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Utils: Add SynchronizedValue<T>

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Change-Id: I0af6998f540ba688fa54d9e43e33cb3cb0fc54e8
Reviewed-by: hjk <hjk@qt.io>
This commit is contained in:
Marcus Tillmanns
2023-11-08 15:30:40 +01:00
parent 3939ba93af
commit 35a2d598ab
6 changed files with 602 additions and 0 deletions
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370
src/libs/utils/synchronizedvalue.h Normal file
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@@ -0,0 +1,370 @@
// Copyright (C) 2023 The Qt Company Ltd.
// SPDX-License-Identifier: LicenseRef-Qt-Commercial OR GPL-3.0-only WITH Qt-GPL-exception-1.0
#pragma once
#include <functional>
#include <mutex>
#include <shared_mutex>
namespace Utils {
/*!
\brief A wrapper that provides thread-safe access to the wrapped type using a read/write mutex.
Examples:
\code
void writeAndGet() {
SynchronizedValue<QString> synchronizedString;
// To update the value of the synchronized object, you can use the write function.
synchronizedString.write([](QString &str) { str = "Hello World"; });
// If you just need a value from the synchronized object, you can use the get function
qDebug() << "New value is:" << synchronizedString.get<QString>([](const QString &str) { return str; });
}
void read() {
SynchronizedValue<QPair<QString, QString>> synchronized;
QString both;
// If you want to access multiple members of the synchronized object, you can use the read function
synchronized.read([&both](const QPair<QString, QString> &pair) {
qDebug() << "First value is:" << pair.first();
qDebug() << "Second value is:" << pair.second();
both = pair.first() + pair.second();
// ...
});
}
// You can use the SynchronizedValue<T>::update() to return whether the value was changed:
void setString(const QString &newString) {
const bool wasChanged = m_synchronizedString.update([&newString](QString &str) {
if (newString == str)
return false;
str = newString;
return true;
}));
if (wasChanged)
emit stringChanged(newString);
}
// You can also use a lock type to get access
void withLocks() {
SynchronizedValue<QString> synchronizedData;
*synchronizedData.writeLocked() = "Hello World";
qDebug() << *synchronizedData.readLocked() << "== Hello World";
auto lk = synchronizedData.writeLocked();
assert(lk.ownsLock());
*lk = "I am locked";
}
\endcode
*/
template<typename T>
class SynchronizedValue
{
template<typename... SV>
friend std::tuple<typename SV::unique_lock...> synchronize(SV &...sv);
public:
SynchronizedValue() = default;
SynchronizedValue(const SynchronizedValue<T> &other)
{
std::shared_lock lk(other.mutex);
value = other.value;
}
SynchronizedValue(const T &other)
: value(other)
{}
class shared_lock
{
public:
shared_lock(T const &value_, std::shared_mutex &mutex)
: lock(mutex)
, value(value_)
{}
shared_lock(T const &value_, std::shared_mutex &mutex, std::try_to_lock_t)
: lock(mutex, std::try_to_lock)
, value(value_)
{}
shared_lock(T const &value_, std::shared_mutex &mutex, std::defer_lock_t)
: lock(mutex, std::defer_lock)
, value(value_)
{}
shared_lock(T const &value_, std::shared_mutex &mutex, std::adopt_lock_t)
: lock(mutex, std::adopt_lock)
, value(value_)
{}
bool ownsLock() const { return lock.owns_lock(); }
const T *operator->() const
{
Q_ASSERT(ownsLock());
return &value;
}
const T &operator*() const
{
Q_ASSERT(ownsLock());
return value;
}
private:
std::shared_lock<std::shared_mutex> lock;
T const &value;
};
class unique_lock
{
public:
unique_lock(T &value_, std::shared_mutex &mutex)
: lock(mutex)
, value(value_)
{}
unique_lock(T &value_, std::shared_mutex &mutex, std::try_to_lock_t)
