/*
- * Copyright 2013 Facebook, Inc.
+ * Copyright 2013-present Facebook, Inc.
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* limitations under the License.
*/
-#include "folly/io/IOBuf.h"
-#include "folly/io/TypedIOBuf.h"
+#include <folly/io/IOBuf.h>
+#include <folly/io/TypedIOBuf.h>
-// googletest requires std::tr1::tuple, not std::tuple
-#include <tr1/tuple>
+#include <cstddef>
-#include <gflags/gflags.h>
#include <boost/random.hpp>
-#include <gtest/gtest.h>
-#include "folly/Malloc.h"
-#include "folly/Range.h"
+#include <folly/Range.h>
+#include <folly/memory/Malloc.h>
+#include <folly/portability/GTest.h>
using folly::fbstring;
using folly::fbvector;
iobuf3.reset();
EXPECT_EQ(1, deleteCount);
-
+ deleteCount = 0;
+ {
+ uint32_t size4 = 1234;
+ uint8_t *buf4 = new uint8_t[size4];
+ uint32_t length4 = 48;
+ IOBuf iobuf4(IOBuf::TAKE_OWNERSHIP, buf4, size4, length4,
+ deleteArrayBuffer, &deleteCount);
+ EXPECT_EQ(buf4, iobuf4.data());
+ EXPECT_EQ(length4, iobuf4.length());
+ EXPECT_EQ(buf4, iobuf4.buffer());
+ EXPECT_EQ(size4, iobuf4.capacity());
+
+ IOBuf iobuf5 = std::move(iobuf4);
+ EXPECT_EQ(buf4, iobuf5.data());
+ EXPECT_EQ(length4, iobuf5.length());
+ EXPECT_EQ(buf4, iobuf5.buffer());
+ EXPECT_EQ(size4, iobuf5.capacity());
+ EXPECT_EQ(0, deleteCount);
+ }
+ EXPECT_EQ(1, deleteCount);
}
TEST(IOBuf, WrapBuffer) {
EXPECT_EQ(size2, iobuf2->length());
EXPECT_EQ(buf2.get(), iobuf2->buffer());
EXPECT_EQ(size2, iobuf2->capacity());
+
+ uint32_t size3 = 4321;
+ unique_ptr<uint8_t[]> buf3(new uint8_t[size3]);
+ IOBuf iobuf3(IOBuf::WRAP_BUFFER, buf3.get(), size3);
+ EXPECT_EQ(buf3.get(), iobuf3.data());
+ EXPECT_EQ(size3, iobuf3.length());
+ EXPECT_EQ(buf3.get(), iobuf3.buffer());
+ EXPECT_EQ(size3, iobuf3.capacity());
+
+ const uint32_t size4 = 2345;
+ unique_ptr<uint8_t[]> buf4(new uint8_t[size4]);
+ IOBuf iobuf4 = IOBuf::wrapBufferAsValue(buf4.get(), size4);
+ EXPECT_EQ(buf4.get(), iobuf4.data());
+ EXPECT_EQ(size4, iobuf4.length());
+ EXPECT_EQ(buf4.get(), iobuf4.buffer());
+ EXPECT_EQ(size4, iobuf4.capacity());
+}
+
+TEST(IOBuf, CreateCombined) {
+ // Create a combined IOBuf, then destroy it.
+ // The data buffer and IOBuf both become unused as part of the destruction
+ {
+ auto buf = IOBuf::createCombined(256);
+ EXPECT_FALSE(buf->isShared());
+ }
+
+ // Create a combined IOBuf, clone from it, and then destroy the original
+ // IOBuf. The data buffer cannot be deleted until the clone is also
+ // destroyed.
+ {
+ auto bufA = IOBuf::createCombined(256);
+ EXPECT_FALSE(bufA->isShared());
+ auto bufB = bufA->clone();
+ EXPECT_TRUE(bufA->isShared());
+ EXPECT_TRUE(bufB->isShared());
+ bufA.reset();
+ EXPECT_FALSE(bufB->isShared());
+ }
+
+ // Create a combined IOBuf, then call reserve() to get a larger buffer.
