x < y; });

	// merge(first1, last1, first2, last2, dest)
	assert_non_throwing([=, &policy] {
	(void)std::merge(
	policy, std::move(first1), std::move(last1), std::move(first2), std::move(last2), std::move(dest));
	});

	// merge(first1, last1, first2, last2, dest, comp)
	assert_non_throwing([=, &policy] {
	(void)std::merge(
	policy,
	std::move(first1),
	std::move(last1),
	std::move(first2),
	std::move(last2),
	std::move(dest),
	compare);
	});
	}

	{
	// move(first, last, dest)
	assert_non_throwing([=, &policy] {
	(void)std::move(policy, std::move(first1), std::move(last1), std::move(dest));
	});
	}

	{
	auto pred = maybe_throw(tokens[5], [](int x) -> bool { return x % 2 == 0; });

	// replace_if(first, last, pred, val)
	assert_non_throwing([=, &policy] {
	(void)std::replace_if(policy, std::move(first1), std::move(last1), pred, val);
	});

	// replace(first, last, val1, val2)
	assert_non_throwing([=, &policy] {
	(void)std::replace(policy, std::move(first1), std::move(last1), val, val);
	});

	// replace_copy_if(first, last, dest, pred, val)
	assert_non_throwing([=, &policy] {
	(void)std::replace_copy_if(policy, std::move(first1), std::move(last1), std::move(dest), pred, val);
	});

	// replace_copy(first, last, dest, val1, val2)
	assert_non_throwing([=, &policy] {
	(void)std::replace_copy(policy, std::move(first1), std::move(last1), std::move(dest), val, val);
	});
	}

	{
	auto mid1 = util::throw_on_move_iterator(std::begin(a) + 2, tokens[5].active() ? 1 : -1);

	// rotate_copy(first, mid, last, dest)
	assert_non_throwing([=, &policy] {
	(void)std::rotate_copy(policy, std::move(first1), std::move(mid1), std::move(last1), std::move(dest));
	});
	}

	{
	auto compare = maybe_throw(tokens[5], [](int x, int y) -> bool { return x < y; });

	// sort(first, last)
	assert_non_throwing([=, &policy] { (void)std::sort(policy, std::move(first1), std::move(last1)); });

	// sort(first, last, comp)
	assert_non_throwing([=, &policy] { (void)std::sort(policy, std::move(first1), std::move(last1), compare); });

	// stable_sort(first, last)
	assert_non_throwing([=, &policy] { (void)std::stable_sort(policy, std::move(first1), std::move(last1)); });

	// stable_sort(first, last, comp)
	assert_non_throwing([=, &policy] {
	(void)std::stable_sort(policy, std::move(first1), std::move(last1), compare);
	});
	}

	{
	auto unary = maybe_throw(tokens[5], [](int x) -> int { return x * 2; });
	auto binary = maybe_throw(tokens[5], [](int x, int y) -> int { return x * y; });

	// transform(first, last, dest, func)
	assert_non_throwing([=, &policy] {
	(void)std::transform(policy, std::move(first1), std::move(last1), std::move(dest), unary);
	});

	// transform(first1, last1, first2, dest, func)
	assert_non_throwing([=, &policy] {
	(void)std::transform(policy, std::move(first1), std::move(last1), std::move(first2), std::move(dest), binary);
	});
	}

	{
	auto reduction = maybe_throw(tokens[5], [](int x, int y) -> int { return x + y; });
	auto transform_unary = maybe_throw(tokens[6], [](int x) -> int { return x * 2; });
	auto transform_binary = maybe_throw(tokens[6], [](int x, int y) -> int { return x * y; });

	// transform_reduce(first1, last1, first2, init)
	assert_non_throwing([=, &policy] {
	(void)std::transform_reduce(policy, std::move(first1), std::move(last1), std::move(first2), init);
	});

	// transform_reduce(first1, last1, init, reduce, transform)
	assert_non_throwing([=, &policy] {
	(void)std::transform_reduce(policy, std::move(first1), std::move(last1), init, reduction, transform_unary);
	});

	// transform_reduce(first1, last1, first2, init, reduce, transform)
	assert_non_throwing([=, &policy] {
	(void)std::transform_reduce(
	policy, std::move(first1), std::move(last1), std::move(first2), init, reduction, transform_binary);
	});
	}

	{
	auto reduction = maybe_throw(tokens[5], [](int x, int y) -> int { return x + y; });

	// reduce(first, last)
	assert_non_throwing([=, &policy] { (void)std::reduce(policy, std::move(first1), std::move(last1)); });

	// reduce(first, last, init)
	assert_non_throwing([=, &policy] { (void)std::reduce(policy, std::move(first1), std::move(last1), init); });

	// reduce(first, last, init, binop)
	assert_non_throwing([=, &policy] {
	(void)std::reduce(policy, std::move(first1), std::move(last1), init, reduction);
	});
	}
	}
	});
	}