test/hotspot/gtest/runtime/test_atomic.cpp - toolchain/jdk/jdk21 - Git at Google

 /*
  * Copyright (c) 2022, 2023, Oracle and/or its affiliates. All rights reserved.
  * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
  *
  * This code is free software; you can redistribute it and/or modify it
  * under the terms of the GNU General Public License version 2 only, as
  * published by the Free Software Foundation.
  *
  * This code is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
  * FITNESS FOR A PARTICULAR PURPOSE.  See the GNU General Public License
  * version 2 for more details (a copy is included in the LICENSE file that
  * accompanied this code).
  *
  * You should have received a copy of the GNU General Public License version
  * 2 along with this work; if not, write to the Free Software Foundation,
  * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
  *
  * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
  * or visit www.oracle.com if you need additional information or have any
  * questions.
  *
  */

 #include "precompiled.hpp"
 #include "runtime/atomic.hpp"
 #include "unittest.hpp"

 // These tests of Atomic only verify functionality.  They don't verify atomicity.

 template<typename T>
 struct AtomicAddTestSupport {
   volatile T _test_value;

   AtomicAddTestSupport() : _test_value{} {}

   void test_add() {
     T zero = 0;
     T five = 5;
     Atomic::store(&_test_value, zero);
     T value = Atomic::add(&_test_value, five);
     EXPECT_EQ(five, value);
     EXPECT_EQ(five, Atomic::load(&_test_value));
   }

   void test_fetch_add() {
     T zero = 0;
     T five = 5;
     Atomic::store(&_test_value, zero);
     T value = Atomic::fetch_then_add(&_test_value, five);
     EXPECT_EQ(zero, value);
     EXPECT_EQ(five, Atomic::load(&_test_value));
   }
 };

 TEST_VM(AtomicAddTest, int32) {
   using Support = AtomicAddTestSupport<int32_t>;
   Support().test_add();
   Support().test_fetch_add();
 }

 TEST_VM(AtomicAddTest, int64) {
   // Check if 64-bit atomics are available on the machine.
   if (!VM_Version::supports_cx8()) return;

   using Support = AtomicAddTestSupport<int64_t>;
   Support().test_add();
   Support().test_fetch_add();
 }

 TEST_VM(AtomicAddTest, ptr) {
   uint _test_values[10] = {};
   uint* volatile _test_value{};

   uint* zero = &_test_values[0];
   uint* five = &_test_values[5];
   uint* six  = &_test_values[6];

   Atomic::store(&_test_value, zero);
   uint* value = Atomic::add(&_test_value, 5);
   EXPECT_EQ(five, value);
   EXPECT_EQ(five, Atomic::load(&_test_value));

   Atomic::store(&_test_value, zero);
   value = Atomic::fetch_then_add(&_test_value, 6);
   EXPECT_EQ(zero, value);
   EXPECT_EQ(six, Atomic::load(&_test_value));
 };

 template<typename T>
 struct AtomicXchgTestSupport {
   volatile T _test_value;

   AtomicXchgTestSupport() : _test_value{} {}

   void test() {
     T zero = 0;
     T five = 5;
     Atomic::store(&_test_value, zero);
     T res = Atomic::xchg(&_test_value, five);
     EXPECT_EQ(zero, res);
     EXPECT_EQ(five, Atomic::load(&_test_value));
   }
 };

 TEST_VM(AtomicXchgTest, int32) {
   using Support = AtomicXchgTestSupport<int32_t>;
   Support().test();
 }

 TEST_VM(AtomicXchgTest, int64) {
   // Check if 64-bit atomics are available on the machine.
   if (!VM_Version::supports_cx8()) return;

   using Support = AtomicXchgTestSupport<int64_t>;
   Support().test();
 }

 template<typename T>
 struct AtomicCmpxchgTestSupport {
   volatile T _test_value;

   AtomicCmpxchgTestSupport() : _test_value{} {}

   void test() {
     T zero = 0;
     T five = 5;
     T ten = 10;
     Atomic::store(&_test_value, zero);
     T res = Atomic::cmpxchg(&_test_value, five, ten);
     EXPECT_EQ(zero, res);
     EXPECT_EQ(zero, Atomic::load(&_test_value));
     res = Atomic::cmpxchg(&_test_value, zero, ten);
     EXPECT_EQ(zero, res);
     EXPECT_EQ(ten, Atomic::load(&_test_value));
   }
 };

