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Merge branch 'master' of https://git.mewin.de/mewin/mijin2

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This commit is contained in:
Patrick Wuttke 2025-07-14 10:08:04 +02:00
commit d8b03893b3
43 changed files with 3482 additions and 564 deletions
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50
source/mijin/async/boxed_signal.hpp Normal file
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@ -0,0 +1,50 @@
#pragma once
#if !defined(MIJIN_ASYNC_BOXED_SIGNAL_HPP_INCLUDED)
#define MIJIN_ASYNC_BOXED_SIGNAL_HPP_INCLUDED 1
#include "./signal.hpp"
#include "../container/boxed_object.hpp"
namespace mijin
{
//
// public defines
//
//
// public constants
//
//
// public types
//
template<template<typename> typename TAllocator, typename... TArgs>
class BaseBoxedSignal : private BoxedObject<BaseSignal<TAllocator, TArgs...>>
{
private:
using base_t = BoxedObject<BaseSignal<TAllocator, TArgs...>>;
public:
using base_t::construct;
using base_t::destroy;
using base_t::moveTo;
MIJIN_BOXED_PROXY_FUNC(connect)
MIJIN_BOXED_PROXY_FUNC(disconnect)
MIJIN_BOXED_PROXY_FUNC(emit)
};
template<typename... TArgs>
using BoxedSignal = BaseBoxedSignal<MIJIN_DEFAULT_ALLOCATOR, TArgs...>;
//
// public functions
//
} // namespace mijin
#endif // !defined(MIJIN_ASYNC_BOXED_SIGNAL_HPP_INCLUDED)

192
source/mijin/async/coroutine.cpp
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@ -26,205 +26,15 @@ namespace mijin
namespace impl
{
thread_local TaskLoop::StoredTask* gCurrentTask = nullptr;
thread_local std::shared_ptr<TaskSharedState> gCurrentTaskState;
}
//
// internal functions
//
void MultiThreadedTaskLoop::managerThread(std::stop_token stopToken) // NOLINT(performance-unnecessary-value-param)
{
setCurrentThreadName("Task Manager");
while (!stopToken.stop_requested())
{
// first clear out any parked tasks that are actually finished
auto itRem = std::remove_if(parkedTasks_.begin(), parkedTasks_.end(), [](StoredTask& task) {
return !task.task || task.task->status() == TaskStatus::FINISHED;
});
parkedTasks_.erase(itRem, parkedTasks_.end());
// then try to push any task from the buffer into the queue, if possible
for (auto it = parkedTasks_.begin(); it != parkedTasks_.end();)
{
if (!it->task->canResume())
{
++it;
continue;
}
if (readyTasks_.tryPushMaybeMove(*it)) {
it = parkedTasks_.erase(it);
}
else {
break;
}
}
// then clear the incoming task queue
while (true)
{
std::optional<StoredTask> task = queuedTasks_.tryPop();
if (!task.has_value()) {
break;
}
// try to directly move it into the next queue
if (readyTasks_.tryPushMaybeMove(*task)) {
continue;
}
// otherwise park it
parkedTasks_.push_back(std::move(*task));
}
// next collect tasks returning from the worker threads
while (true)
{
std::optional<StoredTask> task = returningTasks_.tryPop();
if (!task.has_value()) {
break;
}
if (task->task == nullptr || task->task->status() == TaskStatus::FINISHED) {
continue; // task has been transferred or finished
}
if (task->task->canResume() && readyTasks_.tryPushMaybeMove(*task)) {
continue; // instantly resume, no questions asked
}
// otherwise park it for future processing
parkedTasks_.push_back(std::move(*task));
}
std::this_thread::sleep_for(std::chrono::milliseconds(1));
}
}
void MultiThreadedTaskLoop::workerThread(std::stop_token stopToken, std::size_t workerId) // NOLINT(performance-unnecessary-value-param)
{
currentLoopStorage() = this; // forever (on this thread)
std::array<char, 16> threadName;
(void) std::snprintf(threadName.data(), 16, "Task Worker %lu", static_cast<unsigned long>(workerId));
setCurrentThreadName(threadName.data());
while (!stopToken.stop_requested())
{
// try to fetch a task to run
std::optional<StoredTask> task = readyTasks_.tryPop();
if (!task.has_value())
{
std::this_thread::sleep_for(std::chrono::milliseconds(1));
continue;
}
// run it
impl::gCurrentTask = &*task;
tickTask(*task);
impl::gCurrentTask = nullptr;
// and give it back
returningTasks_.push(std::move(*task));
}
}
//
// public functions
//
void SimpleTaskLoop::transferCurrentTask(TaskLoop& otherLoop) MIJIN_NOEXCEPT
{
assertCorrectThread();
if (&otherLoop == this) {
return;
}
MIJIN_ASSERT_FATAL(currentTask_ != tasks_.end(), "Trying to call transferCurrentTask() while not running a task!");
// now start the transfer, first disown the task
StoredTask storedTask = std::move(*currentTask_);
currentTask_->task = nullptr; // just to be sure
// then send it over to the other loop
otherLoop.addStoredTask(std::move(storedTask));
}
void SimpleTaskLoop::addStoredTask(StoredTask&& storedTask) MIJIN_NOEXCEPT
{
storedTask.task->setLoop(this);
if (threadId_ == std::thread::id() || threadId_ == std::this_thread::get_id())
{
// same thread, just copy it over
if (currentLoopStorage() != nullptr) {
// currently running, can't append to tasks_ directly
newTasks_.push_back(std::move(storedTask));
}
else {
tasks_.push_back(std::move(storedTask));
}
}
else
{
// other thread, better be safe
queuedTasks_.push(std::move(storedTask));
}
}
std::size_t SimpleTaskLoop::getActiveTasks() const MIJIN_NOEXCEPT
{
std::size_t sum = 0;
for (const StoredTask& task : mijin::chain(tasks_, newTasks_))
{
const TaskStatus status = task.task ? task.task->status() : TaskStatus::FINISHED;
if (status == TaskStatus::SUSPENDED || status == TaskStatus::RUNNING)
{
++sum;
}
}
return sum;
}
void MultiThreadedTaskLoop::transferCurrentTask(TaskLoop& otherLoop) MIJIN_NOEXCEPT
{
if (&otherLoop == this) {
return;
}
MIJIN_ASSERT_FATAL(impl::gCurrentTask != nullptr, "Trying to call transferCurrentTask() while not running a task!");
// now start the transfer, first disown the task
StoredTask storedTask = std::move(*impl::gCurrentTask);
impl::gCurrentTask->task = nullptr; // just to be sure
// then send it over to the other loop
otherLoop.addStoredTask(std::move(storedTask));
}
void MultiThreadedTaskLoop::addStoredTask(StoredTask&& storedTask) MIJIN_NOEXCEPT
{
storedTask.task->setLoop(this);
// just assume we are not on the manager thread, as that wouldn't make sense
queuedTasks_.push(std::move(storedTask));
}
void MultiThreadedTaskLoop::start(std::size_t numWorkerThreads)
{
managerThread_ = std::jthread([this](std::stop_token stopToken) { managerThread(std::move(stopToken)); });
workerThreads_.reserve(numWorkerThreads);
for (std::size_t workerId = 0; workerId < numWorkerThreads; ++workerId) {
workerThreads_.emplace_back([this, workerId](std::stop_token stopToken) { workerThread(std::move(stopToken), workerId); });
}
}
void MultiThreadedTaskLoop::stop()
{
workerThreads_.clear(); // will also set the stop token
managerThread_ = {}; // this too
}
} // namespace mijin

