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transaction.cpp
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transaction.cpp
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// SPDX-License-Identifier: BSD-3-Clause
/* Copyright 2016-2021, Intel Corporation */
/*
* transaction.cpp -- C++ documentation snippets.
*/
/*
* The following might be necessary to compile the examples on older compilers.
*/
#if !defined(__cpp_lib_uncaught_exceptions) && !defined(_MSC_VER) || \
(_MSC_VER < 1900)
#define __cpp_lib_uncaught_exceptions 201411
namespace std
{
int
uncaught_exceptions() noexcept
{
return 0;
}
} /* namespace std */
#endif /* __cpp_lib_uncaught_exceptions */
//! [general_tx_example]
#include <libpmemobj++/make_persistent.hpp>
#include <libpmemobj++/mutex.hpp>
#include <libpmemobj++/persistent_ptr.hpp>
#include <libpmemobj++/pext.hpp>
#include <libpmemobj++/pool.hpp>
#include <libpmemobj++/shared_mutex.hpp>
#include <libpmemobj++/transaction.hpp>
using namespace pmem::obj;
void
general_tx_example()
{
/* pool root structure */
struct root {
mutex pmutex;
shared_mutex shared_pmutex;
p<int> count;
persistent_ptr<root> another_root;
};
/* create a pmemobj pool */
auto pop = pool<root>::create("poolfile", "layout", PMEMOBJ_MIN_POOL);
auto proot = pop.root();
/* typical usage schemes */
try {
/* take locks and start a transaction */
transaction::run(
pop,
[&]() {
/* atomically allocate objects */
proot->another_root = make_persistent<root>();
/* atomically modify objects */
proot->count++;
},
proot->pmutex, proot->shared_pmutex);
} catch (pmem::transaction_error &) {
/* a transaction error occurred, transaction got aborted
* reacquire locks if necessary */
} catch (...) {
/* some other exception got propagated from within the tx
* reacquire locks if necessary */
}
}
//! [general_tx_example]
//! [manual_tx_example]
#include <libpmemobj++/make_persistent.hpp>
#include <libpmemobj++/mutex.hpp>
#include <libpmemobj++/persistent_ptr.hpp>
#include <libpmemobj++/pext.hpp>
#include <libpmemobj++/pool.hpp>
#include <libpmemobj++/shared_mutex.hpp>
#include <libpmemobj++/transaction.hpp>
using namespace pmem::obj;
int
manual_tx_example()
{
/* pool root structure */
struct root {
mutex pmutex;
shared_mutex shared_pmutex;
p<int> count;
persistent_ptr<root> another_root;
};
/* create a pmemobj pool */
auto pop = pool<root>::create("poolfile", "layout", PMEMOBJ_MIN_POOL);
auto proot = pop.root();
try {
transaction::manual tx(pop, proot->pmutex,
proot->shared_pmutex);
/* atomically allocate objects */
proot->another_root = make_persistent<root>();
/* atomically modify objects */
proot->count++;
/* It's necessary to commit the transaction manually and
* it has to be the last operation in the transaction. */
transaction::commit();
} catch (pmem::transaction_error &) {
/* an internal transaction error occurred, tx aborted
* reacquire locks if necessary */
} catch (...) {
/* some other exception thrown, tx aborted
* reacquire locks if necessary */
}
/* In complex cases with library calls, remember to check the status of
* the previous transaction. */
return transaction::error();
}
//! [manual_tx_example]
//! [automatic_tx_example]
#include <libpmemobj++/make_persistent.hpp>
#include <libpmemobj++/mutex.hpp>
#include <libpmemobj++/persistent_ptr.hpp>
#include <libpmemobj++/pext.hpp>
#include <libpmemobj++/pool.hpp>
#include <libpmemobj++/shared_mutex.hpp>
#include <libpmemobj++/transaction.hpp>
using namespace pmem::obj;
int
automatic_tx_example()
{
/* pool root structure */
struct root {
mutex pmutex;
shared_mutex shared_pmutex;
p<int> count;
persistent_ptr<root> another_root;
};
/* create a pmemobj pool */
auto pop = pool<root>::create("poolfile", "layout", PMEMOBJ_MIN_POOL);
auto proot = pop.root();
try {
transaction::automatic tx(pop, proot->pmutex,
proot->shared_pmutex);
/* atomically allocate objects */
proot->another_root = make_persistent<root>();
/* atomically modify objects */
proot->count++;
/* manual transaction commit is no longer necessary */
} catch (pmem::transaction_error &) {
/* an internal transaction error occurred, tx aborted
* reacquire locks if necessary */
} catch (...) {
/* some other exception thrown, tx aborted
* reacquire locks if necessary */