+ // The IOBuf no longer points to the combined data buffer, but the
+ // overall memory segment cannot be deleted until the IOBuf is also
+ // destroyed.
+ {
+ auto buf = IOBuf::createCombined(256);
+ buf->reserve(0, buf->capacity() + 100);
+ }
+
+ // Create a combined IOBuf, clone from it, then call unshare() on the original
+ // buffer. This creates a situation where bufB is pointing at the combined
+ // buffer associated with bufA, but bufA is now using a different buffer.
+ auto testSwap = [](bool resetAFirst) {
+ auto bufA = IOBuf::createCombined(256);
+ EXPECT_FALSE(bufA->isShared());
+ auto bufB = bufA->clone();
+ EXPECT_TRUE(bufA->isShared());
+ EXPECT_TRUE(bufB->isShared());
+ bufA->unshare();
+ EXPECT_FALSE(bufA->isShared());
+ EXPECT_FALSE(bufB->isShared());
+
+ if (resetAFirst) {
+ bufA.reset();
+ bufB.reset();
+ } else {
+ bufB.reset();
+ bufA.reset();
+ }
+ };
+ testSwap(true);
+ testSwap(false);
}
void fillBuf(uint8_t* buf, uint32_t length, boost::mt19937& gen) {
EXPECT_TRUE(iob1->isShared());
EXPECT_TRUE(iob1->isSharedOne());
- // since iob2 has a small internal buffer, it will never be shared
- EXPECT_FALSE(iob2ptr->isSharedOne());
+ EXPECT_TRUE(iob2ptr->isSharedOne());
EXPECT_TRUE(iob3ptr->isSharedOne());
EXPECT_TRUE(iob4ptr->isSharedOne());
EXPECT_TRUE(iob5ptr->isSharedOne());
EXPECT_EQ(0, arrayBufFreeCount);
// Buffer lengths: 1500 20 1234 900 321
+ // Attempting to gather more data than available should fail
+ EXPECT_THROW(chainClone->gather(4000), std::overflow_error);
// Coalesce the first 3 buffers
chainClone->gather(1521);
EXPECT_EQ(3, chainClone->countChainElements());
gen.seed(fillSeed);
checkChain(chainClone.get(), gen);
+ // cloneCoalesced
+ {
+ auto chainCloneCoalesced = chainClone->cloneCoalesced();
+ EXPECT_EQ(1, chainCloneCoalesced->countChainElements());
+ EXPECT_EQ(fullLength, chainCloneCoalesced->computeChainDataLength());
+ gen.seed(fillSeed);
+ checkChain(chainCloneCoalesced.get(), gen);
+ }
+
// Coalesce the entire chain
chainClone->coalesce();
EXPECT_EQ(1, chainClone->countChainElements());
EXPECT_EQ(3, iob2->computeChainDataLength());
}
+void testFreeFn(void* buffer, void* ptr) {
+ uint32_t* freeCount = static_cast<uint32_t*>(ptr);;
+ delete[] static_cast<uint8_t*>(buffer);
+ if (freeCount) {
+ ++(*freeCount);
+ }
+};
+
TEST(IOBuf, Reserve) {
uint32_t fillSeed = 0x23456789;
boost::mt19937 gen(fillSeed);
EXPECT_EQ(0, iob->headroom());
EXPECT_EQ(100, iob->length());
const void* p1 = iob->buffer();
- const uint8_t* d1 = iob->data();
iob->reserve(100, 2512); // allocation sizes are multiples of 256
EXPECT_LE(100, iob->headroom());
if (folly::usingJEMalloc()) {
EXPECT_EQ(0, iob->headroom());
EXPECT_LE(2000, iob->tailroom());
}
+
+ // Test reserving from a user-allocated buffer.