568
source/mijin/async/coroutine.hpp
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@ -10,6 +10,7 @@
#endif
#include <any>
#include <chrono>
#include <coroutine>
#include <exception>
#include <memory>
@ -20,8 +21,10 @@
#include "./message_queue.hpp"
#include "../container/optional.hpp"
#include "../internal/common.hpp"
#include "../memory/memutil.hpp"
#include "../util/flag.hpp"
#include "../util/iterators.hpp"
#include "../util/misc.hpp"
#include "../util/traits.hpp"
#if MIJIN_COROUTINE_ENABLE_DEBUG_INFO
#include "../debug/stacktrace.hpp"
@ -63,9 +66,10 @@ enum class TaskStatus
template<typename T>
struct TaskState;
template<template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
class TaskLoop;
template<typename TResult = void>
template<typename TResult = void, template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
class TaskBase;
#if MIJIN_COROUTINE_ENABLE_CANCEL
@ -103,6 +107,7 @@ public:
}
inline void cancel() const MIJIN_NOEXCEPT;
[[nodiscard]] inline Optional<std::source_location> getLocation() const MIJIN_NOEXCEPT;
#if MIJIN_COROUTINE_ENABLE_DEBUG_INFO
inline Optional<Stacktrace> getCreationStack() const MIJIN_NOEXCEPT;
#endif
@ -111,6 +116,7 @@ struct TaskSharedState
{
std::atomic_bool cancelled_ = false;
TaskHandle subTask;
std::source_location sourceLoc;
#if MIJIN_COROUTINE_ENABLE_DEBUG_INFO
Stacktrace creationStack_;
#endif
@ -245,16 +251,68 @@ struct TaskAwaitableSuspend
}
};
template<typename TTraits>
namespace impl
{
template<typename T>
using default_is_valid = T::default_is_valid_t;
}
template<template<typename> typename TAllocator>
struct TaskAllocatorTraits
{
static constexpr bool default_is_valid_v = detect_or_t<std::true_type, impl::default_is_valid, TAllocator<void>>::value;
template<typename T>
static TAllocator<T> create()
{
auto taskLoop = TaskLoop<TAllocator>::currentOpt();
if (taskLoop != nullptr)
{
return TAllocator<T>(taskLoop->getAllocator());
}
if constexpr (std::is_default_constructible_v<TAllocator<T>>)
{
return TAllocator<T>();
}
else
{
MIJIN_FATAL("Could not create task allocator.");
}
}
};
template<>
struct TaskAllocatorTraits<std::allocator>
{
static constexpr bool default_is_valid_v = true;
template<typename T>
static std::allocator<T> create() noexcept
{
return std::allocator<T>();
}
};
template<template<typename> typename TAllocator, typename T>
TAllocator<T> makeTaskAllocator()
{
return TaskAllocatorTraits<TAllocator>::template create<T>();
}
template<typename TTraits, template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
struct TaskPromise : impl::TaskReturn<typename TTraits::result_t, TaskPromise<TTraits>>
{
using handle_t = std::coroutine_handle<TaskPromise>;
using task_t = typename TTraits::task_t;
using result_t = typename TTraits::result_t;
[[no_unique_address]] TAllocator<std::max_align_t> allocator_;
TaskState<result_t> state_;
std::shared_ptr<TaskSharedState> sharedState_ = std::make_shared<TaskSharedState>();
TaskLoop* loop_ = nullptr;
std::shared_ptr<TaskSharedState> sharedState_;
TaskLoop<TAllocator>* loop_ = nullptr;
explicit TaskPromise(TAllocator<std::max_align_t> allocator = makeTaskAllocator<TAllocator, std::max_align_t>()) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<TAllocator<TaskSharedState>>)
: allocator_(std::move(allocator)), sharedState_(std::allocate_shared<TaskSharedState>(TAllocator<TaskSharedState>(allocator_))) {}
constexpr task_t get_return_object() MIJIN_NOEXCEPT { return task_t(handle_t::from_promise(*this)); }
constexpr TaskAwaitableSuspend initial_suspend() MIJIN_NOEXCEPT { return {}; }
@ -271,9 +329,10 @@ struct TaskPromise : impl::TaskReturn<typename TTraits::result_t, TaskPromise<TT
// constexpr void unhandled_exception() MIJIN_NOEXCEPT {}
template<typename TValue>
auto await_transform(FuturePtr<TValue> future) MIJIN_NOEXCEPT
auto await_transform(FuturePtr<TValue> future, std::source_location sourceLoc = std::source_location::current()) MIJIN_NOEXCEPT
{
MIJIN_ASSERT(loop_ != nullptr, "Cannot await future outside of a loop!");
sharedState_->sourceLoc = std::move(sourceLoc);
TaskAwaitableFuture<TValue> awaitable{future};
if (!awaitable.await_ready())
{
@ -287,17 +346,18 @@ struct TaskPromise : impl::TaskReturn<typename TTraits::result_t, TaskPromise<TT
}
template<typename TResultOther>
auto await_transform(TaskBase<TResultOther> task) MIJIN_NOEXCEPT
auto await_transform(TaskBase<TResultOther> task, std::source_location sourceLoc = std::source_location::current()) MIJIN_NOEXCEPT
{
MIJIN_ASSERT(loop_ != nullptr, "Cannot await another task outside of a loop!"); // NOLINT(clang-analyzer-core.UndefinedBinaryOperatorResult)
auto future = delayEvaluation<TResultOther>(loop_)->addTask(std::move(task), &sharedState_->subTask); // hackidyhack: delay evaluation of the type of loop_ as it is only forward-declared here
return await_transform(future);
auto future = delayEvaluation<TResultOther>(loop_)->addTaskImpl(std::move(task), &sharedState_->subTask); // hackidyhack: delay evaluation of the type of loop_ as it is only forward-declared here
return await_transform(future, std::move(sourceLoc));
}
template<typename TFirstArg, typename TSecondArg, typename... TArgs>
auto await_transform(Signal<TFirstArg, TSecondArg, TArgs...>& signal) MIJIN_NOEXCEPT
auto await_transform(Signal<TFirstArg, TSecondArg, TArgs...>& signal, std::source_location sourceLoc = std::source_location::current()) MIJIN_NOEXCEPT
{
auto data = std::make_shared<std::tuple<TFirstArg, TSecondArg, TArgs...>>();
sharedState_->sourceLoc = std::move(sourceLoc);
signal.connect([this, data](TFirstArg arg0, TSecondArg arg1, TArgs... args) mutable
{
*data = std::make_tuple(std::move(arg0), std::move(arg1), std::move(args)...);
@ -309,9 +369,10 @@ struct TaskPromise : impl::TaskReturn<typename TTraits::result_t, TaskPromise<TT
}
template<typename TFirstArg>
auto await_transform(Signal<TFirstArg>& signal) MIJIN_NOEXCEPT
auto await_transform(Signal<TFirstArg>& signal, std::source_location sourceLoc = std::source_location::current()) MIJIN_NOEXCEPT
{
auto data = std::make_shared<TFirstArg>();
sharedState_->sourceLoc = std::move(sourceLoc);
signal.connect([this, data](TFirstArg arg0) mutable
{
*data = std::move(arg0);
@ -322,8 +383,9 @@ struct TaskPromise : impl::TaskReturn<typename TTraits::result_t, TaskPromise<TT
return awaitable;
}
auto await_transform(Signal<>& signal) MIJIN_NOEXCEPT
auto await_transform(Signal<>& signal, std::source_location sourceLoc = std::source_location::current()) MIJIN_NOEXCEPT
{
sharedState_->sourceLoc = std::move(sourceLoc);
signal.connect([this]()
{
state_.status = TaskStatus::SUSPENDED;
@ -333,24 +395,39 @@ struct TaskPromise : impl::TaskReturn<typename TTraits::result_t, TaskPromise<TT
return awaitable;
}
std::suspend_always await_transform(std::suspend_always) MIJIN_NOEXCEPT
std::suspend_always await_transform(std::suspend_always, std::source_location sourceLoc = std::source_location::current()) MIJIN_NOEXCEPT
{
sharedState_->sourceLoc = std::move(sourceLoc);
state_.status = TaskStatus::SUSPENDED;
return std::suspend_always();
}
std::suspend_never await_transform(std::suspend_never) MIJIN_NOEXCEPT {
std::suspend_never await_transform(std::suspend_never, std::source_location sourceLoc = std::source_location::current()) MIJIN_NOEXCEPT {
sharedState_->sourceLoc = std::move(sourceLoc);
return std::suspend_never();
}
TaskAwaitableSuspend await_transform(TaskAwaitableSuspend) MIJIN_NOEXCEPT
TaskAwaitableSuspend await_transform(TaskAwaitableSuspend, std::source_location sourceLoc = std::source_location::current()) MIJIN_NOEXCEPT
{
sharedState_->sourceLoc = std::move(sourceLoc);
state_.status = TaskStatus::SUSPENDED;
return TaskAwaitableSuspend();
}
// make sure the allocators are also used for the promise itself
void* operator new(std::size_t size)
{
return makeTaskAllocator<TAllocator, std::max_align_t>().allocate((size - 1) / sizeof(std::max_align_t) + 1);
}
void operator delete(void* ptr, std::size_t size) noexcept
{
TaskPromise* self = static_cast<TaskPromise*>(ptr);
self->allocator_.deallocate(static_cast<std::max_align_t*>(ptr), (size - 1) / sizeof(std::max_align_t) + 1);
}
};
template<typename TResult>
template<typename TResult, template<typename> typename TAllocator>
class [[nodiscard("Tasks should either we awaited or added to a loop.")]] TaskBase
{
public:
@ -362,7 +439,7 @@ public:
using result_t = TResult;
};
public:
using promise_type = TaskPromise<Traits>;
using promise_type = TaskPromise<Traits, TAllocator>;
using handle_t = typename promise_type::handle_t;
private:
handle_t handle_;
@ -415,11 +492,11 @@ private:
[[nodiscard]]
constexpr handle_t handle() const MIJIN_NOEXCEPT { return handle_; }
[[nodiscard]]
constexpr TaskLoop* getLoop() MIJIN_NOEXCEPT
constexpr TaskLoop<TAllocator>* getLoop() MIJIN_NOEXCEPT
{
return handle_.promise().loop_;
}
constexpr void setLoop(TaskLoop* loop) MIJIN_NOEXCEPT
constexpr void setLoop(TaskLoop<TAllocator>* loop) MIJIN_NOEXCEPT
{
// MIJIN_ASSERT(handle_.promise().loop_ == nullptr
// || handle_.promise().loop_ == loop
@ -427,12 +504,24 @@ private:
handle_.promise().loop_ = loop;
}
friend class TaskLoop;
friend class TaskLoop<TAllocator>;
template<typename TTask>
template<typename TTask, template<typename> typename TAllocator2>
friend class WrappedTask;
};
template<typename T>
struct is_task : std::false_type {};
template<typename TResult, template<typename...> typename TAllocator>
struct is_task<TaskBase<TResult, TAllocator>> : std::true_type {};
template<typename T>
inline constexpr bool is_task_v = is_task<T>::value;
template<typename T>
concept task_type = is_task_v<T>;
template<template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
class WrappedTaskBase
{
public:
@ -444,7 +533,7 @@ public:
virtual void resume() = 0;
virtual void* raw() MIJIN_NOEXCEPT = 0;
virtual std::coroutine_handle<> handle() MIJIN_NOEXCEPT = 0;
virtual void setLoop(TaskLoop* loop) MIJIN_NOEXCEPT = 0;
virtual void setLoop(TaskLoop<TAllocator>* loop) MIJIN_NOEXCEPT = 0;
virtual std::shared_ptr<TaskSharedState>& sharedState() MIJIN_NOEXCEPT = 0;
[[nodiscard]] inline bool canResume() {
@ -453,8 +542,8 @@ public:
}
};
template<typename TTask>
class WrappedTask : public WrappedTaskBase
template<typename TTask, template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
class WrappedTask : public WrappedTaskBase<TAllocator>
{
private:
TTask task_;
@ -480,57 +569,95 @@ public:
void resume() override { task_.resume(); }
void* raw() MIJIN_NOEXCEPT override { return &task_; }
std::coroutine_handle<> handle() MIJIN_NOEXCEPT override { return task_.handle(); }
void setLoop(TaskLoop* loop) MIJIN_NOEXCEPT override { task_.setLoop(loop); }
void setLoop(TaskLoop<TAllocator>* loop) MIJIN_NOEXCEPT override { task_.setLoop(loop); }
virtual std::shared_ptr<TaskSharedState>& sharedState() MIJIN_NOEXCEPT override { return task_.sharedState(); }
};
template<typename TTask>
std::unique_ptr<WrappedTask<TTask>> wrapTask(TTask&& task) MIJIN_NOEXCEPT
template<typename TTask, template<typename> typename TAllocator>
auto wrapTask(TAllocator<WrappedTask<TTask, TAllocator>> allocator, TTask&& task)
{
return std::make_unique<WrappedTask<TTask>>(std::forward<TTask>(task));
using wrapped_task_t = WrappedTask<TTask, TAllocator>;
using deleter_t = AllocatorDeleter<TAllocator<wrapped_task_t>>;
using allocator_t = TAllocator<wrapped_task_t>;
wrapped_task_t* ptr = ::new (allocator.allocate(1)) wrapped_task_t(std::forward<TTask>(task));
return std::unique_ptr<wrapped_task_t, deleter_t>(ptr, AllocatorDeleter<allocator_t>(std::move(allocator)));
}
template<template<typename> typename TAllocator>
class TaskLoop
{
public:
MIJIN_DEFINE_FLAG(CanContinue);
MIJIN_DEFINE_FLAG(IgnoreWaiting);
using wrapped_task_t = WrappedTaskBase;
using wrapped_task_base_ptr_t = std::unique_ptr<wrapped_task_t>;
using wrapped_task_t = WrappedTaskBase<TAllocator>;
using wrapped_allocator_t = TAllocator<wrapped_task_t>;
using wrapped_deleter_t = AllocatorDeleter<wrapped_allocator_t >;
using wrapped_task_base_ptr_t = std::unique_ptr<wrapped_task_t, wrapped_deleter_t>;
struct StoredTask
{
using set_future_t = std::function<void(StoredTask&)>;
wrapped_task_base_ptr_t task;
std::function<void(StoredTask&)> setFuture;
set_future_t setFuture;
std::any resultData;
StoredTask(wrapped_task_base_ptr_t&& task_, set_future_t&& setFuture_, std::any&& resultData_)
: task(std::move(task_)), setFuture(std::move(setFuture_)), resultData(std::move(resultData_)) {}
template<typename T>
StoredTask(TAllocator<T> allocator_) : task(nullptr, wrapped_deleter_t(wrapped_allocator_t(allocator_))) {}
};
using exception_handler_t = std::function<void(std::exception_ptr)>;
using allocator_t = TAllocator<void>;
protected:
using task_vector_t = std::vector<StoredTask>;
using task_vector_t = std::vector<StoredTask, TAllocator<StoredTask>>;
template<typename TTask>
using wrapped_task_ptr_t = std::unique_ptr<WrappedTask<TTask>>;
exception_handler_t uncaughtExceptionHandler_;
[[no_unique_address]] allocator_t allocator_;
public:
TaskLoop() MIJIN_NOEXCEPT = default;
explicit TaskLoop(allocator_t allocator = {}) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<allocator_t>)
: allocator_(std::move(allocator)) {};
TaskLoop(const TaskLoop&) = delete;
TaskLoop(TaskLoop&&) = delete;
virtual ~TaskLoop() MIJIN_NOEXCEPT = default;
[[nodiscard]]
const allocator_t& getAllocator() const MIJIN_NOEXCEPT { return allocator_; }
TaskLoop& operator=(const TaskLoop&) = delete;
TaskLoop& operator=(TaskLoop&&) = delete;
void setUncaughtExceptionHandler(exception_handler_t handler) MIJIN_NOEXCEPT { uncaughtExceptionHandler_ = std::move(handler); }
template<typename TResult>
inline FuturePtr<TResult> addTask(TaskBase<TResult> task, TaskHandle* outHandle = nullptr) MIJIN_NOEXCEPT;
FuturePtr<TResult> addTaskImpl(TaskBase<TResult, TAllocator> task, TaskHandle* outHandle) MIJIN_NOEXCEPT;
template<typename TResult>
FuturePtr<TResult> addTask(TaskBase<TResult, TAllocator> task, TaskHandle* outHandle = nullptr) MIJIN_NOEXCEPT
{
static_assert(TaskAllocatorTraits<TAllocator>::default_is_valid_v, "Allocator is not valid when default constructed, use makeTask() instead.");
return addTaskImpl(std::move(task), outHandle);
}
template<typename TCoro, typename... TArgs>
auto makeTask(TCoro&& coro, TaskHandle& outHandle, TArgs&&... args) MIJIN_NOEXCEPT;
template<typename TCoro, typename... TArgs>
auto makeTask(TCoro&& coro, TArgs&&... args) MIJIN_NOEXCEPT
{
TaskHandle dummy;
return makeTask(std::forward<TCoro>(coro), dummy, std::forward<TArgs>(args)...);
}
virtual void transferCurrentTask(TaskLoop& otherLoop) MIJIN_NOEXCEPT = 0;
virtual void addStoredTask(StoredTask&& storedTask) MIJIN_NOEXCEPT = 0;
[[nodiscard]] static TaskLoop& current() MIJIN_NOEXCEPT;
[[nodiscard]] static TaskLoop* currentOpt() MIJIN_NOEXCEPT;
protected:
inline TaskStatus tickTask(StoredTask& task);
protected:
@ -542,17 +669,29 @@ protected:
template<typename TResult = void>
using Task = TaskBase<TResult>;
class SimpleTaskLoop : public TaskLoop
template<template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
class BaseSimpleTaskLoop : public TaskLoop<TAllocator>
{
private:
using base_t = TaskLoop<TAllocator>;
using typename TaskLoop<TAllocator>::task_vector_t;
using typename TaskLoop<TAllocator>::allocator_t;
using typename TaskLoop<TAllocator>::StoredTask;
using typename TaskLoop<TAllocator>::CanContinue;
using typename TaskLoop<TAllocator>::IgnoreWaiting;
using base_t::allocator_;
task_vector_t tasks_;
task_vector_t newTasks_;
task_vector_t::iterator currentTask_;
MessageQueue<StoredTask> queuedTasks_;
std::thread::id threadId_;
public:
explicit BaseSimpleTaskLoop(const allocator_t& allocator = {}) MIJIN_NOEXCEPT_IF(std::is_nothrow_copy_constructible_v<allocator_t>)
: base_t(std::move(allocator)), tasks_(TAllocator<StoredTask>(allocator_)), newTasks_(TAllocator<StoredTask>(allocator_)),
queuedTasks_(constructArray<StoredTask, MessageQueue<StoredTask>::BUFFER_SIZE>(allocator_)) {}
public: // TaskLoop implementation
void transferCurrentTask(TaskLoop& otherLoop) MIJIN_NOEXCEPT override;
void transferCurrentTask(TaskLoop<TAllocator>& otherLoop) MIJIN_NOEXCEPT override;
void addStoredTask(StoredTask&& storedTask) MIJIN_NOEXCEPT override;
public: // public interface
@ -562,23 +701,39 @@ public: // public interface
inline CanContinue tick();
inline void runUntilDone(IgnoreWaiting ignoreWaiting = IgnoreWaiting::NO);
inline void cancelAllTasks() MIJIN_NOEXCEPT;
[[nodiscard]] inline std::vector<TaskHandle> getAllTasks() const MIJIN_NOEXCEPT;
[[nodiscard]] inline std::vector<TaskHandle, TAllocator<TaskHandle>> getAllTasks() const MIJIN_NOEXCEPT;
private:
inline void assertCorrectThread() { MIJIN_ASSERT(threadId_ == std::thread::id() || threadId_ == std::this_thread::get_id(), "Unsafe to TaskLoop from different thread!"); }
};
using SimpleTaskLoop = BaseSimpleTaskLoop<>;
class MultiThreadedTaskLoop : public TaskLoop
template<template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
class BaseMultiThreadedTaskLoop : public TaskLoop<TAllocator>
{
private:
using base_t = TaskLoop<TAllocator>;
using typename base_t::task_vector_t;
using typename base_t::allocator_t;
using typename base_t::StoredTask;
using base_t::allocator_;
task_vector_t parkedTasks_; // buffer for tasks that don't fit into readyTasks_
MessageQueue<StoredTask> queuedTasks_; // tasks that should be appended to parked tasks
MessageQueue<StoredTask> readyTasks_; // task queue to send tasks to a worker thread
MessageQueue<StoredTask> returningTasks_; // task that have executed on a worker thread and return for further processing
std::jthread managerThread_;
std::vector<std::jthread> workerThreads_;
std::vector<std::jthread, TAllocator<std::jthread>> workerThreads_;
public:
explicit BaseMultiThreadedTaskLoop(allocator_t allocator = {}) MIJIN_NOEXCEPT_IF(std::is_nothrow_copy_constructible_v<allocator_t>)
: base_t(std::move(allocator)),
parkedTasks_(TAllocator<StoredTask>(allocator_)),
queuedTasks_(constructArray<StoredTask, MessageQueue<StoredTask>::BUFFER_SIZE>(allocator_)),
readyTasks_(constructArray<StoredTask, MessageQueue<StoredTask>::BUFFER_SIZE>(allocator_)),
returningTasks_(constructArray<StoredTask, MessageQueue<StoredTask>::BUFFER_SIZE>(allocator_)),
workerThreads_(TAllocator<std::jthread>(allocator_)) {}
public: // TaskLoop implementation
void transferCurrentTask(TaskLoop& otherLoop) MIJIN_NOEXCEPT override;
void transferCurrentTask(TaskLoop<TAllocator>& otherLoop) MIJIN_NOEXCEPT override;
void addStoredTask(StoredTask&& storedTask) MIJIN_NOEXCEPT override;
public: // public interface
@ -587,7 +742,14 @@ public: // public interface
private: // private stuff
void managerThread(std::stop_token stopToken);
void workerThread(std::stop_token stopToken, std::size_t workerId);
static StoredTask*& getCurrentTask()
{
static thread_local StoredTask* task = nullptr;
return task;
}
};
using MultiThreadedTaskLoop = BaseMultiThreadedTaskLoop<>;
//
// public functions
@ -595,12 +757,12 @@ private: // private stuff
namespace impl
{
extern thread_local TaskLoop::StoredTask* gCurrentTask;
extern thread_local std::shared_ptr<TaskSharedState> gCurrentTaskState;
inline void throwIfCancelled()
{
#if MIJIN_COROUTINE_ENABLE_CANCEL
if (gCurrentTask->task->sharedState()->cancelled_)
if (gCurrentTaskState->cancelled_)
{
throw TaskCancelled();
}
@ -617,6 +779,15 @@ void TaskHandle::cancel() const MIJIN_NOEXCEPT
}
}
Optional<std::source_location> TaskHandle::getLocation() const MIJIN_NOEXCEPT
{
if (std::shared_ptr<TaskSharedState> state = state_.lock())
{
return state->sourceLoc;
}
return NULL_OPTIONAL;
}
#if MIJIN_COROUTINE_ENABLE_DEBUG_INFO
Optional<Stacktrace> TaskHandle::getCreationStack() const MIJIN_NOEXCEPT
{
@ -628,8 +799,8 @@ Optional<Stacktrace> TaskHandle::getCreationStack() const MIJIN_NOEXCEPT
}
#endif // MIJIN_COROUTINE_ENABLE_DEBUG_INFO
template<typename TResult>
TaskBase<TResult>::~TaskBase() MIJIN_NOEXCEPT
template<typename TResult, template<typename> typename TAllocator>
TaskBase<TResult, TAllocator>::~TaskBase() MIJIN_NOEXCEPT
{
if (handle_)
{
@ -637,13 +808,14 @@ TaskBase<TResult>::~TaskBase() MIJIN_NOEXCEPT
}
}
template<template<typename> typename TAllocator>
template<typename TResult>
inline FuturePtr<TResult> TaskLoop::addTask(TaskBase<TResult> task, TaskHandle* outHandle) MIJIN_NOEXCEPT
FuturePtr<TResult> TaskLoop<TAllocator>::addTaskImpl(TaskBase<TResult, TAllocator> task, TaskHandle* outHandle) MIJIN_NOEXCEPT
{
MIJIN_ASSERT(!task.getLoop(), "Attempting to add task that already has a loop!");
task.setLoop(this);
auto future = std::make_shared<Future<TResult>>();
FuturePtr<TResult> future = std::allocate_shared<Future<TResult>>(TAllocator<Future<TResult>>(allocator_), allocator_);
auto setFuture = &setFutureHelper<TResult>;
if (outHandle != nullptr)
@ -652,26 +824,35 @@ inline FuturePtr<TResult> TaskLoop::addTask(TaskBase<TResult> task, TaskHandle*
}
// add tasks to a seperate vector first as we might be running another task right now
addStoredTask(StoredTask{
.task = wrapTask(std::move(task)),
.setFuture = setFuture,
.resultData = future
});
TAllocator<WrappedTask<TaskBase<TResult, TAllocator>>> allocator(allocator_);
addStoredTask(StoredTask(wrapTask(std::move(allocator), std::move(task)), std::move(setFuture), future));
return future;
}
inline TaskStatus TaskLoop::tickTask(StoredTask& task)
template<template<typename> typename TAllocator>
template<typename TCoro, typename... TArgs>
auto TaskLoop<TAllocator>::makeTask(TCoro&& coro, TaskHandle& outHandle, TArgs&&... args) MIJIN_NOEXCEPT
{
TaskLoop<TAllocator>* previousLoop = currentLoopStorage();
currentLoopStorage() = this;
auto result = addTaskImpl(std::invoke(std::forward<TCoro>(coro), std::forward<TArgs>(args)...), &outHandle);
currentLoopStorage() = previousLoop;
return result;
}
template<template<typename> typename TAllocator>
TaskStatus TaskLoop<TAllocator>::tickTask(StoredTask& task)
{
TaskStatus status = {};
impl::gCurrentTask = &task;
impl::gCurrentTaskState = task.task->sharedState();
do
{
task.task->resume();
status = task.task ? task.task->status() : TaskStatus::WAITING; // no inner task -> task switch context (and will be removed later)
}
while (status == TaskStatus::RUNNING);
impl::gCurrentTask = nullptr;
impl::gCurrentTaskState = nullptr;
#if MIJIN_COROUTINE_ENABLE_EXCEPTION_HANDLING
if (task.task && task.task->exception())
@ -706,22 +887,31 @@ inline TaskStatus TaskLoop::tickTask(StoredTask& task)
return status;
}
/* static */ inline auto TaskLoop::current() MIJIN_NOEXCEPT -> TaskLoop&
template<template<typename> typename TAllocator>
/* static */ inline auto TaskLoop<TAllocator>::current() MIJIN_NOEXCEPT -> TaskLoop&
{
MIJIN_ASSERT(currentLoopStorage() != nullptr, "Attempting to fetch current loop while no coroutine is running!");
return *currentLoopStorage();
}
/* static */ auto TaskLoop::currentLoopStorage() MIJIN_NOEXCEPT -> TaskLoop*&
template<template<typename> typename TAllocator>
/* static */ inline auto TaskLoop<TAllocator>::currentOpt() MIJIN_NOEXCEPT -> TaskLoop*
{
return currentLoopStorage();
}
template<template<typename> typename TAllocator>
/* static */ auto TaskLoop<TAllocator>::currentLoopStorage() MIJIN_NOEXCEPT -> TaskLoop*&
{
static thread_local TaskLoop* storage = nullptr;
return storage;
}
template<template<typename> typename TAllocator>
template<typename TResult>
/* static */ inline void TaskLoop::setFutureHelper(StoredTask& storedTask) MIJIN_NOEXCEPT
/* static */ inline void TaskLoop<TAllocator>::setFutureHelper(StoredTask& storedTask) MIJIN_NOEXCEPT
{
TaskBase<TResult>& task = *static_cast<TaskBase<TResult>*>(storedTask.task->raw());
TaskBase<TResult, TAllocator>& task = *static_cast<TaskBase<TResult, TAllocator>*>(storedTask.task->raw());
auto future = std::any_cast<FuturePtr<TResult>>(storedTask.resultData);
if constexpr (!std::is_same_v<TResult, void>)
@ -734,9 +924,10 @@ template<typename TResult>
}
}
inline std::suspend_always switchContext(TaskLoop& taskLoop)
template<template<typename> typename TAllocator>
inline std::suspend_always switchContext(TaskLoop<TAllocator>& taskLoop)
{
TaskLoop& currentTaskLoop = TaskLoop::current();
TaskLoop<TAllocator>& currentTaskLoop = TaskLoop<TAllocator>::current();
if (&currentTaskLoop == &taskLoop) {
return {};
}
@ -744,11 +935,68 @@ inline std::suspend_always switchContext(TaskLoop& taskLoop)
return {};
}
inline auto SimpleTaskLoop::tick() -> CanContinue
template<template<typename> typename TAllocator>
void BaseSimpleTaskLoop<TAllocator>::transferCurrentTask(TaskLoop<TAllocator>& otherLoop) MIJIN_NOEXCEPT
{
assertCorrectThread();
if (&otherLoop == this) {
return;
}
MIJIN_ASSERT_FATAL(currentTask_ != tasks_.end(), "Trying to call transferCurrentTask() while not running a task!");
// now start the transfer, first disown the task
StoredTask storedTask = std::move(*currentTask_);
currentTask_->task = nullptr; // just to be sure
// then send it over to the other loop
otherLoop.addStoredTask(std::move(storedTask));
}
template<template<typename> typename TAllocator>
void BaseSimpleTaskLoop<TAllocator>::addStoredTask(StoredTask&& storedTask) MIJIN_NOEXCEPT
{
storedTask.task->setLoop(this);
if (threadId_ == std::thread::id() || threadId_ == std::this_thread::get_id())
{
// same thread, just copy it over
if (TaskLoop<TAllocator>::currentLoopStorage() != nullptr) {
// currently running, can't append to tasks_ directly
newTasks_.push_back(std::move(storedTask));
}
else {
tasks_.push_back(std::move(storedTask));
}
}
else
{
// other thread, better be safe
queuedTasks_.push(std::move(storedTask));
}
}
template<template<typename> typename TAllocator>
std::size_t BaseSimpleTaskLoop<TAllocator>::getActiveTasks() const MIJIN_NOEXCEPT
{
std::size_t sum = 0;
for (const StoredTask& task : mijin::chain(tasks_, newTasks_))
{
const TaskStatus status = task.task ? task.task->status() : TaskStatus::FINISHED;
if (status == TaskStatus::SUSPENDED || status == TaskStatus::RUNNING)
{
++sum;
}
}
return sum;
}
template<template<typename> typename TAllocator>
inline auto BaseSimpleTaskLoop<TAllocator>::tick() -> CanContinue
{
// set current taskloop
MIJIN_ASSERT(currentLoopStorage() == nullptr, "Trying to tick a loop from a coroutine, this is not supported.");
currentLoopStorage() = this;
MIJIN_ASSERT(TaskLoop<TAllocator>::currentLoopStorage() == nullptr, "Trying to tick a loop from a coroutine, this is not supported.");
TaskLoop<TAllocator>::currentLoopStorage() = this;
threadId_ = std::this_thread::get_id();
// move over all tasks from newTasks
@ -791,7 +1039,7 @@ inline auto SimpleTaskLoop::tick() -> CanContinue
continue;
}
status = tickTask(task);
status = base_t::tickTask(task);
if (status == TaskStatus::SUSPENDED || status == TaskStatus::YIELDED)
{
@ -799,7 +1047,7 @@ inline auto SimpleTaskLoop::tick() -> CanContinue
}
}
// reset current loop
currentLoopStorage() = nullptr;
TaskLoop<TAllocator>::currentLoopStorage() = nullptr;
// remove any tasks that have been transferred to another queue
it = std::remove_if(tasks_.begin(), tasks_.end(), [](const StoredTask& task) {
@ -810,7 +1058,8 @@ inline auto SimpleTaskLoop::tick() -> CanContinue
return canContinue;
}
inline void SimpleTaskLoop::runUntilDone(IgnoreWaiting ignoreWaiting)
template<template<typename> typename TAllocator>
void BaseSimpleTaskLoop<TAllocator>::runUntilDone(IgnoreWaiting ignoreWaiting)
{
while (!tasks_.empty() || !newTasks_.empty())
{
@ -822,7 +1071,8 @@ inline void SimpleTaskLoop::runUntilDone(IgnoreWaiting ignoreWaiting)
}
}
inline void SimpleTaskLoop::cancelAllTasks() MIJIN_NOEXCEPT
template<template<typename> typename TAllocator>
void BaseSimpleTaskLoop<TAllocator>::cancelAllTasks() MIJIN_NOEXCEPT
{
for (StoredTask& task : mijin::chain(tasks_, newTasks_))
{
@ -835,9 +1085,10 @@ inline void SimpleTaskLoop::cancelAllTasks() MIJIN_NOEXCEPT
}
}
inline std::vector<TaskHandle> SimpleTaskLoop::getAllTasks() const MIJIN_NOEXCEPT
template<template<typename> typename TAllocator>
std::vector<TaskHandle, TAllocator<TaskHandle>> BaseSimpleTaskLoop<TAllocator>::getAllTasks() const MIJIN_NOEXCEPT
{
std::vector<TaskHandle> result;
std::vector<TaskHandle, TAllocator<TaskHandle>> result((TAllocator<TaskHandle>(TaskLoop<TAllocator>::allocator_)));
for (const StoredTask& task : mijin::chain(tasks_, newTasks_))
{
result.emplace_back(task.task->sharedState());
@ -845,6 +1096,151 @@ inline std::vector<TaskHandle> SimpleTaskLoop::getAllTasks() const MIJIN_NOEXCEP
return result;
}
template<template<typename> typename TAllocator>
void BaseMultiThreadedTaskLoop<TAllocator>::managerThread(std::stop_token stopToken) // NOLINT(performance-unnecessary-value-param)
{
// setCurrentThreadName("Task Manager");
while (!stopToken.stop_requested())
{
// first clear out any parked tasks that are actually finished
auto itRem = std::remove_if(parkedTasks_.begin(), parkedTasks_.end(), [](StoredTask& task) {
return !task.task || task.task->status() == TaskStatus::FINISHED;
});
parkedTasks_.erase(itRem, parkedTasks_.end());
// then try to push any task from the buffer into the queue, if possible
for (auto it = parkedTasks_.begin(); it != parkedTasks_.end();)
{
if (!it->task->canResume())
{
++it;
continue;
}
if (readyTasks_.tryPushMaybeMove(*it)) {
it = parkedTasks_.erase(it);
}
else {
break;
}
}
// then clear the incoming task queue
while (true)
{
std::optional<StoredTask> task = queuedTasks_.tryPop();
if (!task.has_value()) {
break;
}
// try to directly move it into the next queue
if (readyTasks_.tryPushMaybeMove(*task)) {
continue;
}
// otherwise park it
parkedTasks_.push_back(std::move(*task));
}
// next collect tasks returning from the worker threads
while (true)
{
std::optional<StoredTask> task = returningTasks_.tryPop();
if (!task.has_value()) {
break;
}
if (task->task == nullptr || task->task->status() == TaskStatus::FINISHED) {
continue; // task has been transferred or finished
}
if (task->task->canResume() && readyTasks_.tryPushMaybeMove(*task)) {
continue; // instantly resume, no questions asked
}
// otherwise park it for future processing
parkedTasks_.push_back(std::move(*task));
}
std::this_thread::sleep_for(std::chrono::milliseconds(1));
}
}
template<template<typename> typename TAllocator>
void BaseMultiThreadedTaskLoop<TAllocator>::workerThread(std::stop_token stopToken, std::size_t workerId) // NOLINT(performance-unnecessary-value-param)
{
TaskLoop<TAllocator>::currentLoopStorage() = this; // forever (on this thread)
std::array<char, 16> threadName;
(void) std::snprintf(threadName.data(), 16, "Task Worker %lu", static_cast<unsigned long>(workerId));
// setCurrentThreadName(threadName.data());
while (!stopToken.stop_requested())
{
// try to fetch a task to run
std::optional<StoredTask> task = readyTasks_.tryPop();
if (!task.has_value())
{
std::this_thread::sleep_for(std::chrono::milliseconds(1));
continue;
}
// run it
getCurrentTask() = &*task;
impl::gCurrentTaskState = task->task->sharedState();
tickTask(*task);
getCurrentTask() = nullptr;
impl::gCurrentTaskState = nullptr;
// and give it back
returningTasks_.push(std::move(*task));
}
}
template<template<typename> typename TAllocator>
void BaseMultiThreadedTaskLoop<TAllocator>::transferCurrentTask(TaskLoop<TAllocator>& otherLoop) MIJIN_NOEXCEPT
{
if (&otherLoop == this) {
return;
}
MIJIN_ASSERT_FATAL(getCurrentTask() != nullptr, "Trying to call transferCurrentTask() while not running a task!");
// now start the transfer, first disown the task
StoredTask storedTask = std::move(*getCurrentTask());
getCurrentTask()->task = nullptr; // just to be sure
// then send it over to the other loop
otherLoop.addStoredTask(std::move(storedTask));
}
template<template<typename> typename TAllocator>
void BaseMultiThreadedTaskLoop<TAllocator>::addStoredTask(StoredTask&& storedTask) MIJIN_NOEXCEPT
{
storedTask.task->setLoop(this);
// just assume we are not on the manager thread, as that wouldn't make sense
queuedTasks_.push(std::move(storedTask));
}
template<template<typename> typename TAllocator>
void BaseMultiThreadedTaskLoop<TAllocator>::start(std::size_t numWorkerThreads)
{
managerThread_ = std::jthread([this](std::stop_token stopToken) { managerThread(std::move(stopToken)); });
workerThreads_.reserve(numWorkerThreads);
for (std::size_t workerId = 0; workerId < numWorkerThreads; ++workerId) {
workerThreads_.emplace_back([this, workerId](std::stop_token stopToken) { workerThread(std::move(stopToken), workerId); });
}
}
template<template<typename> typename TAllocator>
void BaseMultiThreadedTaskLoop<TAllocator>::stop()
{
workerThreads_.clear(); // will also set the stop token
managerThread_ = {}; // this too
}
// utility stuff
inline TaskAwaitableSuspend c_suspend() {
@ -869,10 +1265,40 @@ Task<> c_allDone(const TCollection<FuturePtr<TType>, TTemplateArgs...>& futures)
} while (!allDone);
}
template<template<typename> typename TAllocator, typename... TResult>
struct AllDoneHelper
{
TaskLoop<TAllocator>& currentTaskLoop;
template<typename T, std::size_t index>
auto makeFuture(TaskBase<T, TAllocator>&& task, std::array<TaskHandle, sizeof...(TResult)>& outHandles)
{
return currentTaskLoop.addTaskImpl(std::move(task), &outHandles[index]);
}
template<std::size_t... indices>
auto makeFutures(TaskBase<TResult, TAllocator>&&... tasks, std::array<TaskHandle, sizeof...(TResult)>& outHandles, std::index_sequence<indices...>)
{
return std::make_tuple(makeFuture<TResult, indices>(std::move(tasks), outHandles)...);
}
};
template<template<typename> typename TAllocator, typename... TResult>
TaskBase<std::tuple<TResult...>, TAllocator> c_allDone(TaskBase<TResult, TAllocator>&&... tasks)
{
TaskLoop<TAllocator>& currentTaskLoop = TaskLoop<TAllocator>::current();
std::tuple futures = std::make_tuple(currentTaskLoop.addTaskImpl(std::move(tasks), nullptr)...);
while (!allReady(futures)) {
co_await c_suspend();
}
co_return getAll(futures);
}
[[nodiscard]] inline TaskHandle getCurrentTask() MIJIN_NOEXCEPT
{
MIJIN_ASSERT(impl::gCurrentTask != nullptr, "Attempt to call getCurrentTask() outside of task.");
return TaskHandle(impl::gCurrentTask->task->sharedState());
MIJIN_ASSERT(impl::gCurrentTaskState != nullptr, "Attempt to call getCurrentTask() outside of task.");
return TaskHandle(impl::gCurrentTaskState);
}
}