}
/* In complex cases with library calls, remember to check the status of
* the previous transaction. */
return transaction::error();
}
//! [automatic_tx_example]
//! [tx_callback_example]
#include <libpmemobj++/make_persistent.hpp>
#include <libpmemobj++/persistent_ptr.hpp>
#include <libpmemobj++/pext.hpp>
#include <libpmemobj++/pool.hpp>
#include <libpmemobj++/transaction.hpp>
using namespace pmem::obj;
void
tx_callback_example()
{
/* pool root structure */
struct root {
p<int> count;
};
/* create a pmemobj pool */
auto pop = pool<root>::create("poolfile", "layout", PMEMOBJ_MIN_POOL);
bool cb_called = false;
auto internal_tx_function = [&] {
/* callbacks can be registered even in inner transaction but
* will be called when outer transaction ends */
transaction::run(pop, [&] {
transaction::register_callback(
transaction::stage::oncommit,
[&] { cb_called = true; });
});
/* cb_called is false here if internal_tx_function is called
* inside another transaction */
};
try {
transaction::run(pop, [&] { internal_tx_function(); });
/* cb_called == true if transaction ended successfully */
} catch (pmem::transaction_error &) {
/* an internal transaction error occurred, tx aborted
* reacquire locks if necessary */
} catch (...) {
/* some other exception thrown, tx aborted
* reacquire locks if necessary */
}
}
//! [tx_callback_example]
//! [tx_flat_example]
#include <libpmemobj++/make_persistent.hpp>
#include <libpmemobj++/persistent_ptr.hpp>
#include <libpmemobj++/pext.hpp>
#include <libpmemobj++/pool.hpp>
#include <libpmemobj++/transaction.hpp>
using namespace pmem::obj;
void
tx_flat_example()
{
/* pool root structure */
struct root {
p<int> count;
};
/* create a pmemobj pool */
auto pop = pool<root>::create("poolfile", "layout", PMEMOBJ_MIN_POOL);
auto proot = pop.root();
try {
flat_transaction::run(pop, [&] {
proot->count++;
try {
flat_transaction::run(pop, [&] {
proot->count++;
throw std::runtime_error("some error");
});
} catch (...) {
/* Transaction is not aborted yet (unlike for
* basic_transaction). */
assert(pmemobj_tx_stage() == TX_STAGE_WORK);
assert(proot->count == 2);
throw;
}
});
} catch (pmem::transaction_error &) {
/* An internal transaction error occurred, outer tx aborted just
* now. Reacquire locks if necessary. */
assert(proot->count == 0);
} catch (...) {
/* Some other exception thrown, outer tx aborted just now.
* Reacquire locks if necessary. */
assert(proot->count == 0);
}
}
//! [tx_flat_example]
//! [tx_nested_struct_example]
#include <libpmemobj++/make_persistent.hpp>
#include <libpmemobj++/persistent_ptr.hpp>
#include <libpmemobj++/pext.hpp>
#include <libpmemobj++/pool.hpp>
#include <libpmemobj++/transaction.hpp>
using namespace pmem::obj;
template <typename T>
struct simple_ptr {
simple_ptr()
{
assert(pmemobj_tx_stage() == TX_STAGE_WORK);
ptr = make_persistent<T>();
}
~simple_ptr()
{
assert(pmemobj_tx_stage() == TX_STAGE_WORK);
try {
delete_persistent<T>(ptr);
} catch (pmem::transaction_free_error &e) {
std::cerr << e.what() << std::endl;
std::terminate();
} catch (pmem::transaction_scope_error &e) {
std::cerr << e.what() << std::endl;
std::terminate();
}
}
persistent_ptr<T> ptr;
};
/**
* This struct holds two simple_ptr. It presents problems when using
* basic_transaction in case of transactional function abort. */
struct A {
A() : ptr1(), ptr2()
{
}
simple_ptr<int> ptr1;
simple_ptr<char[(1ULL << 30)]> ptr2;
};
/**
* This struct holds two simple_ptr. It presents problems when throwing
* exception from within basic_transaction. */
struct B {
B() : ptr1(), ptr2()
{
auto pop = pool_base(pmemobj_pool_by_ptr(this));
// It would result in a crash!
// basic_transaction::run(pop, [&]{ throw
// std::runtime_error("Error"); });
flat_transaction::run(
pop, [&] { throw std::runtime_error("Error"); });
}
simple_ptr<int> ptr1;
simple_ptr<int> ptr2;
};
void
tx_nested_struct_example()
{
/* pool root structure */
struct root {
persistent_ptr<A> ptrA;
persistent_ptr<B> ptrB;
};
/* create a pmemobj pool */
auto pop = pool<root>::create("poolfile", "layout", PMEMOBJ_MIN_POOL);
auto proot = pop.root();
auto create_a = [&] { proot->ptrA = make_persistent<A>(); };
auto create_b = [&] { proot->ptrB = make_persistent<B>(); };
try {
// It would result in a crash!