+ {
+ uint8_t* buf = static_cast<uint8_t*>(malloc(100));
+ auto iob = IOBuf::takeOwnership(buf, 100);
+ iob->reserve(0, 2000);
+ EXPECT_EQ(0, iob->headroom());
+ EXPECT_LE(2000, iob->tailroom());
+ }
+
+ // Test reserving from a user-allocated with a custom free function.
+ {
+ uint32_t freeCount{0};
+ uint8_t* buf = new uint8_t[100];
+ auto iob = IOBuf::takeOwnership(buf, 100, testFreeFn, &freeCount);
+ iob->reserve(0, 2000);
+ EXPECT_EQ(0, iob->headroom());
+ EXPECT_LE(2000, iob->tailroom());
+ EXPECT_EQ(1, freeCount);
+ }
}
TEST(IOBuf, copyBuffer) {
EXPECT_EQ(3, buf->headroom());
EXPECT_EQ(0, buf->length());
EXPECT_LE(6, buf->tailroom());
+
+ // A stack-allocated version
+ IOBuf stackBuf(IOBuf::COPY_BUFFER, s, 1, 2);
+ EXPECT_EQ(1, stackBuf.headroom());
+ EXPECT_EQ(s, std::string(reinterpret_cast<const char*>(stackBuf.data()),
+ stackBuf.length()));
+ EXPECT_LE(2, stackBuf.tailroom());
}
TEST(IOBuf, maybeCopyBuffer) {
EXPECT_EQ(nullptr, buf.get());
}
+TEST(IOBuf, copyEmptyBuffer) {
+ auto buf = IOBuf::copyBuffer(nullptr, 0);
+ EXPECT_EQ(buf->length(), 0);
+}
+
namespace {
int customDeleterCount = 0;
delete[] p;
}
-} // namespace
+} // namespace
TEST(IOBuf, takeOwnershipUniquePtr) {
destructorCount = 0;
destructorCount = 0;
{
std::unique_ptr<OwnershipTestClass[], CustomDeleter>
- p(new OwnershipTestClass[2], customDeleteArray);
+ p(new OwnershipTestClass[2], CustomDeleter(customDeleteArray));
std::unique_ptr<IOBuf> buf(IOBuf::takeOwnership(std::move(p), 2));
EXPECT_EQ(2 * sizeof(OwnershipTestClass), buf->length());
EXPECT_EQ(0, destructorCount);
}
TEST(IOBuf, Alignment) {
- // max_align_t doesn't exist in gcc 4.6.2
- struct MaxAlign {
- char c;
- } __attribute__((aligned));
- size_t alignment = alignof(MaxAlign);
+ size_t alignment = alignof(std::max_align_t);
std::vector<size_t> sizes {0, 1, 64, 256, 1024, 1 << 10};
for (size_t size : sizes) {
EXPECT_EQ(i, typed.data()[i]);
}
}
+enum BufType {
+ CREATE,
+ TAKE_OWNERSHIP_MALLOC,
+ TAKE_OWNERSHIP_CUSTOM,
+ USER_OWNED,
+};
// chain element size, number of elements in chain, shared
class MoveToFbStringTest
- : public ::testing::TestWithParam<std::tr1::tuple<int, int, bool>> {
+ : public ::testing::TestWithParam<std::tr1::tuple<int, int, bool, BufType>> {
protected:
- void SetUp() {
- std::tr1::tie(elementSize_, elementCount_, shared_) = GetParam();
+ void SetUp() override {
+ elementSize_ = std::tr1::get<0>(GetParam());
+ elementCount_ = std::tr1::get<1>(GetParam());
+ shared_ = std::tr1::get<2>(GetParam());
+ type_ = std::tr1::get<3>(GetParam());
+
buf_ = makeBuf();
for (int i = 0; i < elementCount_ - 1; ++i) {