52
source/mijin/async/future.hpp
View File

@ -4,8 +4,9 @@
#if !defined(MIJIN_ASYNC_FUTURE_HPP_INCLUDED)
#define MIJIN_ASYNC_FUTURE_HPP_INCLUDED 1
#include <optional>
#include <memory>
#include <optional>
#include <tuple>
#include <type_traits>
#include "./signal.hpp"
#include "../container/optional.hpp"
@ -26,7 +27,7 @@ namespace mijin
//
// public types
//
template<typename TValue>
template<typename TValue, template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
class Future;
// TODO: add support for mutexes and waiting for futures
@ -57,16 +58,17 @@ struct FutureStorage<void>
};
} // namespace impl
template<typename TValue>
template<typename TValue, template<typename> typename TAllocator>
class Future
{
private:
impl::FutureStorage<TValue> value_;
[[no_unique_address]] impl::FutureStorage<TValue> value_;
bool isSet_ = false;
public:
Future() = default;
Future(const Future&) = delete;
Future(Future&&) MIJIN_NOEXCEPT = default;
explicit Future(TAllocator<void> allocator) : sigSet(std::move(allocator)) {}
public:
Future& operator=(const Future&) = delete;
Future& operator=(Future&&) MIJIN_NOEXCEPT = default;
@ -126,16 +128,52 @@ public: // modification
}
}
public: // signals
Signal<> sigSet;
BaseSignal<TAllocator> sigSet;
};
template<typename TValue>
using FuturePtr = std::shared_ptr<Future<TValue>>;
template<typename TValue = void, template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
using FuturePtr = std::shared_ptr<Future<TValue, TAllocator>>;
//
// public functions
//
namespace impl
{
template<typename... TResult>
struct MultiFutureHelper
{
template<std::size_t... indices>
static bool allReady(const std::tuple<FuturePtr<TResult>...>& futures, std::index_sequence<indices...>) MIJIN_NOEXCEPT
{
return (std::get<indices>(futures)->ready() && ...);
}
template<std::size_t... indices>
static std::tuple<std::remove_reference_t<TResult>...> getAll(const std::tuple<FuturePtr<TResult>...>& futures, std::index_sequence<indices...>) MIJIN_NOEXCEPT
{
return std::make_tuple(std::move(std::get<indices>(futures)->get())...);
}
};
}
template<typename T, template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
constexpr FuturePtr<T> makeSharedFuture(TAllocator<Future<T>> allocator = {}) MIJIN_NOEXCEPT
{
return std::allocate_shared<Future<T>>(std::move(allocator));
}
template<typename... TResult>
constexpr bool allReady(const std::tuple<FuturePtr<TResult>...>& futures) MIJIN_NOEXCEPT
{
return impl::MultiFutureHelper<TResult...>::allReady(futures, std::index_sequence_for<TResult...>());
}
template<typename... TResult>
constexpr std::tuple<std::remove_reference_t<TResult>...> getAll(const std::tuple<FuturePtr<TResult>...>& futures) MIJIN_NOEXCEPT
{
return impl::MultiFutureHelper<TResult...>::getAll(futures, std::index_sequence_for<TResult...>());
}
} // namespace mijin
#endif // !defined(MIJIN_ASYNC_FUTURE_HPP_INCLUDED)