: lock(mutex, std::try_to_lock)
, value(value_)
{}
unique_lock(T &value_, std::shared_mutex &mutex, std::defer_lock_t)
: lock(mutex, std::defer_lock)
, value(value_)
{}
unique_lock(T &value_, std::shared_mutex &mutex, std::adopt_lock_t)
: lock(mutex, std::adopt_lock)
, value(value_)
{}
bool ownsLock() const { return lock.owns_lock(); }
T *operator->() const
{
Q_ASSERT(ownsLock());
return &value;
}
T &operator*() const
{
Q_ASSERT(ownsLock());
return value;
}
private:
std::unique_lock<std::shared_mutex> lock;
T &value;
};
[[nodiscard]] shared_lock readLocked() const { return shared_lock(value, mutex); }
[[nodiscard]] shared_lock readLocked(std::try_to_lock_t) const
{
return shared_lock(value, mutex, std::try_to_lock);
}
[[nodiscard]] unique_lock writeLocked() { return unique_lock(value, mutex); }
[[nodiscard]] unique_lock writeLocked(std::try_to_lock_t)
{
return unique_lock(value, mutex, std::try_to_lock);
}
//! Call func with a const reference to the wrapped object
void read(const std::function<void(const T &)> &func) const
{
std::shared_lock lk(mutex);
func(value);
}
//! Call func with a const reference to the wrapped object and returns the result of func
template<typename R>
[[nodiscard]] R get(const std::function<R(const T &)> &func) const
{
std::shared_lock lk(mutex);
return func(value);
}
[[nodiscard]] T get() const
{
std::shared_lock lk(mutex);
return value;
}
//! Call func with a mutable reference to the wrapped object
void write(const std::function<void(T &)> &func)
{
std::unique_lock lk(mutex);
func(value);
}
//! Call func with a mutable reference to the wrapped object and returns the result of func
template<typename R>
[[nodiscard]] R update(const std::function<R(T &)> &func)
{
std::unique_lock lk(mutex);
return func(value);
}
SynchronizedValue<T> &operator=(const SynchronizedValue<T> &other)
{
std::unique_lock lk(mutex, std::defer_lock);
std::shared_lock lkOther(other.mutex, std::defer_lock);
std::lock(lk, lkOther);
value = other.value;
return *this;
}
SynchronizedValue<T> &operator=(const T &other)
{
std::unique_lock lk(mutex);
value = other;
return *this;
}
bool operator!=(const SynchronizedValue<T> &rhs) const
{
std::shared_lock lk(mutex, std ::defer_lock);
std::shared_lock lkOther(rhs.mutex, std ::defer_lock);
std::lock(lk, lkOther);
return value != rhs.value;
}
bool operator==(const SynchronizedValue<T> &rhs) const
{
std::shared_lock lk(mutex, std ::defer_lock);
std::shared_lock lkOther(rhs.mutex, std ::defer_lock);
std::lock(lk, lkOther);
return value == rhs.value;
}
bool operator<(const SynchronizedValue<T> &rhs) const
{
std::shared_lock lk(mutex, std ::defer_lock);
std::shared_lock lkOther(rhs.mutex, std ::defer_lock);
std::lock(lk, lkOther);
return value < rhs.value;
}
bool operator<=(const SynchronizedValue<T> &rhs) const
{
std::shared_lock lk(mutex, std ::defer_lock);
std::shared_lock lkOther(rhs.mutex, std ::defer_lock);
std::lock(lk, lkOther);
return value <= rhs.value;
}
bool operator>(const SynchronizedValue<T> &rhs) const
{
std::shared_lock lk(mutex, std ::defer_lock);
std::shared_lock lkOther(rhs.mutex, std ::defer_lock);
std::lock(lk, lkOther);
return value > rhs.value;
}
bool operator>=(const SynchronizedValue<T> &rhs) const
{
std::shared_lock lk(mutex, std ::defer_lock);
std::shared_lock lkOther(rhs.mutex, std ::defer_lock);
std::lock(lk, lkOther);
return value >= rhs.value;
}
bool operator>(const T &rhs) const
{
std::shared_lock lk(mutex);
return value > rhs;
}
bool operator>=(const T &rhs) const
{
std::shared_lock lk(mutex);
return value >= rhs;
}
bool operator!=(const T &rhs) const
{
std::shared_lock lk(mutex);