buf_->prependChain(makeBuf());
}
std::unique_ptr<IOBuf> makeBuf() {
- auto buf = IOBuf::create(elementSize_);
- memset(buf->writableTail(), 'x', elementSize_);
- buf->append(elementSize_);
+ unique_ptr<IOBuf> buf;
+ switch (type_) {
+ case CREATE:
+ buf = IOBuf::create(elementSize_);
+ buf->append(elementSize_);
+ break;
+ case TAKE_OWNERSHIP_MALLOC: {
+ void* data = malloc(elementSize_);
+ if (!data) {
+ throw std::bad_alloc();
+ }
+ buf = IOBuf::takeOwnership(data, elementSize_);
+ break;
+ }
+ case TAKE_OWNERSHIP_CUSTOM: {
+ uint8_t* data = new uint8_t[elementSize_];
+ buf = IOBuf::takeOwnership(data, elementSize_, testFreeFn);
+ break;
+ }
+ case USER_OWNED: {
+ unique_ptr<uint8_t[]> data(new uint8_t[elementSize_]);
+ buf = IOBuf::wrapBuffer(data.get(), elementSize_);
+ ownedBuffers_.emplace_back(std::move(data));
+ break;
+ }
+ default:
+ throw std::invalid_argument("unexpected buffer type parameter");
+ }
+ memset(buf->writableData(), 'x', elementSize_);
return buf;
}
int elementSize_;
int elementCount_;
bool shared_;
+ BufType type_;
std::unique_ptr<IOBuf> buf_;
std::unique_ptr<IOBuf> buf2_;
+ std::vector<std::unique_ptr<uint8_t[]>> ownedBuffers_;
};
TEST_P(MoveToFbStringTest, Simple) {
::testing::Combine(
::testing::Values(0, 1, 24, 256, 1 << 10, 1 << 20), // element size
::testing::Values(1, 2, 10), // element count
- ::testing::Bool())); // shared
+ ::testing::Bool(), // shared
+ ::testing::Values(CREATE, TAKE_OWNERSHIP_MALLOC,
+ TAKE_OWNERSHIP_CUSTOM, USER_OWNED)));
TEST(IOBuf, getIov) {
uint32_t fillSeed = 0xdeadbeef;
buf->prev()->clear();
iov = buf->getIov();
EXPECT_EQ(count - 3, iov.size());
+
+ // test appending to an existing iovec array
+ iov.clear();
+ const char localBuf[] = "hello";
+ iov.push_back({(void*)localBuf, sizeof(localBuf)});
+ iov.push_back({(void*)localBuf, sizeof(localBuf)});
+ buf->appendToIov(&iov);
+ EXPECT_EQ(count - 1, iov.size());
+ EXPECT_EQ(localBuf, iov[0].iov_base);
+ EXPECT_EQ(localBuf, iov[1].iov_base);
+ // The first two IOBufs were cleared, so the next iov entry
+ // should be the third IOBuf in the chain.
+ EXPECT_EQ(buf->next()->next()->data(), iov[2].iov_base);
}
-int main(int argc, char** argv) {
- testing::InitGoogleTest(&argc, argv);
- google::ParseCommandLineFlags(&argc, &argv, true);
+TEST(IOBuf, move) {
+ // Default allocate an IOBuf on the stack
+ IOBuf outerBuf;
+ char data[] = "foobar";
+ uint32_t length = sizeof(data);
+ uint32_t actualCapacity{0};
+ const void* ptr{nullptr};
+
+ {
+ // Create a small IOBuf on the stack.
+ // Note that IOBufs created on the stack always use an external buffer.
