522 lines
16 KiB
C++
522 lines
16 KiB
C++
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// Copyright (c) 2012 The Chromium Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file.
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#include <stdio.h>
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#include <stdlib.h>
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#include <algorithm> // for min()
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#include "base/atomicops.h"
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#include "testing/gtest/include/gtest/gtest.h"
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// Number of bits in a size_t.
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static const int kSizeBits = 8 * sizeof(size_t);
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// The maximum size of a size_t.
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static const size_t kMaxSize = ~static_cast<size_t>(0);
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// Maximum positive size of a size_t if it were signed.
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static const size_t kMaxSignedSize = ((size_t(1) << (kSizeBits-1)) - 1);
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// An allocation size which is not too big to be reasonable.
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static const size_t kNotTooBig = 100000;
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// An allocation size which is just too big.
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static const size_t kTooBig = ~static_cast<size_t>(0);
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namespace {
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using std::min;
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// Fill a buffer of the specified size with a predetermined pattern
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static void Fill(unsigned char* buffer, int n) {
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for (int i = 0; i < n; i++) {
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buffer[i] = (i & 0xff);
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}
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}
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// Check that the specified buffer has the predetermined pattern
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// generated by Fill()
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static bool Valid(unsigned char* buffer, int n) {
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for (int i = 0; i < n; i++) {
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if (buffer[i] != (i & 0xff)) {
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return false;
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}
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}
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return true;
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}
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// Check that a buffer is completely zeroed.
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static bool IsZeroed(unsigned char* buffer, int n) {
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for (int i = 0; i < n; i++) {
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if (buffer[i] != 0) {
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return false;
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}
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}
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return true;
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}
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// Check alignment
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static void CheckAlignment(void* p, int align) {
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EXPECT_EQ(0, reinterpret_cast<uintptr_t>(p) & (align-1));
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}
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// Return the next interesting size/delta to check. Returns -1 if no more.
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static int NextSize(int size) {
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if (size < 100)
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return size+1;
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if (size < 100000) {
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// Find next power of two
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int power = 1;
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while (power < size)
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power <<= 1;
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// Yield (power-1, power, power+1)
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if (size < power-1)
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return power-1;
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if (size == power-1)
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return power;
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assert(size == power);
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return power+1;
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} else {
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return -1;
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}
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}
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#define GG_ULONGLONG(x) static_cast<uint64>(x)
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template <class AtomicType>
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static void TestAtomicIncrement() {
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// For now, we just test single threaded execution
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// use a guard value to make sure the NoBarrier_AtomicIncrement doesn't go
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// outside the expected address bounds. This is in particular to
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// test that some future change to the asm code doesn't cause the
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// 32-bit NoBarrier_AtomicIncrement to do the wrong thing on 64-bit machines.
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struct {
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AtomicType prev_word;
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AtomicType count;
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AtomicType next_word;
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} s;
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AtomicType prev_word_value, next_word_value;
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memset(&prev_word_value, 0xFF, sizeof(AtomicType));
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memset(&next_word_value, 0xEE, sizeof(AtomicType));
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s.prev_word = prev_word_value;
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s.count = 0;
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s.next_word = next_word_value;
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EXPECT_EQ(base::subtle::NoBarrier_AtomicIncrement(&s.count, 1), 1);