 TEST_VM(AtomicCmpxchgTest, int32) {
   using Support = AtomicCmpxchgTestSupport<int32_t>;
   Support().test();
 }

 TEST_VM(AtomicCmpxchgTest, int64) {
   // Check if 64-bit atomics are available on the machine.
   if (!VM_Version::supports_cx8()) return;

   using Support = AtomicCmpxchgTestSupport<int64_t>;
   Support().test();
 }

 struct AtomicCmpxchg1ByteStressSupport {
   char _default_val;
   int  _base;
   char _array[7+32+7];

   AtomicCmpxchg1ByteStressSupport() : _default_val(0x7a), _base(7), _array{} {}

   void validate(char val, char val2, int index) {
     for (int i = 0; i < 7; i++) {
       EXPECT_EQ(_array[i], _default_val);
     }
     for (int i = 7; i < (7+32); i++) {
       if (i == index) {
         EXPECT_EQ(_array[i], val2);
       } else {
         EXPECT_EQ(_array[i], val);
       }
     }
     for (int i = 0; i < 7; i++) {
       EXPECT_EQ(_array[i], _default_val);
     }
   }

   void test_index(int index) {
     char one = 1;
     Atomic::cmpxchg(&_array[index], _default_val, one);
     validate(_default_val, one, index);

     Atomic::cmpxchg(&_array[index], one, _default_val);
     validate(_default_val, _default_val, index);
   }

   void test() {
     memset(_array, _default_val, sizeof(_array));
     for (int i = _base; i < (_base+32); i++) {
       test_index(i);
     }
   }
 };

 TEST_VM(AtomicCmpxchg1Byte, stress) {
   AtomicCmpxchg1ByteStressSupport support;
   support.test();
 }

 template<typename T>
 struct AtomicEnumTestSupport {
   volatile T _test_value;

   AtomicEnumTestSupport() : _test_value{} {}

   void test_store_load(T value) {
     EXPECT_NE(value, Atomic::load(&_test_value));
     Atomic::store(&_test_value, value);
     EXPECT_EQ(value, Atomic::load(&_test_value));
   }

   void test_cmpxchg(T value1, T value2) {
     EXPECT_NE(value1, Atomic::load(&_test_value));
     Atomic::store(&_test_value, value1);
     EXPECT_EQ(value1, Atomic::cmpxchg(&_test_value, value2, value2));
     EXPECT_EQ(value1, Atomic::load(&_test_value));
     EXPECT_EQ(value1, Atomic::cmpxchg(&_test_value, value1, value2));
     EXPECT_EQ(value2, Atomic::load(&_test_value));
   }

   void test_xchg(T value1, T value2) {
     EXPECT_NE(value1, Atomic::load(&_test_value));
     Atomic::store(&_test_value, value1);
     EXPECT_EQ(value1, Atomic::xchg(&_test_value, value2));
     EXPECT_EQ(value2, Atomic::load(&_test_value));
   }
 };

 namespace AtomicEnumTestUnscoped {       // Scope the enumerators.
   enum TestEnum { A, B, C };
 }

 TEST_VM(AtomicEnumTest, unscoped_enum) {
   using namespace AtomicEnumTestUnscoped;
   using Support = AtomicEnumTestSupport<TestEnum>;

   Support().test_store_load(B);
   Support().test_cmpxchg(B, C);
   Support().test_xchg(B, C);
 }

 enum class AtomicEnumTestScoped { A, B, C };

 TEST_VM(AtomicEnumTest, scoped_enum) {
   const AtomicEnumTestScoped B = AtomicEnumTestScoped::B;
   const AtomicEnumTestScoped C = AtomicEnumTestScoped::C;
   using Support = AtomicEnumTestSupport<AtomicEnumTestScoped>;

   Support().test_store_load(B);
   Support().test_cmpxchg(B, C);
   Support().test_xchg(B, C);
 }

 template<typename T>
 struct AtomicBitopsTestSupport {
   volatile T _test_value;