37
source/mijin/async/message_queue.hpp
View File

@ -79,15 +79,20 @@ class MessageQueue
public:
using message_t = TMessage;
using iterator_t = MessageQueueIterator<MessageQueue<TMessage, bufferSize>>;
static constexpr std::size_t BUFFER_SIZE = bufferSize;
private:
std::array<TMessage, bufferSize> messages;
mijin::BitArray<bufferSize, true> messageReady;
std::atomic_uint writePos = 0;
std::atomic_uint readPos = 0;
std::array<TMessage, bufferSize> messages_;
mijin::BitArray<bufferSize, true> messageReady_;
std::atomic_uint writePos_ = 0;
std::atomic_uint readPos_ = 0;
public:
MessageQueue() = default;
MessageQueue(const MessageQueue&) = delete;
MessageQueue(MessageQueue&&) = delete;
explicit MessageQueue(const std::array<TMessage, bufferSize>& messages) MIJIN_NOEXCEPT_IF(std::is_nothrow_copy_constructible_v<TMessage>)
: messages_(messages) {}
explicit MessageQueue(std::array<TMessage, bufferSize>&& messages) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<TMessage>)
: messages_(std::move(messages)) {}
MessageQueue& operator=(const MessageQueue&) = delete;
MessageQueue& operator=(MessageQueue&&) = delete;
@ -118,22 +123,22 @@ struct TaskMessageQueue
template<typename TMessage, std::size_t bufferSize>
bool MessageQueue<TMessage, bufferSize>::tryPushMaybeMove(TMessage& message)
{
unsigned oldWritePos = writePos.load(std::memory_order_relaxed);
unsigned oldWritePos = writePos_.load(std::memory_order_relaxed);
unsigned newWritePos = 0;
do
{
newWritePos = (oldWritePos + 1) % bufferSize;
if (newWritePos == readPos) {
if (newWritePos == readPos_) {
return false;
}
} while (!writePos.compare_exchange_weak(oldWritePos, newWritePos, std::memory_order_release, std::memory_order_relaxed));
} while (!writePos_.compare_exchange_weak(oldWritePos, newWritePos, std::memory_order_release, std::memory_order_relaxed));
while (messageReady.get(oldWritePos)) {
while (messageReady_.get(oldWritePos)) {
std::this_thread::yield(); // someone is still reading, wait...
}
messages[oldWritePos] = std::move(message);
messageReady.set(oldWritePos, true);
messages_[oldWritePos] = std::move(message);
messageReady_.set(oldWritePos, true);
return true;
}
@ -149,22 +154,22 @@ void MessageQueue<TMessage, bufferSize>::push(TMessage message)
template<typename TMessage, std::size_t bufferSize>
std::optional<TMessage> MessageQueue<TMessage, bufferSize>::tryPop()
{
unsigned oldReadPos = readPos.load(std::memory_order_relaxed);
unsigned oldReadPos = readPos_.load(std::memory_order_relaxed);
unsigned newReadPos = 0;
do
{
if (oldReadPos == writePos) {
if (oldReadPos == writePos_) {
return std::nullopt;
}
newReadPos = (oldReadPos + 1) % bufferSize;
} while (!readPos.compare_exchange_weak(oldReadPos, newReadPos, std::memory_order_release, std::memory_order_relaxed));
} while (!readPos_.compare_exchange_weak(oldReadPos, newReadPos, std::memory_order_release, std::memory_order_relaxed));
while (!messageReady.get(oldReadPos)) {
while (!messageReady_.get(oldReadPos)) {
std::this_thread::yield(); // no harm in busy-waiting here, should be fast
};
TMessage message = std::move(messages[oldReadPos]);
messageReady.set(oldReadPos, false);
TMessage message = std::move(messages_[oldReadPos]);
messageReady_.set(oldReadPos, false);
return message;
}

59
source/mijin/async/signal.hpp
View File

@ -33,11 +33,11 @@ inline constexpr signal_token_t INVALID_SIGNAL_TOKEN = std::numeric_limits<signa
MIJIN_DEFINE_FLAG(Oneshot);
template<typename... TArgs>
class Signal
template<template<typename> typename TAllocator, typename... TArgs>
class BaseSignal
{
public:
using handler_t = std::function<void(TArgs...)>;
using handler_t = std::function<void(TArgs...)>; // TODO: write a custom function wrapper with allocator support
using token_t = signal_token_t;
private:
struct RegisteredHandler
@ -47,36 +47,41 @@ private:
token_t token;
Oneshot oneshot = Oneshot::NO;
};
using handler_vector_t = std::vector<RegisteredHandler>;
using handler_vector_t = std::vector<RegisteredHandler, TAllocator<RegisteredHandler>>;
private:
handler_vector_t handlers_;
token_t nextToken = 1;
std::mutex handlersMutex_;
public:
Signal() = default;
Signal(const Signal&) = delete;
Signal(Signal&&) MIJIN_NOEXCEPT = default;
explicit BaseSignal(TAllocator<void> allocator = {}) : handlers_(TAllocator<RegisteredHandler>(std::move(allocator))) {}
BaseSignal(const BaseSignal&) = delete;
BaseSignal(BaseSignal&&) MIJIN_NOEXCEPT = default;
public:
Signal& operator=(const Signal&) = delete;
Signal& operator=(Signal&&) MIJIN_NOEXCEPT = default;
BaseSignal& operator=(const BaseSignal&) = delete;
BaseSignal& operator=(BaseSignal&&) MIJIN_NOEXCEPT = default;
public:
template<typename THandler, typename TWeak = void>
inline token_t connect(THandler handler, Oneshot oneshot = Oneshot::NO, std::weak_ptr<TWeak> referenced = std::weak_ptr<TWeak>()) MIJIN_NOEXCEPT;
template<typename TObject, typename TWeak = void>
inline token_t connect(TObject& object, void (TObject::* handler)(TArgs...), Oneshot oneshot = Oneshot::NO, std::weak_ptr<TWeak> referenced = std::weak_ptr<TWeak>()) MIJIN_NOEXCEPT;
template<typename TObject, typename TWeak = void>
inline token_t connect(TObject& object, void (TObject::* handler)(TArgs...) const, Oneshot oneshot = Oneshot::NO, std::weak_ptr<TWeak> referenced = std::weak_ptr<TWeak>()) MIJIN_NOEXCEPT;
inline void disconnect(token_t token) MIJIN_NOEXCEPT;
template<typename... TArgs2>
inline void emit(TArgs2&&... args) MIJIN_NOEXCEPT;
};
template<typename... TArgs>
using Signal = BaseSignal<MIJIN_DEFAULT_ALLOCATOR, TArgs...>;
//
// public functions
//
template<typename... TArgs>
template<template<typename> typename TAllocator, typename... TArgs>
template<typename THandler, typename TWeak>
inline auto Signal<TArgs...>::connect(THandler handler, Oneshot oneshot, std::weak_ptr<TWeak> referenced) MIJIN_NOEXCEPT -> token_t
inline auto BaseSignal<TAllocator, TArgs...>::connect(THandler handler, Oneshot oneshot, std::weak_ptr<TWeak> referenced) MIJIN_NOEXCEPT -> token_t
{
std::lock_guard lock(handlersMutex_);
@ -91,9 +96,9 @@ inline auto Signal<TArgs...>::connect(THandler handler, Oneshot oneshot, std::we
return nextToken++;
}
template<typename... TArgs>
template<template<typename> typename TAllocator, typename... TArgs>
template<typename TObject, typename TWeak>
inline auto Signal<TArgs...>::connect(TObject& object, void (TObject::* handler)(TArgs...), Oneshot oneshot, std::weak_ptr<TWeak> referenced) MIJIN_NOEXCEPT -> token_t
inline auto BaseSignal<TAllocator, TArgs...>::connect(TObject& object, void (TObject::* handler)(TArgs...), Oneshot oneshot, std::weak_ptr<TWeak> referenced) MIJIN_NOEXCEPT -> token_t
{
std::lock_guard lock(handlersMutex_);
@ -111,8 +116,28 @@ inline auto Signal<TArgs...>::connect(TObject& object, void (TObject::* handler)
return nextToken++;
}
template<typename... TArgs>
inline void Signal<TArgs...>::disconnect(token_t token) MIJIN_NOEXCEPT
template<template<typename> typename TAllocator, typename... TArgs>
template<typename TObject, typename TWeak>
inline auto BaseSignal<TAllocator, TArgs...>::connect(TObject& object, void (TObject::* handler)(TArgs...) const, Oneshot oneshot, std::weak_ptr<TWeak> referenced) MIJIN_NOEXCEPT -> token_t
{
std::lock_guard lock(handlersMutex_);
auto callable = [object = &object, handler](TArgs... args)
{
std::invoke(handler, object, std::forward<TArgs>(args)...);
};
handlers_.push_back({
.callable = std::move(callable),
.referenced = std::move(referenced),
.token = nextToken,
.oneshot = oneshot
});
return nextToken++;
}
template<template<typename> typename TAllocator, typename... TArgs>
inline void BaseSignal<TAllocator, TArgs...>::disconnect(token_t token) MIJIN_NOEXCEPT
{
std::lock_guard lock(handlersMutex_);
@ -123,9 +148,9 @@ inline void Signal<TArgs...>::disconnect(token_t token) MIJIN_NOEXCEPT
handlers_.erase(it, handlers_.end());
}
template<typename... TArgs>
template<template<typename> typename TAllocator, typename... TArgs>
template<typename... TArgs2>
inline void Signal<TArgs...>::emit(TArgs2&&... args) MIJIN_NOEXCEPT
inline void BaseSignal<TAllocator, TArgs...>::emit(TArgs2&&... args) MIJIN_NOEXCEPT
{
std::lock_guard lock(handlersMutex_);

96
source/mijin/container/boxed_object.hpp
View File

@ -16,8 +16,26 @@ namespace mijin
//
#if !defined(MIJIN_BOXED_OBJECT_DEBUG)
#if defined(MIJIN_DEBUG)
#define MIJIN_BOXED_OBJECT_DEBUG MIJIN_DEBUG
#else
#define MIJIN_BOXED_OBJECT_DEBUG 0
#endif
#endif // !defined(MIJIN_BOXED_OBJECT_DEBUG)
#define MIJIN_BOXED_PROXY_FUNC(funcname) \
template<typename... TFuncArgs> \
decltype(auto) funcname(TFuncArgs&&... args) \
{ \
return base_t::get().funcname(std::forward<TFuncArgs>(args)...); \
}
#define MIJIN_BOXED_PROXY_FUNC_CONST(funcname) \
template<typename... TFuncArgs> \
decltype(auto) funcname(TFuncArgs&&... args) const \
{ \
return base_t::get().funcname(std::forward<TFuncArgs>(args)...); \
}
//
// public constants
@ -39,8 +57,8 @@ private:
bool constructed = false;
#endif
public:
BoxedObject() noexcept : placeholder_() {};
explicit BoxedObject(T object)
constexpr BoxedObject() MIJIN_NOEXCEPT : placeholder_() {};
explicit constexpr BoxedObject(T object) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<T>)
#if MIJIN_BOXED_OBJECT_DEBUG
: constructed(true)
#endif
@ -51,7 +69,7 @@ public:
BoxedObject(BoxedObject&&) = delete;
#if MIJIN_BOXED_OBJECT_DEBUG
~BoxedObject()
constexpr ~BoxedObject() noexcept
{
MIJIN_ASSERT(!constructed, "BoxedObject::~BoxedObject(): Object has not been destroyed prior to destructor!");
}
@ -60,13 +78,13 @@ public:
BoxedObject& operator=(const BoxedObject&) = delete;
BoxedObject& operator=(BoxedObject&&) = delete;
T& operator*() noexcept { return get(); }
const T& operator*() const noexcept { return get(); }
T* operator->() noexcept { return &get(); }
const T* operator->() const noexcept { return &get(); }
constexpr T& operator*() noexcept { return get(); }
constexpr const T& operator*() const noexcept { return get(); }
constexpr T* operator->() noexcept { return &get(); }
constexpr const T* operator->() const noexcept { return &get(); }
template<typename... TArgs>
void construct(TArgs&&... args)
constexpr void construct(TArgs&&... args) MIJIN_NOEXCEPT_IF((std::is_nothrow_constructible_v<T, TArgs...>))
{
#if MIJIN_BOXED_OBJECT_DEBUG
MIJIN_ASSERT(!constructed, "BoxedObject::construct(): Attempt to construct an already constructed object!");
@ -75,7 +93,7 @@ public:
std::construct_at(&object_, std::forward<TArgs>(args)...);
}
void destroy()
constexpr void destroy() MIJIN_NOEXCEPT
{
#if MIJIN_BOXED_OBJECT_DEBUG
MIJIN_ASSERT(constructed, "BoxedObject::destroy(): Attempt to destroy a not constructed object!");
@ -84,7 +102,7 @@ public:
std::destroy_at(&object_);
}
void copyTo(BoxedObject& other) const
constexpr void copyTo(BoxedObject& other) const MIJIN_NOEXCEPT_IF(std::is_nothrow_copy_constructible_v<T>)
{
#if MIJIN_BOXED_OBJECT_DEBUG
MIJIN_ASSERT(constructed, "BoxedObject::copy(): Attempt to copy a not constructed object!");
@ -92,7 +110,7 @@ public:
other.construct(object_);
}
void moveTo(BoxedObject& other)
constexpr void moveTo(BoxedObject& other) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<T>)
{
#if MIJIN_BOXED_OBJECT_DEBUG
MIJIN_ASSERT(constructed, "BoxedObject::copy(): Attempt to copy a not constructed object!");
@ -101,7 +119,7 @@ public:
destroy();
}
[[nodiscard]] T& get()
[[nodiscard]] constexpr T& get() MIJIN_NOEXCEPT
{
#if MIJIN_BOXED_OBJECT_DEBUG
MIJIN_ASSERT(constructed, "BoxedObject::get(): Attempt to access a not constructed object!");
@ -109,7 +127,7 @@ public:
return object_;
}
[[nodiscard]] const T& get() const
[[nodiscard]] constexpr const T& get() const MIJIN_NOEXCEPT
{
#if MIJIN_BOXED_OBJECT_DEBUG
MIJIN_ASSERT(constructed, "BoxedObject::get(): Attempt to access a not constructed object!");
@ -131,38 +149,38 @@ private:
BoxedObject<T>* end_ = nullptr;
#endif
public:
BoxedObjectIterator() = default;
explicit constexpr BoxedObjectIterator(BoxedObject<T>* box, BoxedObject<T>* start, BoxedObject<T>* end)
BoxedObjectIterator() noexcept = default;
explicit constexpr BoxedObjectIterator(BoxedObject<T>* box, BoxedObject<T>* start, BoxedObject<T>* end) MIJIN_NOEXCEPT
: box_(box)
#if MIJIN_CHECKED_ITERATORS
, start_(start), end_(end)
#endif
{}
BoxedObjectIterator(const BoxedObjectIterator&) = default;
BoxedObjectIterator(BoxedObjectIterator&&) noexcept = default;
constexpr BoxedObjectIterator(const BoxedObjectIterator&) noexcept = default;
constexpr BoxedObjectIterator(BoxedObjectIterator&&) noexcept = default;
BoxedObjectIterator& operator=(const BoxedObjectIterator&) = default;
BoxedObjectIterator& operator=(BoxedObjectIterator&&) noexcept = default;
BoxedObjectIterator& operator+=(difference_type diff);
BoxedObjectIterator& operator-=(difference_type diff) { return (*this += -diff); }
constexpr BoxedObjectIterator& operator=(const BoxedObjectIterator&) noexcept = default;
constexpr BoxedObjectIterator& operator=(BoxedObjectIterator&&) noexcept = default;
constexpr BoxedObjectIterator& operator+=(difference_type diff) MIJIN_NOEXCEPT;
constexpr BoxedObjectIterator& operator-=(difference_type diff) MIJIN_NOEXCEPT { return (*this += -diff); }
constexpr auto operator<=>(const BoxedObjectIterator& other) const noexcept = default;
[[nodiscard]] T& operator*() const;
[[nodiscard]] T* operator->() const;
BoxedObjectIterator& operator++();
BoxedObjectIterator operator++(int);
BoxedObjectIterator& operator--();
BoxedObjectIterator operator--(int);
[[nodiscard]] constexpr T& operator*() const MIJIN_NOEXCEPT;
[[nodiscard]] constexpr T* operator->() const MIJIN_NOEXCEPT;
constexpr BoxedObjectIterator& operator++() MIJIN_NOEXCEPT;
constexpr BoxedObjectIterator operator++(int) MIJIN_NOEXCEPT;
constexpr BoxedObjectIterator& operator--() MIJIN_NOEXCEPT;
constexpr BoxedObjectIterator operator--(int) MIJIN_NOEXCEPT;
[[nodiscard]] difference_type operator-(const BoxedObjectIterator& other) const { return box_ - other.box_; }
[[nodiscard]] BoxedObjectIterator operator+(difference_type diff) const;
[[nodiscard]] BoxedObjectIterator operator-(difference_type diff) const { return (*this + -diff); }
[[nodiscard]] constexpr difference_type operator-(const BoxedObjectIterator& other) const MIJIN_NOEXCEPT { return box_ - other.box_; }
[[nodiscard]] constexpr BoxedObjectIterator operator+(difference_type diff) const MIJIN_NOEXCEPT;
[[nodiscard]] constexpr BoxedObjectIterator operator-(difference_type diff) const MIJIN_NOEXCEPT { return (*this + -diff); }
[[nodiscard]] T& operator[](difference_type diff) const { return *(*this + diff); }
[[nodiscard]] T& operator[](difference_type diff) const MIJIN_NOEXCEPT { return *(*this + diff); }
};
template<typename T>
inline BoxedObjectIterator<T> operator+(std::iter_difference_t<T> diff, const BoxedObjectIterator<T>& iter) {
constexpr BoxedObjectIterator<T> operator+(std::iter_difference_t<T> diff, const BoxedObjectIterator<T>& iter) MIJIN_NOEXCEPT {
return iter + diff;
}
static_assert(std::random_access_iterator<BoxedObjectIterator<int>>);
@ -172,7 +190,7 @@ static_assert(std::random_access_iterator<BoxedObjectIterator<int>>);
//
template<typename T>
BoxedObjectIterator<T>& BoxedObjectIterator<T>::operator+=(difference_type diff)
constexpr BoxedObjectIterator<T>& BoxedObjectIterator<T>::operator+=(difference_type diff) MIJIN_NOEXCEPT
{
#if MIJIN_CHECKED_ITERATORS
MIJIN_ASSERT(diff <= (end_ - box_) && diff >= (box_ - start_), "BoxedObjectIterator::operator+=(): Attempt to iterate out of range.");
@ -182,7 +200,7 @@ BoxedObjectIterator<T>& BoxedObjectIterator<T>::operator+=(difference_type diff)
}
template<typename T>
T& BoxedObjectIterator<T>::operator*() const
constexpr T& BoxedObjectIterator<T>::operator*() const MIJIN_NOEXCEPT
{
#if MIJIN_CHECKED_ITERATORS
MIJIN_ASSERT(box_ >= start_ && box_ < end_, "BoxedObjectIterator::operator->(): Attempt to dereference out-of-range iterator.");
@ -191,7 +209,7 @@ T& BoxedObjectIterator<T>::operator*() const
}
template<typename T>
BoxedObjectIterator<T>& BoxedObjectIterator<T>::operator++()
constexpr BoxedObjectIterator<T>& BoxedObjectIterator<T>::operator++() MIJIN_NOEXCEPT
{
#if MIJIN_CHECKED_ITERATORS
MIJIN_ASSERT(box_ < end_, "BoxedObjectIterator::operator++(): Attempt to iterator past the end.");
@ -200,7 +218,7 @@ BoxedObjectIterator<T>& BoxedObjectIterator<T>::operator++()
}
template<typename T>
BoxedObjectIterator<T> BoxedObjectIterator<T>::operator++(int)
constexpr BoxedObjectIterator<T> BoxedObjectIterator<T>::operator++(int) MIJIN_NOEXCEPT
{
#if MIJIN_CHECKED_ITERATORS
MIJIN_ASSERT(box_ < end_, "BoxedObjectIterator::operator++(int): Attempt to iterator past the end.");
@ -211,7 +229,7 @@ BoxedObjectIterator<T> BoxedObjectIterator<T>::operator++(int)
}
template<typename T>
BoxedObjectIterator<T>& BoxedObjectIterator<T>::operator--()
constexpr BoxedObjectIterator<T>& BoxedObjectIterator<T>::operator--() MIJIN_NOEXCEPT
{
#if MIJIN_CHECKED_ITERATORS
MIJIN_ASSERT(box_ > start_, "BoxedObjectIterator::operator--(): Attempt to iterator past start.");
@ -220,7 +238,7 @@ BoxedObjectIterator<T>& BoxedObjectIterator<T>::operator--()
}
template<typename T>
BoxedObjectIterator<T> BoxedObjectIterator<T>::operator--(int)
constexpr BoxedObjectIterator<T> BoxedObjectIterator<T>::operator--(int) MIJIN_NOEXCEPT
{
#if MIJIN_CHECKED_ITERATORS
MIJIN_ASSERT(box_ > start_, "BoxedObjectIterator::operator--(int): Attempt to iterator past start.");
@ -231,7 +249,7 @@ BoxedObjectIterator<T> BoxedObjectIterator<T>::operator--(int)
}
template<typename T>
BoxedObjectIterator<T> BoxedObjectIterator<T>::operator+(difference_type diff) const
constexpr BoxedObjectIterator<T> BoxedObjectIterator<T>::operator+(difference_type diff) const MIJIN_NOEXCEPT
{
BoxedObjectIterator copy(*this);
copy += diff;