+ IOBuf b1(IOBuf::CREATE, 10);
+ actualCapacity = b1.capacity();
+ EXPECT_GE(actualCapacity, 10);
+ EXPECT_EQ(0, b1.length());
+ EXPECT_FALSE(b1.isShared());
+ ptr = b1.data();
+ ASSERT_TRUE(ptr != nullptr);
+ memcpy(b1.writableTail(), data, length);
+ b1.append(length);
+ EXPECT_EQ(length, b1.length());
+
+ // Use the move constructor
+ IOBuf b2(std::move(b1));
+ EXPECT_EQ(ptr, b2.data());
+ EXPECT_EQ(length, b2.length());
+ EXPECT_EQ(actualCapacity, b2.capacity());
+ EXPECT_FALSE(b2.isShared());
+
+ // Use the move assignment operator
+ outerBuf = std::move(b2);
+ // Close scope, destroying b1 and b2
+ // (which are both be invalid now anyway after moving out of them)
+ }
+
+ EXPECT_EQ(ptr, outerBuf.data());
+ EXPECT_EQ(length, outerBuf.length());
+ EXPECT_EQ(actualCapacity, outerBuf.capacity());
+ EXPECT_FALSE(outerBuf.isShared());
+}
+
+namespace {
+std::unique_ptr<IOBuf> fromStr(StringPiece sp) {
+ return IOBuf::copyBuffer(ByteRange(sp));
+}
+} // namespace
+
+TEST(IOBuf, HashAndEqual) {
+ folly::IOBufEqual eq;
+ folly::IOBufHash hash;
+
+ EXPECT_TRUE(eq(nullptr, nullptr));
+ EXPECT_EQ(0, hash(nullptr));
+
+ auto empty = IOBuf::create(0);
+
+ EXPECT_TRUE(eq(*empty, *empty));
+ EXPECT_TRUE(eq(empty, empty));
+
+ EXPECT_FALSE(eq(nullptr, empty));
+ EXPECT_FALSE(eq(empty, nullptr));
+
+ EXPECT_EQ(hash(*empty), hash(empty));
+ EXPECT_NE(0, hash(empty));
+
+ auto a = fromStr("hello");
+
+ EXPECT_TRUE(eq(*a, *a));
+ EXPECT_TRUE(eq(a, a));
+
+ EXPECT_FALSE(eq(nullptr, a));
+ EXPECT_FALSE(eq(a, nullptr));
+
+ EXPECT_EQ(hash(*a), hash(a));
+ EXPECT_NE(0, hash(a));
+
+ auto b = fromStr("hello");
- return RUN_ALL_TESTS();
+ EXPECT_TRUE(eq(*a, *b));
+ EXPECT_TRUE(eq(a, b));
+
+ EXPECT_EQ(hash(a), hash(b));
+
+ auto c = fromStr("hellow");
+
+ EXPECT_FALSE(eq(a, c));
+ EXPECT_NE(hash(a), hash(c));
+
+ auto d = fromStr("world");
+
+ EXPECT_FALSE(eq(a, d));
+ EXPECT_NE(hash(a), hash(d));
+
+ auto e = fromStr("helloworld");
+ auto f = fromStr("hello");
+ f->prependChain(fromStr("wo"));
+ f->prependChain(fromStr("rld"));
+
+ EXPECT_TRUE(eq(e, f));
+ EXPECT_EQ(hash(e), hash(f));
+}
+
+// reserveSlow() had a bug when reallocating the buffer in place. It would
+// preserve old headroom if it's not too much (heuristically) but wouldn't
+// adjust the requested amount of memory to account for that; the end result
+// would be that reserve() would return with less tailroom than requested.
+TEST(IOBuf, ReserveWithHeadroom) {
+ // This is assuming jemalloc, where we know that 4096 and 8192 bytes are
+ // valid (and consecutive) allocation sizes. We're hoping that our
+ // 4096-byte buffer can be expanded in place to 8192 (in practice, this
+ // usually happens).
+ const char data[] = "Lorem ipsum dolor sit amet, consectetur adipiscing elit";
+ constexpr size_t reservedSize = 24; // sizeof(SharedInfo)
+ // chosen carefully so that the buffer is exactly 4096 bytes
+ IOBuf buf(IOBuf::CREATE, 4096 - reservedSize);
+ buf.advance(10);
+ memcpy(buf.writableData(), data, sizeof(data));
+ buf.append(sizeof(data));
+ EXPECT_EQ(sizeof(data), buf.length());
+
+ // Grow the buffer (hopefully in place); this would incorrectly reserve
+ // the 10 bytes of headroom, giving us 10 bytes less than requested.