   // At least one byte differs between _old_value and _old_value op _change_value.
   static const T _old_value =    static_cast<T>(UCONST64(0x7f5300007f530044));
   static const T _change_value = static_cast<T>(UCONST64(0x3800530038005322));

   AtomicBitopsTestSupport() : _test_value(0) {}

   void fetch_then_and() {
     Atomic::store(&_test_value, _old_value);
     T expected = _old_value & _change_value;
     EXPECT_NE(_old_value, expected);
     T result = Atomic::fetch_then_and(&_test_value, _change_value);
     EXPECT_EQ(_old_value, result);
     EXPECT_EQ(expected, Atomic::load(&_test_value));
   }

   void fetch_then_or() {
     Atomic::store(&_test_value, _old_value);
     T expected = _old_value | _change_value;
     EXPECT_NE(_old_value, expected);
     T result = Atomic::fetch_then_or(&_test_value, _change_value);
     EXPECT_EQ(_old_value, result);
     EXPECT_EQ(expected, Atomic::load(&_test_value));
   }

   void fetch_then_xor() {
     Atomic::store(&_test_value, _old_value);
     T expected = _old_value ^ _change_value;
     EXPECT_NE(_old_value, expected);
     T result = Atomic::fetch_then_xor(&_test_value, _change_value);
     EXPECT_EQ(_old_value, result);
     EXPECT_EQ(expected, Atomic::load(&_test_value));
   }

   void and_then_fetch() {
     Atomic::store(&_test_value, _old_value);
     T expected = _old_value & _change_value;
     EXPECT_NE(_old_value, expected);
     T result = Atomic::and_then_fetch(&_test_value, _change_value);
     EXPECT_EQ(expected, result);
     EXPECT_EQ(expected, Atomic::load(&_test_value));
   }

   void or_then_fetch() {
     Atomic::store(&_test_value, _old_value);
     T expected = _old_value | _change_value;
     EXPECT_NE(_old_value, expected);
     T result = Atomic::or_then_fetch(&_test_value, _change_value);
     EXPECT_EQ(expected, result);
     EXPECT_EQ(expected, Atomic::load(&_test_value));
   }

   void xor_then_fetch() {
     Atomic::store(&_test_value, _old_value);
     T expected = _old_value ^ _change_value;
     EXPECT_NE(_old_value, expected);
     T result = Atomic::xor_then_fetch(&_test_value, _change_value);
     EXPECT_EQ(expected, result);
     EXPECT_EQ(expected, Atomic::load(&_test_value));
   }

 #define TEST_BITOP(name) { SCOPED_TRACE(XSTR(name)); name(); }

   void operator()() {
     TEST_BITOP(fetch_then_and)
     TEST_BITOP(fetch_then_or)
     TEST_BITOP(fetch_then_xor)
     TEST_BITOP(and_then_fetch)
     TEST_BITOP(or_then_fetch)
     TEST_BITOP(xor_then_fetch)
   }

 #undef TEST_BITOP
 };

 template<typename T>
 const T AtomicBitopsTestSupport<T>::_old_value;

 template<typename T>
 const T AtomicBitopsTestSupport<T>::_change_value;

 TEST_VM(AtomicBitopsTest, int8) {
   AtomicBitopsTestSupport<int8_t>()();
 }

 TEST_VM(AtomicBitopsTest, uint8) {
   AtomicBitopsTestSupport<uint8_t>()();
 }

 TEST_VM(AtomicBitopsTest, int32) {
   AtomicBitopsTestSupport<int32_t>()();
 }

 TEST_VM(AtomicBitopsTest, uint32) {
   AtomicBitopsTestSupport<uint32_t>()();
 }

 TEST_VM(AtomicBitopsTest, int64) {
   // Check if 64-bit atomics are available on the machine.
   if (!VM_Version::supports_cx8()) return;

   AtomicBitopsTestSupport<int64_t>()();
 }

 TEST_VM(AtomicBitopsTest, uint64) {
   // Check if 64-bit atomics are available on the machine.
   if (!VM_Version::supports_cx8()) return;