178
source/mijin/container/memory_view.hpp
View File

@ -5,10 +5,10 @@
#define MIJIN_CONTAINER_MEMORY_VIEW_HPP_INCLUDED 1
#include <bit>
#include <cstddef>
#include <span>
#include <string_view>
#include "../debug/assert.hpp"
#include "../util/traits.hpp"
#include "../internal/common.hpp"
namespace mijin
{
@ -25,60 +25,172 @@ namespace mijin
// public types
//
template<typename TBytes>
class MemoryViewBase
template<typename T>
concept MemoryViewable = requires(const T& object)
{
{ object.data() } -> std::convertible_to<const void*>;
{ object.byteSize() } -> std::convertible_to<std::size_t>;
};
template<typename T>
concept RWMemoryViewable = MemoryViewable<T> && requires(T& object)
{
{ object.data() } -> std::convertible_to<void*>;
};
template<typename TConcrete>
class MixinMemoryView
{
public:
static constexpr bool WRITABLE = requires(TConcrete& object) { { object.data() } -> std::convertible_to<void*>; };
template<typename T>
[[nodiscard]]
auto makeSpan();
template<typename T>
[[nodiscard]]
auto makeSpan() const;
template<typename TChar = char, typename TTraits = std::char_traits<TChar>>
[[nodiscard]]
std::basic_string_view<TChar, TTraits> makeStringView() const ;
template<typename T>
[[nodiscard]]
auto& dataAt(std::size_t offset) MIJIN_NOEXCEPT;
template<typename T>
[[nodiscard]]
auto& dataAt(std::size_t offset) const MIJIN_NOEXCEPT;
[[nodiscard]]
auto bytes() MIJIN_NOEXCEPT
{
using return_t = mijin::copy_const_t<std::remove_pointer_t<decltype(static_cast<TConcrete*>(this)->data())>, std::byte>;
return static_cast<return_t*>(static_cast<TConcrete*>(this)->data());
}
[[nodiscard]]
auto bytes() const MIJIN_NOEXCEPT
{
using return_t = mijin::copy_const_t<std::remove_pointer_t<decltype(static_cast<const TConcrete*>(this)->data())>, std::byte>;
return static_cast<return_t*>(static_cast<const TConcrete*>(this)->data());
}
private:
std::size_t byteSizeImpl() const MIJIN_NOEXCEPT
{
return static_cast<const TConcrete*>(this)->byteSize();
}
};
class MemoryView : public MixinMemoryView<MemoryView>
{
public:
using size_type = std::size_t;
private:
std::span<TBytes> bytes_;
void* data_ = nullptr;
std::size_t byteSize_ = 0;
public:
MemoryViewBase() noexcept = default;
MemoryViewBase(const MemoryViewBase&) noexcept = default;
MemoryViewBase(copy_const_t<TBytes, void>* data, std::size_t size) noexcept : bytes_(static_cast<TBytes*>(data), size) {}
MemoryView() noexcept = default;
MemoryView(const MemoryView&) = default;
MemoryView(void* data, std::size_t byteSize) MIJIN_NOEXCEPT : data_(data), byteSize_(byteSize) {}
template<typename T> requires(!std::is_const_v<T>)
MemoryView(std::span<T> span) MIJIN_NOEXCEPT : data_(span.data()), byteSize_(span.size_bytes()) {}
template<RWMemoryViewable T>
MemoryView(T& memoryViewable) MIJIN_NOEXCEPT : data_(memoryViewable.data()), byteSize_(memoryViewable.byteSize()) {}
MemoryViewBase& operator=(const MemoryViewBase&) noexcept = default;
MemoryView& operator=(const MemoryView&) = default;
[[nodiscard]] void* data() noexcept { return bytes_.data(); }
[[nodiscard]] const void* data() const noexcept { return bytes_.data(); }
[[nodiscard]] size_type byteSize() const noexcept { return bytes_.size(); }
[[nodiscard]] bool empty() const noexcept { return bytes_.empty(); }
[[nodiscard]]
void* data() const MIJIN_NOEXCEPT { return data_; }
template<typename T>
[[nodiscard]] std::span<T> makeSpan();
template<typename T>
[[nodiscard]] std::span<const T> makeSpan() const;
[[nodiscard]]
size_type byteSize() const MIJIN_NOEXCEPT { return byteSize_; }
};
class ConstMemoryView : public MixinMemoryView<ConstMemoryView>
{
public:
using size_type = std::size_t;
private:
const void* data_;
std::size_t byteSize_;
public:
ConstMemoryView() noexcept = default;
ConstMemoryView(const ConstMemoryView&) = default;
ConstMemoryView(void* data, std::size_t byteSize) MIJIN_NOEXCEPT : data_(data), byteSize_(byteSize) {}
template<typename T>
ConstMemoryView(std::span<T> span) MIJIN_NOEXCEPT : data_(span.data()), byteSize_(span.size_bytes()) {}
template<MemoryViewable T>
ConstMemoryView(const T& memoryViewable) MIJIN_NOEXCEPT : data_(memoryViewable.data()), byteSize_(memoryViewable.byteSize()) {}
ConstMemoryView& operator=(const ConstMemoryView& other) MIJIN_NOEXCEPT = default;
[[nodiscard]]
const void* data() const MIJIN_NOEXCEPT { return data_; }
[[nodiscard]]
size_type byteSize() const MIJIN_NOEXCEPT { return byteSize_; }
};
using MemoryView = MemoryViewBase<std::byte>;
using ConstMemoryView = MemoryViewBase<const std::byte>;
//
// public functions
//
template<typename TBytes>
template<typename TConcrete>
template<typename T>
std::span<T> MemoryViewBase<TBytes>::makeSpan()
auto MixinMemoryView<TConcrete>::makeSpan()
{
static_assert(!std::is_const_v<TBytes>, "Cannot create writable spans from const memory views.");
MIJIN_ASSERT(bytes_.size() % sizeof(T) == 0, "MemoryView cannot be divided into elements of this type.");
return {
std::bit_cast<T*>(bytes_.data()),
std::bit_cast<T*>(bytes_.data() + bytes_.size())
MIJIN_ASSERT(byteSizeImpl() % sizeof(T) == 0, "Buffer cannot be divided into elements of this type.");
using return_t = mijin::copy_const_t<decltype(*bytes()), T>;
return std::span<return_t>{
std::bit_cast<return_t*>(bytes()),
std::bit_cast<return_t*>(bytes() + byteSizeImpl())
};
}
template<typename TBytes>
template<typename TConcrete>
template<typename T>
std::span<const T> MemoryViewBase<TBytes>::makeSpan() const
auto MixinMemoryView<TConcrete>::makeSpan() const
{
MIJIN_ASSERT(bytes_.size() % sizeof(T) == 0, "MemoryView cannot be divided into elements of this type.");
return {
std::bit_cast<const T*>(bytes_.data()),
std::bit_cast<const T*>(bytes_.data() + bytes_.size())
MIJIN_ASSERT(byteSizeImpl() % sizeof(T) == 0, "Buffer cannot be divided into elements of this type.");
using return_t = mijin::copy_const_t<decltype(*bytes()), T>;
return std::span<return_t>{
std::bit_cast<return_t*>(bytes()),
std::bit_cast<return_t*>(bytes() + byteSizeImpl())
};
}
template<typename TConcrete>
template<typename TChar, typename TTraits>
std::basic_string_view<TChar, TTraits> MixinMemoryView<TConcrete>::makeStringView() const
{
MIJIN_ASSERT(byteSizeImpl() % sizeof(TChar) == 0, "Buffer cannot be divided into elements of this char type.");
return {std::bit_cast<const TChar*>(bytes()), byteSizeImpl() / sizeof(TChar)};
}
template<typename TConcrete>
template<typename T>
auto& MixinMemoryView<TConcrete>::dataAt(std::size_t offset) MIJIN_NOEXCEPT
{
MIJIN_ASSERT(offset % alignof(T) == 0, "Offset must be correctly aligned.");
MIJIN_ASSERT(offset + sizeof(T) < byteSizeImpl(), "Buffer access out-of-range.");
using return_t = mijin::copy_const_t<decltype(*bytes()), T>;
return *std::bit_cast<return_t*>(bytes().data() + offset);
}
template<typename TConcrete>
template<typename T>
auto& MixinMemoryView<TConcrete>::dataAt(std::size_t offset) const MIJIN_NOEXCEPT
{
MIJIN_ASSERT(offset % alignof(T) == 0, "Offset must be correctly aligned.");
MIJIN_ASSERT(offset + sizeof(T) < byteSizeImpl(), "Buffer access out-of-range.");
using return_t = mijin::copy_const_t<decltype(*bytes()), T>;
return *std::bit_cast<return_t*>(bytes().data() + offset);
}
} // namespace mijin
#endif // !defined(MIJIN_CONTAINER_MEMORY_VIEW_HPP_INCLUDED)

90
source/mijin/container/typeless_buffer.hpp
View File

@ -10,7 +10,9 @@
#include <span>
#include <string_view>
#include <vector>
#include "./memory_view.hpp"
#include "../debug/assert.hpp"
#include "../internal/common.hpp"
namespace mijin
{
@ -27,17 +29,26 @@ namespace mijin
// public types
//
template<typename T>
template<typename T, template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
class BufferView;
class TypelessBuffer
template<template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR>
class BaseTypelessBuffer : public MixinMemoryView<BaseTypelessBuffer<TAllocator>>
{
public:
using size_type = std::size_t;
private:
std::vector<std::byte> bytes_;
std::vector<std::byte, TAllocator<std::byte>> bytes_;
public:
auto operator<=>(const TypelessBuffer&) const noexcept = default;
BaseTypelessBuffer() noexcept = default;
BaseTypelessBuffer(const BaseTypelessBuffer&) = default;
BaseTypelessBuffer(BaseTypelessBuffer&&) = default;
explicit BaseTypelessBuffer(TAllocator<std::byte> allocator) : bytes_(std::move(allocator)) {}
BaseTypelessBuffer& operator=(const BaseTypelessBuffer&) = default;
BaseTypelessBuffer& operator=(BaseTypelessBuffer&&) = default;
auto operator<=>(const BaseTypelessBuffer&) const noexcept = default;
[[nodiscard]] void* data() noexcept { return bytes_.data(); }
[[nodiscard]] const void* data() const noexcept { return bytes_.data(); }
@ -50,26 +61,13 @@ public:
template<typename T>
[[nodiscard]] BufferView<T> makeBufferView() { return BufferView<T>(this); }
template<typename T>
[[nodiscard]] std::span<T> makeSpan();
template<typename T>
[[nodiscard]] std::span<const T> makeSpan() const;
template<typename TChar = char, typename TTraits = std::char_traits<TChar>>
[[nodiscard]] std::basic_string_view<TChar, TTraits> makeStringView() const ;
template<typename T>
void append(std::span<const T> data);
template<typename T>
[[nodiscard]] T& dataAt(size_type offset) MIJIN_NOEXCEPT;
template<typename T>
[[nodiscard]] const T& dataAt(size_type offset) const MIJIN_NOEXCEPT;
};
template<typename T>
using TypelessBuffer = BaseTypelessBuffer<>;
template<typename T, template<typename> typename TAllocator>
class BufferView
{
public:
@ -84,10 +82,10 @@ public:
using iterator = T*;
using const_iterator = const T*;
private:
class TypelessBuffer* buffer_ = nullptr;
class BaseTypelessBuffer<TAllocator>* buffer_ = nullptr;
public:
BufferView() = default;
explicit BufferView(class TypelessBuffer* buffer) : buffer_(buffer) {}
explicit BufferView(class BaseTypelessBuffer<TAllocator>* buffer) : buffer_(buffer) {}
BufferView(const BufferView&) = default;
BufferView& operator=(const BufferView&) = default;
@ -131,57 +129,13 @@ public:
// public functions
//
template<template<typename> typename TAllocator>
template<typename T>
std::span<T> TypelessBuffer::makeSpan()
{
MIJIN_ASSERT(bytes_.size() % sizeof(T) == 0, "Buffer cannot be divided into elements of this type.");
return {
std::bit_cast<T*>(bytes_.data()),
std::bit_cast<T*>(bytes_.data() + bytes_.size())
};
}
template<typename T>
std::span<const T> TypelessBuffer::makeSpan() const
{
MIJIN_ASSERT(bytes_.size() % sizeof(T) == 0, "Buffer cannot be divided into elements of this type.");
return {
std::bit_cast<const T*>(bytes_.data()),
std::bit_cast<const T*>(bytes_.data() + bytes_.size())
};
}
template<typename TChar, typename TTraits>
std::basic_string_view<TChar, TTraits> TypelessBuffer::makeStringView() const
{
MIJIN_ASSERT(bytes_.size() % sizeof(TChar) == 0, "Buffer cannot be divided into elements of this char type.");
return {std::bit_cast<const TChar*>(bytes_.data()), bytes_.size() / sizeof(TChar)};
}
template<typename T>
void TypelessBuffer::append(std::span<const T> data)
void BaseTypelessBuffer<TAllocator>::append(std::span<const T> data)
{
bytes_.resize(bytes_.size() + data.size_bytes());
std::memcpy(bytes_.data() + bytes_.size() - data.size_bytes(), data.data(), data.size_bytes());
}
template<typename T>
T& TypelessBuffer::dataAt(size_type offset) MIJIN_NOEXCEPT
{
MIJIN_ASSERT(offset % alignof(T) == 0, "Offset must be correctly aligned.");
MIJIN_ASSERT(offset + sizeof(T) < bytes_.size(), "Buffer access out-of-range.");
return *std::bit_cast<T*>(bytes_.data() + offset);
}
template<typename T>
const T& TypelessBuffer::dataAt(size_type offset) const MIJIN_NOEXCEPT
{
MIJIN_ASSERT(offset % alignof(T) == 0, "Offset must be correctly aligned.");
MIJIN_ASSERT(offset + sizeof(T) < bytes_.size(), "Buffer access out-of-range.");
return *std::bit_cast<const T*>(bytes_.data() + offset);
}
} // namespace mijin
#endif // !defined(MIJIN_CONTAINER_TYPELESS_BUFFER_HPP_INCLUDED)