// basic_transaction::run(pop, create_a);
flat_transaction::run(pop, create_a);
/* To see why flat_transaction is necessary let's
* consider what happens when calling A ctor. The call stack
* will look like this:
*
* | ptr2 ctor |
* |-----------|
* | ptr1 ctor |
* |-----------|
* | A ctor |
*
* Since ptr2 is a pointer to some huge array of elements,
* calling ptr2 ctor will most likely result in make_persistent
* throwing an exception (due to out of memory). This exception
* will, in turn, cause stack unwinding - already constructed
* elements must be destroyed (in this example ptr1 destructor
* will be called).
*
* If we'd use basic_transaction the allocation failure, apart
* from throwing an exception, would also cause the transaction
* to abort (by default, in basic_transaction, all transactional
* functions failures cause tx abort). This is problematic since
* the ptr1 destructor, which is called during stack unwinding,
* expects the transaction to be in WORK stage (and the actual
* stage is ABORTED). As a result the application will fail on
* assert (and probably crash in NDEBUG mode).
*
* Now, consider what will happen if we'd use flat_transaction
* instead. In this case, make_persistent failure will not abort
* the transaction, it will only result in an exception. This
* means that the transaction is still in WORK stage during
* stack unwinding. Only after it completes, the transaction is
* aborted (it's happening at the outermost level, when exiting
* create_a lambda).
*/
} catch (std::runtime_error &) {
}
try {
basic_transaction::run(pop, create_b);
flat_transaction::run(pop, create_b);
/* Running create_b can be done both within basic and flat
* transaction. However, note that the transaction used in the B
* constructor MUST be a flat_transaction. This is because
* flat_transaction does not abort immediately when catching an
* exception. Instead it passes it to the outermost transaction
* - the abort is performed at that outermost level. In case of
* a basic_transaction the abort would be done within the B ctor
* and it would result in the same problems as with the previous
* example.
*/
} catch (std::runtime_error &) {
}
}
//! [tx_nested_struct_example]
//! [manual_flat_tx_example]
#include <libpmemobj++/make_persistent.hpp>
#include <libpmemobj++/mutex.hpp>
#include <libpmemobj++/persistent_ptr.hpp>
#include <libpmemobj++/pext.hpp>
#include <libpmemobj++/pool.hpp>
#include <libpmemobj++/shared_mutex.hpp>
#include <libpmemobj++/transaction.hpp>
using namespace pmem::obj;
int
manual_flat_tx_example()
{
/* pool root structure */
struct root {
mutex pmutex;
shared_mutex shared_pmutex;
p<int> count;
persistent_ptr<root> another_root;
};
/* create a pmemobj pool */
auto pop = pool<root>::create("poolfile", "layout", PMEMOBJ_MIN_POOL);
auto proot = pop.root();
try {
flat_transaction::manual tx(pop, proot->pmutex);
/* atomically allocate objects */
proot->another_root = make_persistent<root>();
{
flat_transaction::manual inner_tx(pop,
proot->shared_pmutex);
/* atomically modify objects */
proot->count++;
/* OPTIONAL */
// transaction::commit();
/* Even if there is no explicit commit inner_tx will
* not abort. This is true even if
* flat_transaction::manual is destroyed because of an
* active exception. For basic_transaction::manual you
* have to call commit() at each level (as many times as
* there are manual transaction objects). In case of
* a flat_transaction, the commit has to be called only
* once, at the outermost level.
*/
}
/* It's necessary to commit the transaction manually and
* it has to be the last operation in the transaction. */
transaction::commit();
} catch (pmem::transaction_error &) {
/* An internal transaction error occurred, outer tx aborted just
* now. Reacquire locks if necessary, */
} catch (...) {
/* Some other exception thrown, outer tx aborted just now.
* Reacquire locks if necessary. */
}
/* In complex cases with library calls, remember to check the status of
* the last transaction. */
return transaction::error();
}
//! [manual_flat_tx_example]
int
main()
{
try {
general_tx_example();
manual_tx_example();
automatic_tx_example();
tx_callback_example();
tx_flat_example();
tx_nested_struct_example();
manual_flat_tx_example();
} catch (const std::exception &e) {
std::cerr << "Exception " << e.what() << std::endl;
return -1;
}
return 0;
}