   AtomicBitopsTestSupport<uint64_t>()();
 }
	/*
	* Copyright (c) 2022, 2023, Oracle and/or its affiliates. All rights reserved.
	* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
	*
	* This code is free software; you can redistribute it and/or modify it
	* under the terms of the GNU General Public License version 2 only, as
	* published by the Free Software Foundation.
	*
	* This code is distributed in the hope that it will be useful, but WITHOUT
	* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
	* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
	* version 2 for more details (a copy is included in the LICENSE file that
	* accompanied this code).
	*
	* You should have received a copy of the GNU General Public License version
	* 2 along with this work; if not, write to the Free Software Foundation,
	* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
	*
	* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
	* or visit www.oracle.com if you need additional information or have any
	* questions.
	*
	*/

	#include "precompiled.hpp"
	#include "runtime/atomic.hpp"
	#include "unittest.hpp"

	// These tests of Atomic only verify functionality. They don't verify atomicity.

	template<typename T>
	struct AtomicAddTestSupport {
	volatile T _test_value;

	AtomicAddTestSupport() : _test_value{} {}

	void test_add() {
	T zero = 0;
	T five = 5;
	Atomic::store(&_test_value, zero);
	T value = Atomic::add(&_test_value, five);
	EXPECT_EQ(five, value);
	EXPECT_EQ(five, Atomic::load(&_test_value));
	}

	void test_fetch_add() {
	T zero = 0;
	T five = 5;
	Atomic::store(&_test_value, zero);
	T value = Atomic::fetch_then_add(&_test_value, five);
	EXPECT_EQ(zero, value);
	EXPECT_EQ(five, Atomic::load(&_test_value));
	}
	};

	TEST_VM(AtomicAddTest, int32) {
	using Support = AtomicAddTestSupport<int32_t>;
	Support().test_add();
	Support().test_fetch_add();
	}

	TEST_VM(AtomicAddTest, int64) {
	// Check if 64-bit atomics are available on the machine.
	if (!VM_Version::supports_cx8()) return;

	using Support = AtomicAddTestSupport<int64_t>;
	Support().test_add();
	Support().test_fetch_add();
	}

	TEST_VM(AtomicAddTest, ptr) {
	uint _test_values[10] = {};
	uint* volatile _test_value{};

	uint* zero = &_test_values[0];
	uint* five = &_test_values[5];
	uint* six = &_test_values[6];

	Atomic::store(&_test_value, zero);
	uint* value = Atomic::add(&_test_value, 5);
	EXPECT_EQ(five, value);
	EXPECT_EQ(five, Atomic::load(&_test_value));

	Atomic::store(&_test_value, zero);
	value = Atomic::fetch_then_add(&_test_value, 6);
	EXPECT_EQ(zero, value);
	EXPECT_EQ(six, Atomic::load(&_test_value));
	};

	template<typename T>
	struct AtomicXchgTestSupport {
	volatile T _test_value;

	AtomicXchgTestSupport() : _test_value{} {}

	void test() {
	T zero = 0;
	T five = 5;
	Atomic::store(&_test_value, zero);
	T res = Atomic::xchg(&_test_value, five);
	EXPECT_EQ(zero, res);
	EXPECT_EQ(five, Atomic::load(&_test_value));
	}
	};

	TEST_VM(AtomicXchgTest, int32) {
	using Support = AtomicXchgTestSupport<int32_t>;
	Support().test();
	}

	TEST_VM(AtomicXchgTest, int64) {
	// Check if 64-bit atomics are available on the machine.
	if (!VM_Version::supports_cx8()) return;

	using Support = AtomicXchgTestSupport<int64_t>;
	Support().test();
	}

	template<typename T>
	struct AtomicCmpxchgTestSupport {
	volatile T _test_value;

	AtomicCmpxchgTestSupport() : _test_value{} {}

	void test() {
	T zero = 0;
	T five = 5;
	T ten = 10;
	Atomic::store(&_test_value, zero);
	T res = Atomic::cmpxchg(&_test_value, five, ten);
	EXPECT_EQ(zero, res);
	EXPECT_EQ(zero, Atomic::load(&_test_value));
	res = Atomic::cmpxchg(&_test_value, zero, ten);
	EXPECT_EQ(zero, res);
	EXPECT_EQ(ten, Atomic::load(&_test_value));
	}
	};