14
source/mijin/container/vector_map.hpp
View File

@ -7,6 +7,7 @@
#include <algorithm>
#include <stdexcept>
#include <vector>
#include "./boxed_object.hpp"
#include "./optional.hpp"
@ -102,7 +103,7 @@ public:
}
};
template<typename TKey, typename TValue, typename TKeyAllocator = std::allocator<TKey>, typename TValueAllocator = std::allocator<TValue>>
template<typename TKey, typename TValue, typename TKeyAllocator = MIJIN_DEFAULT_ALLOCATOR<TKey>, typename TValueAllocator = MIJIN_DEFAULT_ALLOCATOR<TValue>>
class VectorMap
{
public:
@ -119,12 +120,17 @@ private:
std::vector<TKey, TKeyAllocator> keys_;
std::vector<TValue, TValueAllocator> values_;
public:
VectorMap() noexcept = default;
explicit VectorMap(TKeyAllocator keyAllocator = {})
MIJIN_NOEXCEPT_IF((std::is_nothrow_move_constructible_v<TKeyAllocator> && std::is_nothrow_constructible_v<TValueAllocator, const TKeyAllocator&>))
: keys_(std::move(keyAllocator)), values_(TValueAllocator(keys_.get_allocator())) {}
VectorMap(TKeyAllocator keyAllocator, TValueAllocator valueAllocator)
MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<TKeyAllocator> && std::is_nothrow_move_constructible_v<TValueAllocator>)
: keys_(std::move(keyAllocator)), values_(std::move(valueAllocator)) {}
VectorMap(const VectorMap&) = default;
VectorMap(VectorMap&&) MIJIN_NOEXCEPT = default;
VectorMap(VectorMap&&) = default;
VectorMap& operator=(const VectorMap&) = default;
VectorMap& operator=(VectorMap&&) MIJIN_NOEXCEPT = default;
VectorMap& operator=(VectorMap&&) = default;
auto operator<=>(const VectorMap& other) const noexcept = default;
TValue& operator[](const TKey& key)

6
source/mijin/debug/assert.hpp
View File

@ -99,10 +99,10 @@ if (!static_cast<bool>(condition)) \
MIJIN_FATAL("Debug assertion failed: " #condition "\nMessage: " msg); \
}
#else // MIJIN_DEBUG
#define MIJIN_ERROR(...)
#define MIJIN_ERROR(...) ((void)0)
#define MIJIN_FATAL(...) std::abort()
#define MIJIN_ASSERT(...)
#define MIJIN_ASSERT_FATAL(...)
#define MIJIN_ASSERT(...) ((void)0)
#define MIJIN_ASSERT_FATAL(...) ((void)0)
#endif // !MIJIN_DEBUG
//

145
source/mijin/debug/stacktrace.cpp
View File

@ -4,8 +4,9 @@
#include <optional>
#include <string>
#include "../detect.hpp"
#include "../util/string.hpp"
#if MIJIN_COMPILER == MIJIN_COMPILER_CLANG || MIJIN_COMPILER == MIJIN_COMPILER_GCC
#if MIJIN_TARGET_OS != MIJIN_OS_WINDOWS && (MIJIN_COMPILER == MIJIN_COMPILER_CLANG || MIJIN_COMPILER == MIJIN_COMPILER_GCC)
#define MIJIN_USE_LIBBACKTRACE 1
#else
#define MIJIN_USE_LIBBACKTRACE 0
@ -13,6 +14,14 @@
#if MIJIN_USE_LIBBACKTRACE
#include <backtrace.h>
#elif MIJIN_TARGET_OS == MIJIN_OS_WINDOWS
#include <array>
#include <cstddef>
#include <mutex>
#include <Windows.h>
#include <DbgHelp.h>
#include "../util/winundef.hpp"
#pragma comment(lib, "dbghelp")
#endif
@ -32,11 +41,15 @@ namespace
// internal types
//
#if MIJIN_USE_LIBBACKTRACE
struct BacktraceData
{
std::optional<std::string> error;
std::vector<Stackframe> stackframes;
};
#elif MIJIN_TARGET_OS == MIJIN_OS_WINDOWS
HANDLE gProcessHandle = nullptr;
#endif
//
// internal variables
@ -44,6 +57,11 @@ struct BacktraceData
thread_local Optional<Stacktrace> gCurrentExceptionStackTrace;
#if MIJIN_TARGET_OS == MIJIN_OS_WINDOWS
std::mutex gDbgHelpMutex;
bool gDbgHelpInitCalled = false;
#endif
//
// internal functions
//
@ -68,6 +86,49 @@ void backtraceErrorCallback(void* data, const char* msg, int /* errnum */)
}
thread_local backtrace_state* gBacktraceState = nullptr;
#elif MIJIN_TARGET_OS == MIJIN_OS_WINDOWS
void cleanupDbgHelp() MIJIN_NOEXCEPT
{
if (!SymCleanup(gProcessHandle))
{
[[maybe_unused]] const DWORD error = GetLastError();
MIJIN_ERROR("Error cleaning up DbgHelp.");
}
}
[[nodiscard]]
bool initDbgHelp() MIJIN_NOEXCEPT
{
if (gDbgHelpInitCalled)
{
return gProcessHandle != nullptr; // if init was successful, process handle is not null
}
gDbgHelpInitCalled = true;
SymSetOptions(SYMOPT_UNDNAME | SYMOPT_DEFERRED_LOADS);
HANDLE hCurrentProcess = GetCurrentProcess();
HANDLE hCopy = nullptr;
if (!DuplicateHandle(hCurrentProcess, hCurrentProcess, hCurrentProcess, &hCopy, 0, FALSE, DUPLICATE_SAME_ACCESS))
{
[[maybe_unused]] const DWORD error = GetLastError();
MIJIN_ERROR("Error duplicating process handle.");
return false;
}
if (!SymInitialize(hCopy, nullptr, true))
{
[[maybe_unused]] const DWORD error = GetLastError();
MIJIN_ERROR("Error initializing DbHelp.");
return false;
}
const int result = std::atexit(&cleanupDbgHelp);
MIJIN_ASSERT(result == 0, "Error registering DbgHelp cleanup handler.");
// only copy in the end so we can still figure out if initialization was successful
gProcessHandle = hCopy;
return true;
}
#endif // MIJIN_USE_LIBBACKTRACE
} // namespace
@ -98,9 +159,87 @@ Result<Stacktrace> captureStacktrace(unsigned skipFrames) MIJIN_NOEXCEPT
}
return Stacktrace(std::move(btData.stackframes));
#else // MIJIN_USE_LIBBACKTRACE
#elif MIJIN_TARGET_OS == MIJIN_OS_WINDOWS
if (!initDbgHelp())
{
return ResultError("error initializing DbgHelp");
}
const HANDLE hThread = GetCurrentThread();
CONTEXT context;
RtlCaptureContext(&context);
STACKFRAME64 stackFrame = {
.AddrPC = {
.Offset = context.Rip,
.Mode = AddrModeFlat
},
.AddrFrame = {
.Offset = context.Rbp,
.Mode = AddrModeFlat
},
.AddrStack = {
.Offset = context.Rsp,
.Mode = AddrModeFlat
}
};
++skipFrames; // always skip the first frame (the current function)
// for symbol info
DWORD64 displacement64 = 0;
static constexpr std::size_t SYMBOL_BUFFER_SIZE = sizeof(SYMBOL_INFO) + (MAX_SYM_NAME * sizeof(char));
std::array<std::byte, SYMBOL_BUFFER_SIZE> symbolBuffer alignas(SYMBOL_INFO);
SYMBOL_INFO& symbolInfo = *std::bit_cast<SYMBOL_INFO*>(symbolBuffer.data());
symbolInfo.SizeOfStruct = sizeof(SYMBOL_BUFFER_SIZE);
symbolInfo.MaxNameLen = MAX_SYM_NAME;
// for file and line info
DWORD displacement = 0;
IMAGEHLP_LINE64 line64;
line64.SizeOfStruct = sizeof(IMAGEHLP_LINE64);
std::vector<Stackframe> stackframes;
while (StackWalk64(
/* MachineType = */ IMAGE_FILE_MACHINE_AMD64,
/* hProcess = */ gProcessHandle,
/* hThread = */ hThread,
/* StackFrame = */ &stackFrame,
/* ContextRecord = */ &context,
/* ReadMemoryRoutine = */ nullptr,
/* FunctionTableAccessRoutine = */ &SymFunctionTableAccess64,
/* GetModuleBaseRoutine = */ &SymGetModuleBase64,
/* TranslateAddress = */ nullptr
))
{
if (skipFrames > 0)
{
--skipFrames;
continue;
}
Stackframe& frame = stackframes.emplace_back();
const DWORD64 baseAddress = SymGetModuleBase64(gProcessHandle, stackFrame.AddrPC.Offset);
const DWORD64 relativeAddress = stackFrame.AddrPC.Offset - baseAddress;
frame.address = std::bit_cast<void*>(relativeAddress);
if (SymFromAddr(gProcessHandle, stackFrame.AddrPC.Offset, &displacement64, &symbolInfo))
{
frame.function = symbolInfo.Name;
}
if (SymGetLineFromAddr64(gProcessHandle, stackFrame.AddrPC.Offset, &displacement, &line64))
{
frame.filename = line64.FileName;
frame.lineNumber = static_cast<int>(line64.LineNumber);
}
}
return Stacktrace(std::move(stackframes));
#else // MIJIN_USE_LIBBACKTRACE || (MIJIN_TARGET_OS == MIJIN_OS_WINDOWS)
(void) skipFrames;
return {}; // TODO
return ResultError("not implemented");
#endif // MIJIN_USE_LIBBACKTRACE
}

63
source/mijin/debug/stacktrace.hpp
View File

@ -5,6 +5,7 @@
#define MIJIN_DEBUG_STACKTRACE_HPP_INCLUDED 1
#include <cmath>
#include <format>
#include <iomanip>
#include <vector>
#if __has_include(<fmt/format.h>)
@ -87,6 +88,68 @@ TStream& operator<<(TStream& stream, const Stacktrace& stacktrace)
} // namespace mijin
template<typename TChar>
struct std::formatter<mijin::Stackframe, TChar>
{
using char_t = TChar;
template<typename TContext>
constexpr TContext::iterator parse(TContext& ctx)
{
auto it = ctx.begin();
auto end = ctx.end();
if (it != end && *it != MIJIN_SMART_QUOTE(char_t, '}'))
{
throw std::format_error("invalid format");
}
return it;
}
template<typename TContext>
TContext::iterator format(const mijin::Stackframe& stackframe, TContext& ctx) const
{
auto it = ctx.out();
it = std::format_to(it, MIJIN_SMART_QUOTE(char_t, "[{}] {}:{} in {}"), stackframe.address, stackframe.filename,
stackframe.lineNumber, mijin::demangleCPPIdentifier(stackframe.function.c_str()));
return it;
}
};
template<typename TChar>
struct std::formatter<mijin::Stacktrace, TChar>
{
using char_t = TChar;
template<class TContext>
constexpr TContext::iterator parse(TContext& ctx)
{
auto it = ctx.begin();
auto end = ctx.end();
if (it != end && *it != MIJIN_SMART_QUOTE(char_t, '}'))
{
throw std::format_error("invalid format");
}
return it;
}
template<typename TContext>
TContext::iterator format(const mijin::Stacktrace& stacktrace, TContext& ctx) const
{
const int numDigits = static_cast<int>(std::ceil(std::log10(stacktrace.getFrames().size())));
auto it = ctx.out();
it = std::format_to(it, MIJIN_SMART_QUOTE(char_t, "[{} frames]"), stacktrace.getFrames().size());
for (const auto& [idx, frame] : mijin::enumerate(stacktrace.getFrames()))
{
it = std::format_to(it, MIJIN_SMART_QUOTE(char_t, "\n #{:<{}} at {}"), idx, numDigits, frame);
}
return it;
}
};
#if __has_include(<fmt/format.h>)
template<>
struct fmt::formatter<mijin::Stackframe>

3
source/mijin/internal/common.hpp
View File

@ -1,4 +1,7 @@
#pragma once
#include "./config.hpp"
#include "./helpers.hpp"
#include "./exception.hpp"
#include "./version_support.hpp"

22
source/mijin/internal/config.hpp Normal file
View File

@ -0,0 +1,22 @@
#pragma once
#if !defined(MIJIN_INTERNAL_CONFIG_HPP_INCLUDED)
#define MIJIN_INTERNAL_CONFIG_HPP_INCLUDED 1
#define MIJIN_QUOTED_ACTUAL(x) #x
#define MIJIN_QUOTED(x) MIJIN_QUOTED_ACTUAL(x)
#if defined(MIJIN_CONFIG_HEADER)
#include MIJIN_QUOTED(MIJIN_CONFIG_HEADER)
#endif
#if !defined(MIJIN_DEFAULT_ALLOCATOR)
#define MIJIN_DEFAULT_ALLOCATOR std::allocator
#endif
#if !defined(MIJIN_DEFAULT_CHAR_TYPE)
#define MIJIN_DEFAULT_CHAR_TYPE char
#endif
#endif // !defined(MIJIN_INTERNAL_CONFIG_HPP_INCLUDED)

2
source/mijin/internal/exception.hpp
View File

@ -23,10 +23,12 @@
#else
#if defined(MIJIN_TEST_NO_NOEXCEPT) // only use for testing
#define MIJIN_NOEXCEPT
#define MIJIN_NOEXCEPT_IF(x)
#define MIJIN_THROWS
#define MIJIN_CONDITIONAL_NOEXCEPT(...)
#else
#define MIJIN_NOEXCEPT noexcept
#define MIJIN_NOEXCEPT_IF(x) noexcept(x)
#define MIJIN_THROWS noexcept
#define MIJIN_CONDITIONAL_NOEXCEPT(...) noexcept(__VA_ARGS__)
#endif

57
source/mijin/internal/helpers.hpp Normal file
View File

@ -0,0 +1,57 @@
#pragma once
#if !defined(MIJIN_INTERNAL_HELPERS_HPP_INCLUDED)
#define MIJIN_INTERNAL_HELPERS_HPP_INCLUDED 1
#include <type_traits>
#include "../util/traits.hpp"
#define MIJIN_IDENTITY(what) what
#define MIJIN_NULLIFY(what)
#define MIJIN_SMART_QUOTE(chr_type, text) \
[]<typename TChar__>(TChar__) consteval \
{ \
if constexpr (std::is_same_v<TChar__, char>) \
{ \
return text; \
} \
else if constexpr (std::is_same_v<TChar__, wchar_t>) \
{ \
return L ## text; \
} \
else if constexpr (std::is_same_v<TChar__, char8_t>) \
{ \
return u8 ## text; \
} \
else \
{ \
static_assert(::mijin::always_false_v<TChar__>, "Invalid char type."); \
} \
}(chr_type())
#define MIJIN_SMART_STRINGIFY(chr_type, text) MIJIN_SMART_QUOTE(chr_type, #text)
#define MIJIN_DEFINE_CHAR_VERSIONS_IMPL(type_name, prefix_a, prefix_b, prefix_c, set_args) \
prefix_a prefix_b(char) prefix_c \
using C ## type_name = Base ## type_name <set_args(char)>; \
\
prefix_a prefix_b(wchar_t) prefix_c \
using W ## type_name = Base ## type_name <set_args(wchar_t)>; \
\
prefix_a prefix_b(char8_t) prefix_c \
using U ## type_name = Base ## type_name <set_args(char8_t)>; \
\
using type_name = Base ## type_name<>;
#define MIJIN_DEFINE_CHAR_VERSIONS_TMPL(type_name, remaining_args, set_args) \
MIJIN_DEFINE_CHAR_VERSIONS_IMPL(type_name, template<, remaining_args, >, set_args)
#define MIJIN_DEFINE_CHAR_VERSIONS_CUSTOM(type_name, set_args) \
MIJIN_DEFINE_CHAR_VERSIONS_IMPL(type_name, , MIJIN_NULLIFY, , set_args)
#define MIJIN_DEFINE_CHAR_VERSIONS(type_name) \
MIJIN_DEFINE_CHAR_VERSIONS_CUSTOM(type_name, MIJIN_IDENTITY)
#endif // !defined(MIJIN_INTERNAL_HELPERS_HPP_INCLUDED)