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EXPECT_EQ(s.count, 1);
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EXPECT_EQ(s.prev_word, prev_word_value);
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EXPECT_EQ(s.next_word, next_word_value);
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EXPECT_EQ(base::subtle::NoBarrier_AtomicIncrement(&s.count, 2), 3);
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EXPECT_EQ(s.count, 3);
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EXPECT_EQ(s.prev_word, prev_word_value);
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EXPECT_EQ(s.next_word, next_word_value);
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EXPECT_EQ(base::subtle::NoBarrier_AtomicIncrement(&s.count, 3), 6);
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EXPECT_EQ(s.count, 6);
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EXPECT_EQ(s.prev_word, prev_word_value);
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EXPECT_EQ(s.next_word, next_word_value);
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EXPECT_EQ(base::subtle::NoBarrier_AtomicIncrement(&s.count, -3), 3);
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EXPECT_EQ(s.count, 3);
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EXPECT_EQ(s.prev_word, prev_word_value);
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EXPECT_EQ(s.next_word, next_word_value);
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EXPECT_EQ(base::subtle::NoBarrier_AtomicIncrement(&s.count, -2), 1);
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EXPECT_EQ(s.count, 1);
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EXPECT_EQ(s.prev_word, prev_word_value);
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EXPECT_EQ(s.next_word, next_word_value);
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EXPECT_EQ(base::subtle::NoBarrier_AtomicIncrement(&s.count, -1), 0);
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EXPECT_EQ(s.count, 0);
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EXPECT_EQ(s.prev_word, prev_word_value);
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EXPECT_EQ(s.next_word, next_word_value);
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EXPECT_EQ(base::subtle::NoBarrier_AtomicIncrement(&s.count, -1), -1);
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EXPECT_EQ(s.count, -1);
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EXPECT_EQ(s.prev_word, prev_word_value);
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EXPECT_EQ(s.next_word, next_word_value);
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EXPECT_EQ(base::subtle::NoBarrier_AtomicIncrement(&s.count, -4), -5);
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EXPECT_EQ(s.count, -5);
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EXPECT_EQ(s.prev_word, prev_word_value);
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EXPECT_EQ(s.next_word, next_word_value);
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EXPECT_EQ(base::subtle::NoBarrier_AtomicIncrement(&s.count, 5), 0);
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EXPECT_EQ(s.count, 0);
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EXPECT_EQ(s.prev_word, prev_word_value);
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EXPECT_EQ(s.next_word, next_word_value);
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}
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#define NUM_BITS(T) (sizeof(T) * 8)
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template <class AtomicType>
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static void TestCompareAndSwap() {
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AtomicType value = 0;
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AtomicType prev = base::subtle::NoBarrier_CompareAndSwap(&value, 0, 1);
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EXPECT_EQ(1, value);
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EXPECT_EQ(0, prev);
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// Use test value that has non-zero bits in both halves, more for testing
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// 64-bit implementation on 32-bit platforms.
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const AtomicType k_test_val = (GG_ULONGLONG(1) <<
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(NUM_BITS(AtomicType) - 2)) + 11;
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value = k_test_val;
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prev = base::subtle::NoBarrier_CompareAndSwap(&value, 0, 5);
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EXPECT_EQ(k_test_val, value);
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EXPECT_EQ(k_test_val, prev);
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value = k_test_val;
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prev = base::subtle::NoBarrier_CompareAndSwap(&value, k_test_val, 5);
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EXPECT_EQ(5, value);
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EXPECT_EQ(k_test_val, prev);
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}
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template <class AtomicType>
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static void TestAtomicExchange() {
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AtomicType value = 0;
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AtomicType new_value = base::subtle::NoBarrier_AtomicExchange(&value, 1);
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EXPECT_EQ(1, value);
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EXPECT_EQ(0, new_value);
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// Use test value that has non-zero bits in both halves, more for testing
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// 64-bit implementation on 32-bit platforms.
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const AtomicType k_test_val = (GG_ULONGLONG(1) <<
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(NUM_BITS(AtomicType) - 2)) + 11;
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value = k_test_val;
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new_value = base::subtle::NoBarrier_AtomicExchange(&value, k_test_val);
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EXPECT_EQ(k_test_val, value);
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EXPECT_EQ(k_test_val, new_value);
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value = k_test_val;
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new_value = base::subtle::NoBarrier_AtomicExchange(&value, 5);
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EXPECT_EQ(5, value);
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EXPECT_EQ(k_test_val, new_value);
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}
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template <class AtomicType>
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static void TestAtomicIncrementBounds() {
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// Test increment at the half-width boundary of the atomic type.
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// It is primarily for testing at the 32-bit boundary for 64-bit atomic type.