	TEST_VM(AtomicCmpxchgTest, int32) {
	using Support = AtomicCmpxchgTestSupport<int32_t>;
	Support().test();
	}

	TEST_VM(AtomicCmpxchgTest, int64) {
	// Check if 64-bit atomics are available on the machine.
	if (!VM_Version::supports_cx8()) return;

	using Support = AtomicCmpxchgTestSupport<int64_t>;
	Support().test();
	}

	struct AtomicCmpxchg1ByteStressSupport {
	char _default_val;
	int _base;
	char _array[7+32+7];

	AtomicCmpxchg1ByteStressSupport() : _default_val(0x7a), _base(7), _array{} {}

	void validate(char val, char val2, int index) {
	for (int i = 0; i < 7; i++) {
	EXPECT_EQ(_array[i], _default_val);
	}
	for (int i = 7; i < (7+32); i++) {
	if (i == index) {
	EXPECT_EQ(_array[i], val2);
	} else {
	EXPECT_EQ(_array[i], val);
	}
	}
	for (int i = 0; i < 7; i++) {
	EXPECT_EQ(_array[i], _default_val);
	}
	}

	void test_index(int index) {
	char one = 1;
	Atomic::cmpxchg(&_array[index], _default_val, one);
	validate(_default_val, one, index);

	Atomic::cmpxchg(&_array[index], one, _default_val);
	validate(_default_val, _default_val, index);
	}

	void test() {
	memset(_array, _default_val, sizeof(_array));
	for (int i = _base; i < (_base+32); i++) {
	test_index(i);
	}
	}
	};

	TEST_VM(AtomicCmpxchg1Byte, stress) {
	AtomicCmpxchg1ByteStressSupport support;
	support.test();
	}

	template<typename T>
	struct AtomicEnumTestSupport {
	volatile T _test_value;

	AtomicEnumTestSupport() : _test_value{} {}

	void test_store_load(T value) {
	EXPECT_NE(value, Atomic::load(&_test_value));
	Atomic::store(&_test_value, value);
	EXPECT_EQ(value, Atomic::load(&_test_value));
	}

	void test_cmpxchg(T value1, T value2) {
	EXPECT_NE(value1, Atomic::load(&_test_value));
	Atomic::store(&_test_value, value1);
	EXPECT_EQ(value1, Atomic::cmpxchg(&_test_value, value2, value2));
	EXPECT_EQ(value1, Atomic::load(&_test_value));
	EXPECT_EQ(value1, Atomic::cmpxchg(&_test_value, value1, value2));
	EXPECT_EQ(value2, Atomic::load(&_test_value));
	}

	void test_xchg(T value1, T value2) {
	EXPECT_NE(value1, Atomic::load(&_test_value));
	Atomic::store(&_test_value, value1);
	EXPECT_EQ(value1, Atomic::xchg(&_test_value, value2));
	EXPECT_EQ(value2, Atomic::load(&_test_value));
	}
	};

	namespace AtomicEnumTestUnscoped { // Scope the enumerators.
	enum TestEnum { A, B, C };
	}

	TEST_VM(AtomicEnumTest, unscoped_enum) {
	using namespace AtomicEnumTestUnscoped;
	using Support = AtomicEnumTestSupport<TestEnum>;

	Support().test_store_load(B);
	Support().test_cmpxchg(B, C);
	Support().test_xchg(B, C);
	}

	enum class AtomicEnumTestScoped { A, B, C };

	TEST_VM(AtomicEnumTest, scoped_enum) {
	const AtomicEnumTestScoped B = AtomicEnumTestScoped::B;
	const AtomicEnumTestScoped C = AtomicEnumTestScoped::C;
	using Support = AtomicEnumTestSupport<AtomicEnumTestScoped>;

	Support().test_store_load(B);
	Support().test_cmpxchg(B, C);
	Support().test_xchg(B, C);
	}

	template<typename T>
	struct AtomicBitopsTestSupport {
	volatile T _test_value;