19
source/mijin/internal/version_support.hpp Normal file
View File

@ -0,0 +1,19 @@
#pragma once
#if !defined(MIJIN_INTERNAL_VERSION_SUPPORT_HPP_INCLUDED)
#define MIJIN_INTERNAL_VERSION_SUPPORT_HPP_INCLUDED 1
#include "../detect.hpp"
#if MIJIN_COMPILER == MIJIN_COMPILER_CLANG
#pragma clang diagnostic ignored "-Wc++26-extensions"
#endif
#if defined(__cpp_deleted_function)
#define MIJIN_DELETE(reason) = delete(reason)
#else
#define MIJIN_DELETE(reason) = delete
#endif
#endif // !defined(MIJIN_INTERNAL_VERSION_SUPPORT_HPP_INCLUDED)

70
source/mijin/io/stream.cpp
View File

@ -197,76 +197,6 @@ StreamError Stream::getTotalLength(std::size_t& outLength)
return StreamError::SUCCESS;
}
StreamError Stream::readRest(TypelessBuffer& outBuffer)
{
// first try to allocate everything at once
std::size_t length = 0;
if (const StreamError lengthError = getTotalLength(length); lengthError == StreamError::SUCCESS)
{
MIJIN_ASSERT(getFeatures().tell, "How did you find the length if you cannot tell()?");
length -= tell();
outBuffer.resize(length);
if (const StreamError error = readRaw(outBuffer.data(), length); error != StreamError::SUCCESS)
{
return error;
}
return StreamError::SUCCESS;
}
// could not determine the size, read chunk-wise
static constexpr std::size_t CHUNK_SIZE = 4096;
std::array<std::byte, CHUNK_SIZE> chunk = {};
while (!isAtEnd())
{
std::size_t bytesRead = 0;
if (const StreamError error = readRaw(chunk, {.partial = true}, &bytesRead); error != StreamError::SUCCESS)
{
return error;
}
outBuffer.resize(outBuffer.byteSize() + bytesRead);
const std::span<std::byte> bufferBytes = outBuffer.makeSpan<std::byte>();
std::copy_n(chunk.begin(), bytesRead, bufferBytes.end() - static_cast<long>(bytesRead));
}
return StreamError::SUCCESS;
}
mijin::Task<StreamError> Stream::c_readRest(TypelessBuffer& outBuffer)
{
// first try to allocate everything at once
std::size_t length = 0;
if (StreamError lengthError = getTotalLength(length); lengthError == StreamError::SUCCESS)
{
MIJIN_ASSERT(getFeatures().tell, "How did you find the length if you cannot tell()?");
length -= tell();
outBuffer.resize(length);
if (StreamError error = co_await c_readRaw(outBuffer.data(), length); error != StreamError::SUCCESS)
{
co_return error;
}
co_return StreamError::SUCCESS;
}
// could not determine the size, read chunk-wise
static constexpr std::size_t CHUNK_SIZE = 4096;
std::array<std::byte, CHUNK_SIZE> chunk = {};
while (!isAtEnd())
{
std::size_t bytesRead = 0;
if (StreamError error = co_await c_readRaw(chunk, {.partial = true}, &bytesRead); error != StreamError::SUCCESS)
{
co_return error;
}
outBuffer.resize(outBuffer.byteSize() + bytesRead);
std::span<std::byte> bufferBytes = outBuffer.makeSpan<std::byte>();
std::copy_n(chunk.begin(), bytesRead, bufferBytes.end() - static_cast<long>(bytesRead));
}
co_return StreamError::SUCCESS;
}
StreamError Stream::readLine(std::string& outString)
{
MIJIN_ASSERT(getFeatures().readOptions.peek, "Stream needs to support peeking.");

102
source/mijin/io/stream.hpp
View File

@ -133,7 +133,8 @@ public:
return readRaw(&*range.begin(), bytes, {.partial = partial}, outBytesRead);
}
StreamError readRaw(TypelessBuffer& buffer, const ReadOptions& options = {})
template<template<typename> typename TAllocator>
StreamError readRaw(BaseTypelessBuffer<TAllocator>& buffer, const ReadOptions& options = {})
{
return readRaw(buffer.data(), buffer.byteSize(), options);
}
@ -145,7 +146,8 @@ public:
return c_readRaw(&*range.begin(), bytes, options, outBytesRead);
}
mijin::Task<StreamError> c_readRaw(TypelessBuffer& buffer, const ReadOptions& options = {})
template<template<typename> typename TAllocator>
mijin::Task<StreamError> c_readRaw(BaseTypelessBuffer<TAllocator>& buffer, const ReadOptions& options = {})
{
return c_readRaw(buffer.data(), buffer.byteSize(), options);
}
@ -272,17 +274,21 @@ public:
inline StreamError writeString(std::string_view str) { return writeBinaryString(str); }
StreamError getTotalLength(std::size_t& outLength);
StreamError readRest(TypelessBuffer& outBuffer);
mijin::Task<StreamError> c_readRest(TypelessBuffer& outBuffer);
template<template<typename> typename TAllocator>
StreamError readRest(BaseTypelessBuffer<TAllocator>& outBuffer);
template<template<typename> typename TAllocator>
mijin::Task<StreamError> c_readRest(BaseTypelessBuffer<TAllocator>& outBuffer);
StreamError readLine(std::string& outString);
mijin::Task<StreamError> c_readLine(std::string& outString);
template<typename TChar = char>
StreamError readAsString(std::basic_string<TChar>& outString);
template<typename TChar = char, typename TTraits = std::char_traits<TChar>, typename TAllocator = MIJIN_DEFAULT_ALLOCATOR<char>>
StreamError readAsString(std::basic_string<TChar, TTraits, TAllocator>& outString);
template<typename TChar = char>
mijin::Task<StreamError> c_readAsString(std::basic_string<TChar>& outString);
template<typename TChar = char, typename TTraits = std::char_traits<TChar>, typename TAllocator = MIJIN_DEFAULT_ALLOCATOR<char>>
mijin::Task<StreamError> c_readAsString(std::basic_string<TChar, TTraits, TAllocator>& outString);
StreamError writeText(std::string_view str)
{
@ -363,8 +369,80 @@ using StreamResult = ResultBase<TSuccess, StreamError>;
// public functions
//
template<typename TChar>
StreamError Stream::readAsString(std::basic_string<TChar>& outString)
template<template<typename> typename TAllocator>
StreamError Stream::readRest(BaseTypelessBuffer<TAllocator>& outBuffer)
{
// first try to allocate everything at once
std::size_t length = 0;
if (const StreamError lengthError = getTotalLength(length); lengthError == StreamError::SUCCESS)
{
MIJIN_ASSERT(getFeatures().tell, "How did you find the length if you cannot tell()?");
length -= tell();
outBuffer.resize(length);
if (const StreamError error = readRaw(outBuffer.data(), length); error != StreamError::SUCCESS)
{
return error;
}
return StreamError::SUCCESS;
}
// could not determine the size, read chunk-wise
static constexpr std::size_t CHUNK_SIZE = 4096;
std::array<std::byte, CHUNK_SIZE> chunk = {};
while (!isAtEnd())
{
std::size_t bytesRead = 0;
if (const StreamError error = readRaw(chunk, {.partial = true}, &bytesRead); error != StreamError::SUCCESS)
{
return error;
}
outBuffer.resize(outBuffer.byteSize() + bytesRead);
const std::span<std::byte> bufferBytes = outBuffer.template makeSpan<std::byte>();
std::copy_n(chunk.begin(), bytesRead, bufferBytes.end() - static_cast<long>(bytesRead));
}
return StreamError::SUCCESS;
}
template<template<typename> typename TAllocator>
mijin::Task<StreamError> Stream::c_readRest(BaseTypelessBuffer<TAllocator>& outBuffer)
{
// first try to allocate everything at once
std::size_t length = 0;
if (StreamError lengthError = getTotalLength(length); lengthError == StreamError::SUCCESS)
{
MIJIN_ASSERT(getFeatures().tell, "How did you find the length if you cannot tell()?");
length -= tell();
outBuffer.resize(length);
if (StreamError error = co_await c_readRaw(outBuffer.data(), length); error != StreamError::SUCCESS)
{
co_return error;
}
co_return StreamError::SUCCESS;
}
// could not determine the size, read chunk-wise
static constexpr std::size_t CHUNK_SIZE = 4096;
std::array<std::byte, CHUNK_SIZE> chunk = {};
while (!isAtEnd())
{
std::size_t bytesRead = 0;
if (StreamError error = co_await c_readRaw(chunk, {.partial = true}, &bytesRead); error != StreamError::SUCCESS)
{
co_return error;
}
outBuffer.resize(outBuffer.byteSize() + bytesRead);
std::span<std::byte> bufferBytes = outBuffer.template makeSpan<std::byte>();
std::copy_n(chunk.begin(), bytesRead, bufferBytes.end() - static_cast<long>(bytesRead));
}
co_return StreamError::SUCCESS;
}
template<typename TChar, typename TTraits, typename TAllocator>
StreamError Stream::readAsString(std::basic_string<TChar, TTraits, TAllocator>& outString)
{
static_assert(sizeof(TChar) == 1, "Can only read to 8-bit character types (char, unsigned char or char8_t");
@ -399,8 +477,8 @@ StreamError Stream::readAsString(std::basic_string<TChar>& outString)
return StreamError::SUCCESS;
}
template<typename TChar>
mijin::Task<StreamError> Stream::c_readAsString(std::basic_string<TChar>& outString)
template<typename TChar, typename TTraits, typename TAllocator>
mijin::Task<StreamError> Stream::c_readAsString(std::basic_string<TChar, TTraits, TAllocator>& outString)
{
static_assert(sizeof(TChar) == 1, "Can only read to 8-bit character types (char, unsigned char or char8_t");

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#pragma once
#if !defined(MIJIN_LOGGING_FORMATTING_HPP_INCLUDED)
#define MIJIN_LOGGING_FORMATTING_HPP_INCLUDED 1
#include <format>
#include <variant>
#include "./logger.hpp"
#include "../internal/common.hpp"
#include "../memory/dynamic_pointer.hpp"
#include "../memory/memutil.hpp"
#include "../memory/virtual_allocator.hpp"
#include "../util/annot.hpp"
#include "../util/ansi_colors.hpp"
#include "../util/concepts.hpp"
#include "../util/string.hpp"
namespace mijin
{
#define FORMATTER_COMMON_ARGS(chr_type) allocator_type_for<chr_type> TAllocator = MIJIN_DEFAULT_ALLOCATOR<chr_type>
template<typename TChar = MIJIN_DEFAULT_CHAR_TYPE, typename TTraits = std::char_traits<TChar>,
FORMATTER_COMMON_ARGS(TChar)>
class BaseLogFormatter
{
public:
using char_t = TChar;
using traits_t = TTraits;
using allocator_t = TAllocator;
using string_t = std::basic_string<char_t, traits_t, allocator_t>;
virtual ~BaseLogFormatter() noexcept = default;
virtual void format(const LogMessage& message, string_t& outFormatted) = 0;
};
template<typename TChar = MIJIN_DEFAULT_CHAR_TYPE, typename TTraits = std::char_traits<TChar>,
FORMATTER_COMMON_ARGS(TChar)>
class BaseSimpleLogFormatter : public BaseLogFormatter<TChar, TTraits, TAllocator>
{
public:
using char_t = TChar;
using traits_t = TTraits;
using allocator_t = TAllocator;
using base_t = BaseLogFormatter<char_t, traits_t, allocator_t>;
using typename base_t::string_t;
using string_view_t = std::basic_string_view<char_t, traits_t>;
private:
string_t mFormat;
string_t mFormatBuffer;
public:
explicit BaseSimpleLogFormatter(string_t format) MIJIN_NOEXCEPT : mFormat(std::move(format)), mFormatBuffer(mFormat.get_allocator()) {}
void format(const LogMessage& message, string_t& outFormatted) override;
private:
void formatAnsiSequence(const LogMessage& message, string_view_t ansiName, string_t& outFormatted);
};
#define FORMATTER_SET_ARGS(chr_type) chr_type, std::char_traits<chr_type>, TAllocator
MIJIN_DEFINE_CHAR_VERSIONS_TMPL(LogFormatter, FORMATTER_COMMON_ARGS, FORMATTER_SET_ARGS)
MIJIN_DEFINE_CHAR_VERSIONS_TMPL(SimpleLogFormatter, FORMATTER_COMMON_ARGS, FORMATTER_SET_ARGS)
#undef FORMATTER_COMMON_ARGS
#undef FORMATTER_SET_ARGS
#define MIJIN_FORMATTING_SINK_COMMON_ARGS(chr_type) \
typename TTraits = std::char_traits<chr_type>, \
template<typename> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR, \
deleter_type<BaseLogFormatter<chr_type, TTraits, TAllocator<chr_type>>> TDeleter \
= AllocatorDeleter<TAllocator<BaseLogFormatter<chr_type, TTraits, TAllocator<chr_type>>>>
#define MIJIN_FORMATTING_SINK_TMPL_ARGS_INIT \
typename TChar = MIJIN_DEFAULT_CHAR_TYPE, \
MIJIN_FORMATTING_SINK_COMMON_ARGS(TChar)
#define MIJIN_FORMATTING_SINK_TMP_ARG_NAMES TChar, TTraits, TAllocator, TDeleter
template<MIJIN_FORMATTING_SINK_TMPL_ARGS_INIT>
requires(allocator_type<TAllocator<TChar>>)
class BaseFormattingLogSink : public BaseLogSink<TChar>
{
public:
using base_t = BaseLogSink<TChar>;
using char_t = TChar;
using traits_t = TTraits;
using allocator_t = TAllocator<TChar>;
using formatter_t = BaseLogFormatter<char_t, traits_t, allocator_t>;
using formatter_deleter_t = TDeleter;
using formatter_ptr_t = DynamicPointer<formatter_t, formatter_deleter_t>;
using string_t = formatter_t::string_t;
using typename base_t::message_t;
private:
not_null_t<formatter_ptr_t> mFormatter;
string_t mBuffer;
public:
explicit BaseFormattingLogSink(not_null_t<formatter_ptr_t> formatter, allocator_t allocator = {})
MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<allocator_t>)
: mFormatter(std::move(formatter)), mBuffer(std::move(allocator))
{}
virtual void handleMessageFormatted(const message_t& message, const char_t* formatted) MIJIN_NOEXCEPT = 0;
void handleMessage(const message_t& message) noexcept override
{
mBuffer.clear();
mFormatter->format(message, mBuffer);
handleMessageFormatted(message, mBuffer.c_str());
}
};
#define SINK_SET_ARGS(chr_type) chr_type, std::char_traits<chr_type>, TAllocator, TDeleter
MIJIN_DEFINE_CHAR_VERSIONS_TMPL(FormattingLogSink, MIJIN_FORMATTING_SINK_COMMON_ARGS, SINK_SET_ARGS)
#undef SINK_SET_ARGS
template<typename TChar, typename TTraits, allocator_type_for<TChar> TAllocator>
void BaseSimpleLogFormatter<TChar, TTraits, TAllocator>::format(const LogMessage& message, string_t& outFormatted)
{
mFormatBuffer.clear();
for (auto pos = mFormat.begin(); pos != mFormat.end(); ++pos)
{
if (*pos == MIJIN_SMART_QUOTE(char_t, '{'))
{
++pos;
if (*pos == MIJIN_SMART_QUOTE(char_t, '{'))
{
// double {
outFormatted += MIJIN_SMART_QUOTE(char_t, '{');
continue;
}
const auto argStart = pos;
static const string_view_t endChars = MIJIN_SMART_QUOTE(char_t, ":}");
pos = std::find_first_of(pos, mFormat.end(), endChars.begin(), endChars.end());
MIJIN_ASSERT(pos != mFormat.end(), "Invalid format.");
const string_view_t argName(argStart, pos);
string_view_t argFormat;
if (*pos == ':')
{
const auto formatStart = pos;
pos = std::find(pos, mFormat.end(), MIJIN_SMART_QUOTE(char_t, '}'));
MIJIN_ASSERT(pos != mFormat.end(), "Invalid format.");
argFormat = string_view_t(formatStart, pos);
}
// small utility that uses the provided string buffer for storing the format string
auto formatInline = [&](const auto& value)
{
using type_t = std::decay_t<decltype(value)>;
// if there is no format, just directly print the value
if (argFormat.empty())
{
if constexpr (is_char_v<type_t>)
{
convertStringType(string_view_t(&value, 1), outFormatted);
}
else if constexpr (std::is_arithmetic_v<type_t>)
{
std::format_to(std::back_inserter(outFormatted), MIJIN_SMART_QUOTE(char_t, "{}"), value);
}
else if constexpr (is_string_v<type_t> || is_cstring_v<type_t>)
{
convertStringType(value, outFormatted);
}
else
{
static_assert(always_false_v<type_t>);
outFormatted += value;
}
return;
}
// first copy the format string + braces into the buffer
const auto formatStart = mFormatBuffer.size();
mFormatBuffer += '{';
mFormatBuffer += argFormat;
mFormatBuffer += '}';
const auto formatEnd = mFormatBuffer.size();
auto doFormatTo = [](string_t& string, string_view_t format, const auto& value)
{
if constexpr (std::is_same_v<char_t, char>)
{
std::vformat_to(std::back_inserter(string), format, std::make_format_args(value));
}
else if constexpr (std::is_same_v<char_t, wchar_t>)
{
std::vformat_to(std::back_inserter(string), format, std::make_wformat_args(value));
}
else
{
static_assert(always_false_v<char_t>, "Cannot format this char type.");
}
};
auto doFormat = [&](const auto& value)
{
auto format = string_view_t(mFormatBuffer).substr(formatStart, formatEnd - formatStart);
doFormatTo(outFormatted, format, value);
};
if constexpr (is_char_v<type_t> && !std::is_same_v<char_t, type_t>)
{
static_assert(always_false_v<type_t>, "TODO...");
}
else if constexpr ((is_string_v<type_t> || is_cstring_v<type_t>) && !std::is_same_v<str_char_type_t<type_t>, char_t>)
{
// different string type, needs to be converted
const auto convertedStart = mFormatBuffer.size();
convertStringType(value, mFormatBuffer);
const auto convertedEnd = mFormatBuffer.size();
// then we can format it
auto converted = string_view_t(mFormatBuffer).substr(convertedStart, mFormatBuffer.size() - convertedEnd);
doFormat(converted);
}
else
{
// nothing special
doFormat(value);
}
};
if (argName == MIJIN_SMART_QUOTE(char_t, "text"))
{
formatInline(message.text);
}
else if (argName == MIJIN_SMART_QUOTE(char_t, "channel"))
{
formatInline(message.channel->name);
}
else if (argName == MIJIN_SMART_QUOTE(char_t, "file"))
{
formatInline(message.sourceLocation.file_name());
}
else if (argName == MIJIN_SMART_QUOTE(char_t, "function"))
{
formatInline(message.sourceLocation.function_name());
}
else if (argName == MIJIN_SMART_QUOTE(char_t, "line"))
{
formatInline(message.sourceLocation.line());
}
else if (argName == MIJIN_SMART_QUOTE(char_t, "column"))
{
formatInline(message.sourceLocation.column());
}
else if (argName == MIJIN_SMART_QUOTE(char_t, "level"))
{
formatInline(message.level->name);
}
else if (argName == MIJIN_SMART_QUOTE(char_t, "ansi"))
{
formatAnsiSequence(message, argFormat.substr(1), outFormatted);
}
else
{
MIJIN_ERROR("Invalid format argument name.");
}
}
else
{
outFormatted += *pos;
}
}
}
template<typename TChar, typename TTraits, allocator_type_for<TChar> TAllocator>
void BaseSimpleLogFormatter<TChar, TTraits, TAllocator>::formatAnsiSequence(const LogMessage& message, string_view_t ansiName, string_t& outFormatted)
{
std::size_t numParts = 0;
const auto formatParts = splitFixed<4>(ansiName, ",", {}, &numParts);
outFormatted += MIJIN_SMART_QUOTE(char_t, "\033[");
for (std::size_t partIdx = 0; partIdx < numParts; ++partIdx)
{
const string_view_t& part = formatParts[partIdx];
if (partIdx > 0)
{
outFormatted += MIJIN_SMART_QUOTE(char_t, ',');
}
if (part == MIJIN_SMART_QUOTE(char_t, "reset"))
{
outFormatted += BaseAnsiFontEffects<char_t>::RESET;
}
else if (part == MIJIN_SMART_QUOTE(char_t, "level_color"))
{
const int levelValue = message.level->value;
if (levelValue < MIJIN_LOG_LEVEL_VALUE_VERBOSE)
{
outFormatted += BaseAnsiFontEffects<char_t>::FG_CYAN;
}
else if (levelValue < MIJIN_LOG_LEVEL_VALUE_INFO)
{
outFormatted += BaseAnsiFontEffects<char_t>::FG_WHITE;
}
else if (levelValue < MIJIN_LOG_LEVEL_VALUE_WARNING)
{
outFormatted += BaseAnsiFontEffects<char_t>::FG_BRIGHT_WHITE;
}
else if (levelValue < MIJIN_LOG_LEVEL_VALUE_ERROR)
{
outFormatted += BaseAnsiFontEffects<char_t>::FG_YELLOW;
}
else
{
outFormatted += BaseAnsiFontEffects<char_t>::FG_RED;
}
}
else
{
MIJIN_ERROR("Invalid format ansi font effect name.");
}
}
outFormatted += MIJIN_SMART_QUOTE(char_t, 'm');
}
} // namespace mijin
#endif // !defined(MIJIN_LOGGING_FORMATTING_HPP_INCLUDED)