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AtomicType test_val = GG_ULONGLONG(1) << (NUM_BITS(AtomicType) / 2);
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AtomicType value = test_val - 1;
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AtomicType new_value = base::subtle::NoBarrier_AtomicIncrement(&value, 1);
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EXPECT_EQ(test_val, value);
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EXPECT_EQ(value, new_value);
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base::subtle::NoBarrier_AtomicIncrement(&value, -1);
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EXPECT_EQ(test_val - 1, value);
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}
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// This is a simple sanity check that values are correct. Not testing
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// atomicity
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template <class AtomicType>
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static void TestStore() {
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const AtomicType kVal1 = static_cast<AtomicType>(0xa5a5a5a5a5a5a5a5LL);
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const AtomicType kVal2 = static_cast<AtomicType>(-1);
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AtomicType value;
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base::subtle::NoBarrier_Store(&value, kVal1);
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EXPECT_EQ(kVal1, value);
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base::subtle::NoBarrier_Store(&value, kVal2);
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EXPECT_EQ(kVal2, value);
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base::subtle::Acquire_Store(&value, kVal1);
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EXPECT_EQ(kVal1, value);
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base::subtle::Acquire_Store(&value, kVal2);
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EXPECT_EQ(kVal2, value);
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base::subtle::Release_Store(&value, kVal1);
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EXPECT_EQ(kVal1, value);
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base::subtle::Release_Store(&value, kVal2);
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EXPECT_EQ(kVal2, value);
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}
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// This is a simple sanity check that values are correct. Not testing
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// atomicity
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template <class AtomicType>
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static void TestLoad() {
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const AtomicType kVal1 = static_cast<AtomicType>(0xa5a5a5a5a5a5a5a5LL);
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const AtomicType kVal2 = static_cast<AtomicType>(-1);
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AtomicType value;
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value = kVal1;
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EXPECT_EQ(kVal1, base::subtle::NoBarrier_Load(&value));
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value = kVal2;
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EXPECT_EQ(kVal2, base::subtle::NoBarrier_Load(&value));
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value = kVal1;
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EXPECT_EQ(kVal1, base::subtle::Acquire_Load(&value));
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value = kVal2;
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EXPECT_EQ(kVal2, base::subtle::Acquire_Load(&value));
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value = kVal1;
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EXPECT_EQ(kVal1, base::subtle::Release_Load(&value));
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value = kVal2;
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EXPECT_EQ(kVal2, base::subtle::Release_Load(&value));
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}
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template <class AtomicType>
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static void TestAtomicOps() {
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TestCompareAndSwap<AtomicType>();
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TestAtomicExchange<AtomicType>();
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TestAtomicIncrementBounds<AtomicType>();
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TestStore<AtomicType>();
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TestLoad<AtomicType>();
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}
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static void TestCalloc(size_t n, size_t s, bool ok) {
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char* p = reinterpret_cast<char*>(calloc(n, s));
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if (!ok) {
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EXPECT_EQ(NULL, p) << "calloc(n, s) should not succeed";
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} else {
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EXPECT_NE(reinterpret_cast<void*>(NULL), p) <<
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"calloc(n, s) should succeed";
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for (int i = 0; i < n*s; i++) {
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EXPECT_EQ('\0', p[i]);
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}
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free(p);
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}
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}
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// A global test counter for number of times the NewHandler is called.
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static int news_handled = 0;
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static void TestNewHandler() {
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++news_handled;
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throw std::bad_alloc();
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}
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// Because we compile without exceptions, we expect these will not throw.
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static void TestOneNewWithoutExceptions(void* (*func)(size_t),
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bool should_throw) {
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// success test
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try {
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void* ptr = (*func)(kNotTooBig);
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EXPECT_NE(reinterpret_cast<void*>(NULL), ptr) <<
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"allocation should not have failed.";
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} catch(...) {
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EXPECT_EQ(0, 1) << "allocation threw unexpected exception.";
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}
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// failure test
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try {
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void* rv = (*func)(kTooBig);
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EXPECT_EQ(NULL, rv);
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EXPECT_FALSE(should_throw) << "allocation should have thrown.";