	// At least one byte differs between _old_value and _old_value op _change_value.
	static const T _old_value = static_cast<T>(UCONST64(0x7f5300007f530044));
	static const T _change_value = static_cast<T>(UCONST64(0x3800530038005322));

	AtomicBitopsTestSupport() : _test_value(0) {}

	void fetch_then_and() {
	Atomic::store(&_test_value, _old_value);
	T expected = _old_value & _change_value;
	EXPECT_NE(_old_value, expected);
	T result = Atomic::fetch_then_and(&_test_value, _change_value);
	EXPECT_EQ(_old_value, result);
	EXPECT_EQ(expected, Atomic::load(&_test_value));
	}

	void fetch_then_or() {
	Atomic::store(&_test_value, _old_value);
	T expected = _old_value \| _change_value;
	EXPECT_NE(_old_value, expected);
	T result = Atomic::fetch_then_or(&_test_value, _change_value);
	EXPECT_EQ(_old_value, result);
	EXPECT_EQ(expected, Atomic::load(&_test_value));
	}

	void fetch_then_xor() {
	Atomic::store(&_test_value, _old_value);
	T expected = _old_value ^ _change_value;
	EXPECT_NE(_old_value, expected);
	T result = Atomic::fetch_then_xor(&_test_value, _change_value);
	EXPECT_EQ(_old_value, result);
	EXPECT_EQ(expected, Atomic::load(&_test_value));
	}

	void and_then_fetch() {
	Atomic::store(&_test_value, _old_value);
	T expected = _old_value & _change_value;
	EXPECT_NE(_old_value, expected);
	T result = Atomic::and_then_fetch(&_test_value, _change_value);
	EXPECT_EQ(expected, result);
	EXPECT_EQ(expected, Atomic::load(&_test_value));
	}

	void or_then_fetch() {
	Atomic::store(&_test_value, _old_value);
	T expected = _old_value \| _change_value;
	EXPECT_NE(_old_value, expected);
	T result = Atomic::or_then_fetch(&_test_value, _change_value);
	EXPECT_EQ(expected, result);
	EXPECT_EQ(expected, Atomic::load(&_test_value));
	}

	void xor_then_fetch() {
	Atomic::store(&_test_value, _old_value);
	T expected = _old_value ^ _change_value;
	EXPECT_NE(_old_value, expected);
	T result = Atomic::xor_then_fetch(&_test_value, _change_value);
	EXPECT_EQ(expected, result);
	EXPECT_EQ(expected, Atomic::load(&_test_value));
	}

	#define TEST_BITOP(name) { SCOPED_TRACE(XSTR(name)); name(); }

	void operator()() {
	TEST_BITOP(fetch_then_and)
	TEST_BITOP(fetch_then_or)
	TEST_BITOP(fetch_then_xor)
	TEST_BITOP(and_then_fetch)
	TEST_BITOP(or_then_fetch)
	TEST_BITOP(xor_then_fetch)
	}

	#undef TEST_BITOP
	};

	template<typename T>
	const T AtomicBitopsTestSupport<T>::_old_value;

	template<typename T>
	const T AtomicBitopsTestSupport<T>::_change_value;

	TEST_VM(AtomicBitopsTest, int8) {
	AtomicBitopsTestSupport<int8_t>()();
	}

	TEST_VM(AtomicBitopsTest, uint8) {
	AtomicBitopsTestSupport<uint8_t>()();
	}

	TEST_VM(AtomicBitopsTest, int32) {
	AtomicBitopsTestSupport<int32_t>()();
	}

	TEST_VM(AtomicBitopsTest, uint32) {
	AtomicBitopsTestSupport<uint32_t>()();
	}

	TEST_VM(AtomicBitopsTest, int64) {
	// Check if 64-bit atomics are available on the machine.
	if (!VM_Version::supports_cx8()) return;

	AtomicBitopsTestSupport<int64_t>()();
	}

	TEST_VM(AtomicBitopsTest, uint64) {
	// Check if 64-bit atomics are available on the machine.
	if (!VM_Version::supports_cx8()) return;

	AtomicBitopsTestSupport<uint64_t>()();
	}