+ size_t tailroom = 8192 - reservedSize - sizeof(data);
+ buf.reserve(0, tailroom);
+ EXPECT_LE(tailroom, buf.tailroom());
+ EXPECT_EQ(sizeof(data), buf.length());
+ EXPECT_EQ(0, memcmp(data, buf.data(), sizeof(data)));
+}
+
+TEST(IOBuf, CopyConstructorAndAssignmentOperator) {
+ auto buf = IOBuf::create(4096);
+ append(buf, "hello world");
+ auto buf2 = IOBuf::create(4096);
+ append(buf2, " goodbye");
+ buf->prependChain(std::move(buf2));
+ EXPECT_FALSE(buf->isShared());
+
+ {
+ auto copy = *buf;
+ EXPECT_TRUE(buf->isShared());
+ EXPECT_TRUE(copy.isShared());
+ EXPECT_EQ((void*)buf->data(), (void*)copy.data());
+ EXPECT_NE(buf->next(), copy.next()); // actually different buffers
+
+ auto copy2 = *buf;
+ copy2.coalesce();
+ EXPECT_TRUE(buf->isShared());
+ EXPECT_TRUE(copy.isShared());
+ EXPECT_FALSE(copy2.isShared());
+
+ auto p = reinterpret_cast<const char*>(copy2.data());
+ EXPECT_EQ("hello world goodbye", std::string(p, copy2.length()));
+ }
+
+ EXPECT_FALSE(buf->isShared());
+
+ {
+ folly::IOBuf newBuf(folly::IOBuf::CREATE, 4096);
+ EXPECT_FALSE(newBuf.isShared());
+
+ auto newBufCopy = newBuf;
+ EXPECT_TRUE(newBuf.isShared());
+ EXPECT_TRUE(newBufCopy.isShared());
+
+ newBufCopy = *buf;
+ EXPECT_TRUE(buf->isShared());
+ EXPECT_FALSE(newBuf.isShared());
+ EXPECT_TRUE(newBufCopy.isShared());
+ }
+
+ EXPECT_FALSE(buf->isShared());
+}
+
+TEST(IOBuf, CloneAsValue) {
+ auto buf = IOBuf::create(4096);
+ append(buf, "hello world");
+ {
+ auto buf2 = IOBuf::create(4096);
+ append(buf2, " goodbye");
+ buf->prependChain(std::move(buf2));
+ EXPECT_FALSE(buf->isShared());
+ }
+
+ {
+ auto copy = buf->cloneOneAsValue();
+ EXPECT_TRUE(buf->isShared());
+ EXPECT_TRUE(copy.isShared());
+ EXPECT_EQ((void*)buf->data(), (void*)copy.data());
+ EXPECT_TRUE(buf->isChained());
+ EXPECT_FALSE(copy.isChained());
+
+ auto copy2 = buf->cloneAsValue();
+ EXPECT_TRUE(buf->isShared());
+ EXPECT_TRUE(copy.isShared());
+ EXPECT_TRUE(copy2.isShared());
+ EXPECT_TRUE(buf->isChained());
+ EXPECT_TRUE(copy2.isChained());
+
+ copy.unshareOne();
+ EXPECT_TRUE(buf->isShared());
+ EXPECT_FALSE(copy.isShared());
+ EXPECT_NE((void*)buf->data(), (void*)copy.data());
+ EXPECT_TRUE(copy2.isShared());
+
+ auto p = reinterpret_cast<const char*>(copy.data());
+ EXPECT_EQ("hello world", std::string(p, copy.length()));
+
+ copy2.coalesce();
+ EXPECT_FALSE(buf->isShared());
+ EXPECT_FALSE(copy.isShared());
+ EXPECT_FALSE(copy2.isShared());
+ EXPECT_FALSE(copy2.isChained());
+
+ auto p2 = reinterpret_cast<const char*>(copy2.data());
+ EXPECT_EQ("hello world goodbye", std::string(p2, copy2.length()));