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} catch(...) {
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EXPECT_TRUE(should_throw) << "allocation threw unexpected exception.";
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}
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}
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static void TestNothrowNew(void* (*func)(size_t)) {
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news_handled = 0;
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// test without new_handler:
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std::new_handler saved_handler = std::set_new_handler(0);
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TestOneNewWithoutExceptions(func, false);
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// test with new_handler:
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std::set_new_handler(TestNewHandler);
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TestOneNewWithoutExceptions(func, true);
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EXPECT_EQ(news_handled, 1) << "nothrow new_handler was not called.";
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std::set_new_handler(saved_handler);
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}
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} // namespace
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//-----------------------------------------------------------------------------
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TEST(Atomics, AtomicIncrementWord) {
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TestAtomicIncrement<AtomicWord>();
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}
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TEST(Atomics, AtomicIncrement32) {
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TestAtomicIncrement<Atomic32>();
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}
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TEST(Atomics, AtomicOpsWord) {
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TestAtomicIncrement<AtomicWord>();
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}
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TEST(Atomics, AtomicOps32) {
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TestAtomicIncrement<Atomic32>();
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}
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TEST(Allocators, Malloc) {
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// Try allocating data with a bunch of alignments and sizes
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for (int size = 1; size < 1048576; size *= 2) {
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unsigned char* ptr = reinterpret_cast<unsigned char*>(malloc(size));
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CheckAlignment(ptr, 2); // Should be 2 byte aligned
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Fill(ptr, size);
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EXPECT_TRUE(Valid(ptr, size));
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free(ptr);
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}
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}
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TEST(Allocators, Calloc) {
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TestCalloc(0, 0, true);
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TestCalloc(0, 1, true);
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TestCalloc(1, 1, true);
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TestCalloc(1<<10, 0, true);
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TestCalloc(1<<20, 0, true);
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TestCalloc(0, 1<<10, true);
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TestCalloc(0, 1<<20, true);
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TestCalloc(1<<20, 2, true);
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TestCalloc(2, 1<<20, true);
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TestCalloc(1000, 1000, true);
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TestCalloc(kMaxSize, 2, false);
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TestCalloc(2, kMaxSize, false);
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TestCalloc(kMaxSize, kMaxSize, false);
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TestCalloc(kMaxSignedSize, 3, false);
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TestCalloc(3, kMaxSignedSize, false);
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TestCalloc(kMaxSignedSize, kMaxSignedSize, false);
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}
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TEST(Allocators, New) {
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TestNothrowNew(&::operator new);
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TestNothrowNew(&::operator new[]);
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}
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// This makes sure that reallocing a small number of bytes in either
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// direction doesn't cause us to allocate new memory.
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TEST(Allocators, Realloc1) {
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int start_sizes[] = { 100, 1000, 10000, 100000 };
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int deltas[] = { 1, -2, 4, -8, 16, -32, 64, -128 };
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for (int s = 0; s < sizeof(start_sizes)/sizeof(*start_sizes); ++s) {
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void* p = malloc(start_sizes[s]);
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ASSERT_TRUE(p);
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// The larger the start-size, the larger the non-reallocing delta.
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for (int d = 0; d < s*2; ++d) {
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void* new_p = realloc(p, start_sizes[s] + deltas[d]);
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ASSERT_EQ(p, new_p); // realloc should not allocate new memory
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}
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// Test again, but this time reallocing smaller first.
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for (int d = 0; d < s*2; ++d) {
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void* new_p = realloc(p, start_sizes[s] - deltas[d]);
|
||
|
ASSERT_EQ(p, new_p); // realloc should not allocate new memory
|
||
|
}
|
||
|
free(p);
|
||
|
}
|
||
|
}
|
||
|
|
||
|
TEST(Allocators, Realloc2) {
|
||
|
for (int src_size = 0; src_size >= 0; src_size = NextSize(src_size)) {
|
||
|
for (int dst_size = 0; dst_size >= 0; dst_size = NextSize(dst_size)) {
|
||
|
unsigned char* src = reinterpret_cast<unsigned char*>(malloc(src_size));
|
||
|
Fill(src, src_size);
|
||
|
unsigned char* dst =
|
||
|
reinterpret_cast<unsigned char*>(realloc(src, dst_size));
|
||
|
EXPECT_TRUE(Valid(dst, min(src_size, dst_size)));
|
||
|
Fill(dst, dst_size);
|
||
|
EXPECT_TRUE(Valid(dst, dst_size));
|
||
|
if (dst != NULL) free(dst);
|
||
|
}
|
||
|
}
|
||
|
|
||
|
// Now make sure realloc works correctly even when we overflow the
|
||
|
// packed cache, so some entries are evicted from the cache.
|
||
|
// The cache has 2^12 entries, keyed by page number.
|
||
|
const int kNumEntries = 1 << 14;
|
||
|
int** p = reinterpret_cast<int**>(malloc(sizeof(*p) * kNumEntries));
|
||
|
int sum = 0;
|
||
|
for (int i = 0; i < kNumEntries; i++) {
|
||
|
// no page size is likely to be bigger than 8192?