return value != rhs;
}
bool operator==(const T &rhs) const
{
std::shared_lock lk(mutex);
return value == rhs;
}
bool operator<(const T &rhs) const
{
std::shared_lock lk(mutex);
return value < rhs;
}
bool operator<=(const T &rhs) const
{
std::shared_lock lk(mutex);
return value <= rhs;
}
private:
template<typename L>
friend bool operator!=(const L &lhs, const SynchronizedValue<T> &rhs)
{
return rhs != lhs;
}
template<typename L>
friend bool operator==(const L &lhs, const SynchronizedValue<T> &rhs)
{
return rhs == lhs;
}
template<typename L>
friend bool operator<(const L &lhs, const SynchronizedValue<T> &rhs)
{
return rhs > lhs;
}
template<typename L>
friend bool operator<=(const L &lhs, const SynchronizedValue<T> &rhs)
{
return rhs >= lhs;
}
template<typename L>
friend bool operator>(const L &lhs, const SynchronizedValue<T> &rhs)
{
return rhs < lhs;
}
template<typename L>
friend bool operator>=(const L &lhs, const SynchronizedValue<T> &rhs)
{
return rhs <= lhs;
}
private:
mutable std::shared_mutex mutex;
T value;
};
//! Lock a number of SynchronizedValue's using a dead-lock free algorithm. ( see std::lock() )
template<typename... SV>
std::tuple<typename SV::unique_lock...> synchronize(SV &...sv)
{
std::lock(sv.mutex...);
typedef std::tuple<typename SV::unique_lock...> t_type;
return t_type(typename SV::unique_lock(sv.value, sv.mutex, std::adopt_lock)...);
}
} // namespace Utils

1
tests/auto/utils/CMakeLists.txt
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@@ -8,6 +8,7 @@ add_subdirectory(fileutils)
add_subdirectory(fsengine)
add_subdirectory(fuzzymatcher)
add_subdirectory(indexedcontainerproxyconstiterator)
add_subdirectory(synchronizedvalue)
add_subdirectory(mathutils)
add_subdirectory(multicursor)
add_subdirectory(persistentsettings)

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tests/auto/utils/synchronizedvalue/CMakeLists.txt Normal file
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add_qtc_test(tst_utils_synchronizedvalue
DEPENDS Utils
SOURCES tst_synchronizedvalue.cpp
)

7
tests/auto/utils/synchronizedvalue/synchronizedvalue.qbs Normal file
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@@ -0,0 +1,7 @@
import qbs
QtcAutotest {
name: "synchronizedvalue autotest"
Depends { name: "Utils" }
files: "tst_synchronizedvalue.cpp"
}

219
tests/auto/utils/synchronizedvalue/tst_synchronizedvalue.cpp Normal file
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@@ -0,0 +1,219 @@
// Copyright (C) 2023 The Qt Company Ltd.
// SPDX-License-Identifier: LicenseRef-Qt-Commercial OR GPL-3.0-only WITH Qt-GPL-exception-1.0
#include <QtTest>
#include <QString>
#include <utils/synchronizedvalue.h>
namespace Utils {
struct TestData
{
TestData() = default;
TestData(int iValue)
: i(iValue)
{}
bool operator==(const TestData &other) const { return i == other.i && str == other.str; }
bool operator!=(const TestData &other) const { return !(*this == other); }
QString str;
int i{20};
};
class tst_synchronizedvalue : public QObject
{
Q_OBJECT
private slots:
void initTestCase() {}
void read()
{
SynchronizedValue<TestData> data;
data.read([](const auto &d) {
QCOMPARE(d.str, QString());
QCOMPARE(d.i, 20);
});
}
void ctor()
{
SynchronizedValue<TestData> data(200);
QCOMPARE(data.get<int>([](const auto &d) { return d.i; }), 200);
}
void initializerCtor()
{
SynchronizedValue<QList<int>> data({1, 2, 3});
QCOMPARE(data.get<QList<int>>([](const auto &d) { return d; }), QList<int>({1, 2, 3}));
}
void get()
{
SynchronizedValue<TestData> data(200);
QCOMPARE(data.get<int>([](const auto &d) { return d.i; }), 200);
}
void constLock()
{
SynchronizedValue<TestData> data(200);