+ }
+
+ EXPECT_FALSE(buf->isShared());
+}
+
+namespace {
+// Use with string literals only
+std::unique_ptr<IOBuf> wrap(const char* str) {
+ return IOBuf::wrapBuffer(str, strlen(str));
+}
+
+std::unique_ptr<IOBuf> copy(const char* str) {
+ // At least 1KiB of tailroom, to ensure an external buffer
+ return IOBuf::copyBuffer(str, strlen(str), 0, 1024);
+}
+
+std::string toString(const folly::IOBuf& buf) {
+ std::string result;
+ result.reserve(buf.computeChainDataLength());
+ for (auto& b : buf) {
+ result.append(reinterpret_cast<const char*>(b.data()), b.size());
+ }
+ return result;
+}
+
+char* writableStr(folly::IOBuf& buf) {
+ return reinterpret_cast<char*>(buf.writableData());
+}
+
+} // namespace
+
+TEST(IOBuf, ExternallyShared) {
+ struct Item {
+ Item(const char* src, size_t len) : size(len) {
+ CHECK_LE(len, sizeof(buffer));
+ memcpy(buffer, src, len);
+ }
+ uint32_t refcount{0};
+ uint8_t size;
+ char buffer[256];
+ };
+
+ auto hello = "hello";
+ struct Item it(hello, strlen(hello));
+
+ {
+ auto freeFn = [](void* /* unused */, void* userData) {
+ auto it = static_cast<struct Item*>(userData);
+ it->refcount--;
+ };
+ it.refcount++;
+ auto buf1 = IOBuf::takeOwnership(it.buffer, it.size, freeFn, &it);
+ EXPECT_TRUE(buf1->isManagedOne());
+ EXPECT_FALSE(buf1->isSharedOne());
+
+ buf1->markExternallyShared();
+ EXPECT_TRUE(buf1->isSharedOne());
+
+ {
+ auto buf2 = buf1->clone();
+ EXPECT_TRUE(buf2->isManagedOne());
+ EXPECT_TRUE(buf2->isSharedOne());
+ EXPECT_EQ(buf1->data(), buf2->data());
+ EXPECT_EQ(it.refcount, 1);
+ }
+ EXPECT_EQ(it.refcount, 1);
+ }
+ EXPECT_EQ(it.refcount, 0);
+}
+
+TEST(IOBuf, Managed) {
+ auto hello = "hello";
+ auto buf1UP = wrap(hello);
+ auto buf1 = buf1UP.get();
+ EXPECT_FALSE(buf1->isManagedOne());
+ auto buf2UP = copy("world");
+ auto buf2 = buf2UP.get();
+ EXPECT_TRUE(buf2->isManagedOne());
+ auto buf3UP = wrap(hello);
+ auto buf3 = buf3UP.get();
+ auto buf4UP = buf2->clone();
+ auto buf4 = buf4UP.get();
+
+ // buf1 and buf3 share the same memory (but are unmanaged)
+ EXPECT_FALSE(buf1->isManagedOne());
+ EXPECT_FALSE(buf3->isManagedOne());
+ EXPECT_TRUE(buf1->isSharedOne());
+ EXPECT_TRUE(buf3->isSharedOne());
+ EXPECT_EQ(buf1->data(), buf3->data());
+
+ // buf2 and buf4 share the same memory (but are managed)
+ EXPECT_TRUE(buf2->isManagedOne());
+ EXPECT_TRUE(buf4->isManagedOne());
+ EXPECT_TRUE(buf2->isSharedOne());
+ EXPECT_TRUE(buf4->isSharedOne());
+ EXPECT_EQ(buf2->data(), buf4->data());
+
+ buf1->prependChain(std::move(buf2UP));
+ buf1->prependChain(std::move(buf3UP));