|
||
|
p[i] = reinterpret_cast<int*>(malloc(8192));
|
||
|
p[i][1000] = i; // use memory deep in the heart of p
|
||
|
}
|
||
|
for (int i = 0; i < kNumEntries; i++) {
|
||
|
p[i] = reinterpret_cast<int*>(realloc(p[i], 9000));
|
||
|
}
|
||
|
for (int i = 0; i < kNumEntries; i++) {
|
||
|
sum += p[i][1000];
|
||
|
free(p[i]);
|
||
|
}
|
||
|
EXPECT_EQ(kNumEntries/2 * (kNumEntries - 1), sum); // assume kNE is even
|
||
|
free(p);
|
||
|
}
|
||
|
|
||
|
TEST(Allocators, ReallocZero) {
|
||
|
// Test that realloc to zero does not return NULL.
|
||
|
for (int size = 0; size >= 0; size = NextSize(size)) {
|
||
|
char* ptr = reinterpret_cast<char*>(malloc(size));
|
||
|
EXPECT_NE(static_cast<char*>(NULL), ptr);
|
||
|
ptr = reinterpret_cast<char*>(realloc(ptr, 0));
|
||
|
EXPECT_NE(static_cast<char*>(NULL), ptr);
|
||
|
if (ptr)
|
||
|
free(ptr);
|
||
|
}
|
||
|
}
|
||
|
|
||
|
#ifdef WIN32
|
||
|
// Test recalloc
|
||
|
TEST(Allocators, Recalloc) {
|
||
|
for (int src_size = 0; src_size >= 0; src_size = NextSize(src_size)) {
|
||
|
for (int dst_size = 0; dst_size >= 0; dst_size = NextSize(dst_size)) {
|
||
|
unsigned char* src =
|
||
|
reinterpret_cast<unsigned char*>(_recalloc(NULL, 1, src_size));
|
||
|
EXPECT_TRUE(IsZeroed(src, src_size));
|
||
|
Fill(src, src_size);
|
||
|
unsigned char* dst =
|
||
|
reinterpret_cast<unsigned char*>(_recalloc(src, 1, dst_size));
|
||
|
EXPECT_TRUE(Valid(dst, min(src_size, dst_size)));
|
||
|
Fill(dst, dst_size);
|
||
|
EXPECT_TRUE(Valid(dst, dst_size));
|
||
|
if (dst != NULL)
|
||
|
free(dst);
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
|
||
|
// Test windows specific _aligned_malloc() and _aligned_free() methods.
|
||
|
TEST(Allocators, AlignedMalloc) {
|
||
|
// Try allocating data with a bunch of alignments and sizes
|
||
|
static const int kTestAlignments[] = {8, 16, 256, 4096, 8192, 16384};
|
||
|
for (int size = 1; size > 0; size = NextSize(size)) {
|
||
|
for (int i = 0; i < ARRAYSIZE(kTestAlignments); ++i) {
|
||
|
unsigned char* ptr = static_cast<unsigned char*>(
|
||
|
_aligned_malloc(size, kTestAlignments[i]));
|
||
|
CheckAlignment(ptr, kTestAlignments[i]);
|
||
|
Fill(ptr, size);
|
||
|
EXPECT_TRUE(Valid(ptr, size));
|
||
|
|
||
|
// Make a second allocation of the same size and alignment to prevent
|
||
|
// allocators from passing this test by accident. Per jar, tcmalloc
|
||
|
// provides allocations for new (never before seen) sizes out of a thread
|
||
|
// local heap of a given "size class." Each time the test requests a new
|
||
|
// size, it will usually get the first element of a span, which is a
|
||
|
// 4K aligned allocation.
|
||
|
unsigned char* ptr2 = static_cast<unsigned char*>(
|
||
|
_aligned_malloc(size, kTestAlignments[i]));
|
||
|
CheckAlignment(ptr2, kTestAlignments[i]);
|
||
|
Fill(ptr2, size);
|
||
|
EXPECT_TRUE(Valid(ptr2, size));
|
||
|
|
||
|
// Should never happen, but sanity check just in case.
|
||
|
ASSERT_NE(ptr, ptr2);
|
||
|
_aligned_free(ptr);
|
||
|
_aligned_free(ptr2);
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
|
||
|
#endif
|
||
|
|
||
|
|
||
|
int main(int argc, char** argv) {
|
||
|
testing::InitGoogleTest(&argc, argv);
|
||
|
return RUN_ALL_TESTS();
|
||
|
}
|