QCOMPARE(data.readLocked()->i, 200);
QCOMPARE(data.get().i, 200);
auto lk = data.readLocked();
QCOMPARE(lk->i, 200);
// This should fail to compile:
// data.readLocked()->i = 200;
}
void lock()
{
SynchronizedValue<TestData> data(123);
data.writeLocked()->i = 200;
QCOMPARE(data.get<int>([](const auto &d) { return d.i; }), 200);
{
auto wlk = data.writeLocked();
wlk->str = "Write locked";
}
QCOMPARE(data.readLocked()->str, "Write locked");
SynchronizedValue<QString> lockedStr("Hello World");
QCOMPARE(*lockedStr.readLocked(), "Hello World");
*lockedStr.writeLocked() = "Hello World 2";
QCOMPARE(*lockedStr.readLocked(), "Hello World 2");
}
void trivialGet()
{
SynchronizedValue<TestData> data(200);
TestData d = data.get();
QCOMPARE(data, d);
QCOMPARE(d.i, 200);
}
void equalop()
{
SynchronizedValue<TestData> data(200);
SynchronizedValue<TestData> data2(300);
data = data2;
QCOMPARE(data.get<int>([](const auto &d) { return d.i; }), 300);
QCOMPARE(data2.get<int>([](const auto &d) { return d.i; }), 300);
TestData dataNoLock(1337);
data = dataNoLock;
QCOMPARE(data.get<int>([](const auto &d) { return d.i; }), 1337);
}
void compareEq()
{
SynchronizedValue<TestData> data(200);
SynchronizedValue<TestData> data2(300);
QVERIFY(data != data2);
QVERIFY(!(data == data2));
data2.write([](auto &d) { d.i = 200; });
QVERIFY(data == data2);
QVERIFY(!(data != data2));
}
void operators()
{
SynchronizedValue<int> data(200);
SynchronizedValue<int> data2(300);
QVERIFY(data < data2);
QVERIFY(data <= data2);
QVERIFY(data2 > data);
QVERIFY(data2 >= data);
QVERIFY(data2 != data);
QVERIFY(!(data2 == data));
QVERIFY(data > 100);
QVERIFY(data >= 100);
QVERIFY(data >= 200);
QVERIFY(data < 300);
QVERIFY(data <= 300);
QVERIFY(100 < data);
QVERIFY(200 <= data);
QVERIFY(199 <= data);
QVERIFY(300 > data);
QVERIFY(200 >= data);
QVERIFY(201 >= data);
QVERIFY(200 == data);
QVERIFY(200 != data2);
}
void copyCtor()
{
SynchronizedValue<TestData> data(123);
SynchronizedValue<TestData> data2(data);
QCOMPARE(data.get<int>([](const auto &d) { return d.i; }), 123);
QCOMPARE(data2.get<int>([](const auto &d) { return d.i; }), 123);
TestData dataNoLock(1337);
SynchronizedValue<TestData> data3(dataNoLock);
QCOMPARE(data3.get<int>([](const auto &d) { return d.i; }), 1337);
}
void multilock()
{
SynchronizedValue<int> value(100);
// Multiple reader, no writer
{
QCOMPARE(value.get(), 100);
auto firstLock = value.readLocked();
QVERIFY(firstLock.ownsLock());
auto secondLock = value.readLocked();
QVERIFY(secondLock.ownsLock());
QCOMPARE(*firstLock, 100);
QCOMPARE(*secondLock, 100);
auto thirdLock = value.writeLocked(std::try_to_lock);
QVERIFY(!thirdLock.ownsLock());
}
// Single writer, no readers
{
auto firstLock = value.writeLocked();
QVERIFY(firstLock.ownsLock());
auto secondLock = value.writeLocked(std::try_to_lock);
QVERIFY(!secondLock.ownsLock());
auto readLock = value.readLocked(std::try_to_lock);
QVERIFY(!readLock.ownsLock());
}
}
void synchronizeMultiple()
{
SynchronizedValue<int> sv1;
SynchronizedValue<QString> sv2;
auto [lk1, lk2] = synchronize(sv1, sv2);
QVERIFY(lk1.ownsLock());
QVERIFY(lk2.ownsLock());
}
};
} // namespace Utils
QTEST_GUILESS_MAIN(Utils::tst_synchronizedvalue)
#include "tst_synchronizedvalue.moc"

1
tests/auto/utils/utils.qbs
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@@ -13,6 +13,7 @@ Project {
"fsengine/fsengine.qbs",
"fuzzymatcher/fuzzymatcher.qbs",
"indexedcontainerproxyconstiterator/indexedcontainerproxyconstiterator.qbs",
"synchronizedvalue/synchronizedvalue.qbs",
"mathutils/mathutils.qbs",
"multicursor/multicursor.qbs",
"persistentsettings/persistentsettings.qbs",