+ buf1->prependChain(std::move(buf4UP));
+
+ EXPECT_EQ("helloworldhelloworld", toString(*buf1));
+ EXPECT_FALSE(buf1->isManaged());
+
+ buf1->makeManaged();
+ EXPECT_TRUE(buf1->isManaged());
+
+ // buf1 and buf3 are now unshared (because they were unmanaged)
+ EXPECT_TRUE(buf1->isManagedOne());
+ EXPECT_TRUE(buf3->isManagedOne());
+ EXPECT_FALSE(buf1->isSharedOne());
+ EXPECT_FALSE(buf3->isSharedOne());
+ EXPECT_NE(buf1->data(), buf3->data());
+
+ // buf2 and buf4 are still shared
+ EXPECT_TRUE(buf2->isManagedOne());
+ EXPECT_TRUE(buf4->isManagedOne());
+ EXPECT_TRUE(buf2->isSharedOne());
+ EXPECT_TRUE(buf4->isSharedOne());
+ EXPECT_EQ(buf2->data(), buf4->data());
+
+ // And verify that the truth is what we expect: modify a byte in buf1 and
+ // buf2, see that the change from buf1 is *not* reflected in buf3, but the
+ // change from buf2 is reflected in buf4.
+ writableStr(*buf1)[0] = 'j';
+ writableStr(*buf2)[0] = 'x';
+ EXPECT_EQ("jelloxorldhelloxorld", toString(*buf1));
+}
+
+TEST(IOBuf, CoalesceEmptyBuffers) {
+ auto b1 = IOBuf::takeOwnership(nullptr, 0);
+ auto b2 = fromStr("hello");
+ auto b3 = IOBuf::takeOwnership(nullptr, 0);
+
+ b2->appendChain(std::move(b3));
+ b1->appendChain(std::move(b2));
+
+ auto br = b1->coalesce();
+
+ EXPECT_TRUE(ByteRange(StringPiece("hello")) == br);
+}
+
+TEST(IOBuf, CloneCoalescedChain) {
+ auto b = IOBuf::createChain(1000, 100);
+ b->advance(10);
+ const uint32_t fillSeed = 0x12345678;
+ boost::mt19937 gen(fillSeed);
+ {
+ auto c = b.get();
+ uint64_t length = c->tailroom();
+ do {
+ length = std::min(length, c->tailroom());
+ c->append(length--);
+ fillBuf(c, gen);
+ c = c->next();
+ } while (c != b.get());
+ }
+ auto c = b->cloneCoalescedAsValue();
+ EXPECT_FALSE(c.isChained()); // Not chained
+ EXPECT_FALSE(c.isSharedOne()); // Not shared
+ EXPECT_EQ(b->headroom(), c.headroom()); // Preserves headroom
+ EXPECT_LE(b->prev()->tailroom(), c.tailroom()); // Preserves minimum tailroom
+ EXPECT_EQ(b->computeChainDataLength(), c.length()); // Same length
+ gen.seed(fillSeed);
+ checkBuf(&c, gen); // Same contents
+}
+
+TEST(IOBuf, CloneCoalescedSingle) {
+ auto b = IOBuf::create(1000);
+ b->advance(10);
+ b->append(900);
+ const uint32_t fillSeed = 0x12345678;
+ boost::mt19937 gen(fillSeed);
+ fillBuf(b.get(), gen);
+
+ auto c = b->cloneCoalesced();
+ EXPECT_FALSE(c->isChained()); // Not chained
+ EXPECT_TRUE(c->isSharedOne()); // Shared
+ EXPECT_EQ(b->buffer(), c->buffer());
+ EXPECT_EQ(b->capacity(), c->capacity());
+ EXPECT_EQ(b->data(), c->data());
+ EXPECT_EQ(b->length(), c->length());
}