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#pragma once
#if !defined(MIJIN_LOGGING_LOGGER_HPP_INCLUDED)
#define MIJIN_LOGGING_LOGGER_HPP_INCLUDED 1
#include <cstdint>
#include <format>
#include <source_location>
#include <string>
#include <vector>
#include "../internal/common.hpp"
#include "../util/annot.hpp"
namespace mijin
{
#if !defined(MIJIN_LOG_LEVEL_VALUE_DEBUG)
#define MIJIN_LOG_LEVEL_VALUE_DEBUG -1000
#endif
#if !defined(MIJIN_LOG_LEVEL_VALUE_VERBOSE)
#define MIJIN_LOG_LEVEL_VALUE_VERBOSE -500
#endif
#if !defined(MIJIN_LOG_LEVEL_VALUE_INFO)
#define MIJIN_LOG_LEVEL_VALUE_INFO 0
#endif
#if !defined(MIJIN_LOG_LEVEL_VALUE_WARNING)
#define MIJIN_LOG_LEVEL_VALUE_WARNING 500
#endif
#if !defined(MIJIN_LOG_LEVEL_VALUE_ERROR)
#define MIJIN_LOG_LEVEL_VALUE_ERROR 1000
#endif
#if !defined(MIJIN_FUNCNAME_GET_LOGGER)
#define MIJIN_FUNCNAME_GET_LOGGER mijin__getLogger__
#endif
#if !defined(MIJIN_FUNCNAME_MIN_LOG_LEVEL_COMPILE)
#define MIJIN_FUNCNAME_MIN_LOG_LEVEL_COMPILE mijin__getMinLogLevelCompile
#endif
#if !defined(MIJIN_NSNAME_LOG_LEVEL)
#define MIJIN_NSNAME_LOG_LEVEL mijin_log_level
#endif
#if !defined(MIJIN_NSNAME_LOG_CHANNEL)
#define MIJIN_NSNAME_LOG_CHANNEL mijin_log_channel
#endif
template<typename TChar = MIJIN_DEFAULT_CHAR_TYPE>
struct BaseLogLevel
{
using char_t = TChar;
const char_t* name;
int value;
explicit operator int() const MIJIN_NOEXCEPT { return value; }
auto operator<=>(const BaseLogLevel& other) const MIJIN_NOEXCEPT { return value <=> other.value; }
};
MIJIN_DEFINE_CHAR_VERSIONS(LogLevel)
template<typename TChar = MIJIN_DEFAULT_CHAR_TYPE>
struct BaseLogChannel
{
using char_t = TChar;
const char_t* name;
};
MIJIN_DEFINE_CHAR_VERSIONS(LogChannel)
template<typename TChar = MIJIN_DEFAULT_CHAR_TYPE>
struct BaseLogMessage
{
using char_t = TChar;
const char_t* text;
const BaseLogChannel<char_t>* channel;
const BaseLogLevel<char_t>* level;
std::source_location sourceLocation;
};
MIJIN_DEFINE_CHAR_VERSIONS(LogMessage)
template<typename TChar = MIJIN_DEFAULT_CHAR_TYPE>
class BaseLogSink
{
public:
using char_t = TChar;
using message_t = BaseLogMessage<char_t>;
virtual ~BaseLogSink() noexcept = default;
virtual void handleMessage(const message_t& message) MIJIN_NOEXCEPT = 0;
};
MIJIN_DEFINE_CHAR_VERSIONS(LogSink)
#define LOGGER_COMMON_ARGS(chr_type) template<typename T> typename TAllocator = MIJIN_DEFAULT_ALLOCATOR
template<typename TChar = MIJIN_DEFAULT_CHAR_TYPE, typename TTraits = std::char_traits<TChar>, LOGGER_COMMON_ARGS(TChar)>
class BaseLogger
{
public:
using char_t = TChar;
using traits_t = TTraits;
using allocator_t = TAllocator<char_t>;
using sink_t = BaseLogSink<char_t>;
using level_t = BaseLogLevel<char_t>;
using channel_t = BaseLogChannel<char_t>;
using message_t = BaseLogMessage<char_t>;
using string_t = std::basic_string<char_t, traits_t, allocator_t>;
private:
std::vector<sink_t*, TAllocator<sink_t*>> mSinks;
public:
explicit BaseLogger(TAllocator<sink_t*> allocator = {}) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<TAllocator<sink_t*>>)
: mSinks(std::move(allocator))
{}
BaseLogger(const BaseLogger&) = default;
BaseLogger(BaseLogger&&) = default;
BaseLogger& operator=(const BaseLogger&) = default;
BaseLogger& operator=(BaseLogger&&) = default;
void addSink(sink_t& sink)
{
mSinks.push_back(&sink);
}
void postMessage(const message_t& message) const MIJIN_NOEXCEPT
{
for (sink_t* sink: mSinks)
{
sink->handleMessage(message);
}
}
void log(const level_t& level, const channel_t& channel, std::source_location sourceLocation, const char_t* msg) const MIJIN_NOEXCEPT
{
postMessage({
.text = msg,
.channel = &channel,
.level = &level,
.sourceLocation = std::move(sourceLocation)
});
}
template<typename... TArgs>
void log(const level_t& level, const channel_t& channel, std::source_location sourceLocation,
std::basic_format_string<char_t, std::type_identity_t<TArgs>...> fmt, TArgs&& ... args) const
MIJIN_NOEXCEPT_IF(noexcept(std::declval<allocator_t>().allocate(1)))
{
string_t buffer(allocator_t(mSinks.get_allocator()));
std::format_to(std::back_inserter(buffer), fmt, std::forward<TArgs>(args)...);
log(level, channel, std::move(sourceLocation), buffer.c_str());
}
};
#define LOGGER_SET_ARGS(chr_type) chr_type, std::char_traits<chr_type>, TAllocator
MIJIN_DEFINE_CHAR_VERSIONS_TMPL(Logger, LOGGER_COMMON_ARGS, LOGGER_SET_ARGS)
#undef LOGGER_COMMON_ARGS
#undef LOGGER_SET_ARGS
#define MIJIN_DECLARE_LOG_CHANNEL_BASE(chr_type, cnlName) \
namespace MIJIN_NSNAME_LOG_CHANNEL \
{ \
extern const ::mijin::BaseLogChannel<chr_type> cnlName; \
}
#define MIJIN_DECLARE_LOG_CHANNEL(cnlName) MIJIN_DECLARE_LOG_CHANNEL_BASE(MIJIN_DEFAULT_CHAR_TYPE, cnlName)
#define MIJIN_DEFINE_LOG_CHANNEL_BASE(chr_type, cnlName) \
namespace MIJIN_NSNAME_LOG_CHANNEL \
{ \
const ::mijin::BaseLogChannel<chr_type> cnlName { \
.name = MIJIN_SMART_STRINGIFY(chr_type, cnlName) \
}; \
}
#define MIJIN_DEFINE_LOG_CHANNEL(cnlName) MIJIN_DEFINE_LOG_CHANNEL_BASE(MIJIN_DEFAULT_CHAR_TYPE, cnlName)
#define MIJIN_DEFINE_LOG_LEVEL_BASE(chr_type, lvlName, lvlValue) \
namespace MIJIN_NSNAME_LOG_LEVEL \
{ \
inline constexpr ::mijin::BaseLogLevel<chr_type> lvlName{ \
.name = MIJIN_SMART_STRINGIFY(chr_type, lvlName), \
.value = lvlValue \
}; \
}
#define MIJIN_DEFINE_LOG_LEVEL(lvlName, lvlValue) MIJIN_DEFINE_LOG_LEVEL_BASE(MIJIN_DEFAULT_CHAR_TYPE, lvlName, lvlValue)
#if defined(MIJIN_MIN_LOGLEVEL_COMPILE)
inline constexpr int MIN_LOG_LEVEL_COMPILE = static_cast<int>(MIJIN_MIN_LOGLEVEL_COMPILE);
#elif defined(MIJIN_DEBUG)
inline constexpr int MIN_LOG_LEVEL_COMPILE = MIJIN_LOG_LEVEL_VALUE_DEBUG;
#else
inline constexpr int MIN_LOG_LEVEL_COMPILE = MIJIN_LOG_LEVEL_VALUE_VERBOSE;
#endif
#define MIJIN_DEFINE_DEFAULT_LOG_LEVELS \
MIJIN_DEFINE_LOG_LEVEL(DEBUG, MIJIN_LOG_LEVEL_VALUE_DEBUG) \
MIJIN_DEFINE_LOG_LEVEL(VERBOSE, MIJIN_LOG_LEVEL_VALUE_VERBOSE) \
MIJIN_DEFINE_LOG_LEVEL(INFO, MIJIN_LOG_LEVEL_VALUE_INFO) \
MIJIN_DEFINE_LOG_LEVEL(WARNING, MIJIN_LOG_LEVEL_VALUE_WARNING) \
MIJIN_DEFINE_LOG_LEVEL(ERROR, MIJIN_LOG_LEVEL_VALUE_ERROR)
#define MIJIN_LOG_LEVEL_OBJECT(level) MIJIN_NSNAME_LOG_LEVEL::level
#define MIJIN_LOG_CHANNEL_OBJECT(channel) MIJIN_NSNAME_LOG_CHANNEL::channel
#define MIJIN_LOG_ALWAYS(level, channel, ...) MIJIN_FUNCNAME_GET_LOGGER().log( \
MIJIN_LOG_LEVEL_OBJECT(level), MIJIN_LOG_CHANNEL_OBJECT(channel), std::source_location::current(), __VA_ARGS__ \
)
#define MIJIN_LOG(level, channel, ...) \
if constexpr (MIJIN_LOG_LEVEL_OBJECT(level).value < MIJIN_FUNCNAME_MIN_LOG_LEVEL_COMPILE()) {} \
else MIJIN_LOG_ALWAYS(level, channel, __VA_ARGS__)
#define MIJIN_SET_CLASS_LOGGER(loggerExpr) \
const auto& MIJIN_FUNCNAME_GET_LOGGER() const noexcept \
{ \
return loggerExpr; \
}
#define MIJIN_SET_SCOPE_LOGGER(loggerExpr) \
auto MIJIN_FUNCNAME_GET_LOGGER = [&]() -> const auto& \
{ \
return loggerExpr; \
};
#define MIJIN_SET_CLASS_MIN_LOG_LEVEL_COMPILE(level) \
int MIJIN_FUNCNAME_MIN_LOG_LEVEL_COMPILE() MIJIN_NOEXCEPT \
{ \
return MIJIN_LOG_LEVEL_OBJECT(level).value; \
}
#define MIJIN_SET_SCOPE_MIN_LOG_LEVEL_COMPILE(level) \
auto MIJIN_FUNCNAME_MIN_LOG_LEVEL_COMPILE = []() -> int \
{ \
return MIJIN_LOG_LEVEL_OBJECT(level).value; \
};
} // namespace mijin
inline constexpr int MIJIN_FUNCNAME_MIN_LOG_LEVEL_COMPILE() MIJIN_NOEXCEPT
{
return ::mijin::MIN_LOG_LEVEL_COMPILE;
}
#endif // !defined(MIJIN_LOGGING_LOGGER_HPP_INCLUDED)

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#pragma once
#if !defined(MIJIN_LOGGING_STDIO_SINK_HPP_INCLUDED)
#define MIJIN_LOGGING_STDIO_SINK_HPP_INCLUDED 1
#include "./formatting.hpp"
#include "../util/traits.hpp"
namespace mijin
{
template<MIJIN_FORMATTING_SINK_TMPL_ARGS_INIT>
requires(allocator_type<TAllocator<TChar>>)
class BaseStdioSink : public BaseFormattingLogSink<MIJIN_FORMATTING_SINK_TMP_ARG_NAMES>
{
public:
using base_t = BaseFormattingLogSink<MIJIN_FORMATTING_SINK_TMP_ARG_NAMES>;
using typename base_t::char_t;
using typename base_t::allocator_t;
using typename base_t::formatter_ptr_t;
using typename base_t::message_t;
private:
int mMinStderrLevel = MIJIN_LOG_LEVEL_VALUE_WARNING;
public:
explicit BaseStdioSink(not_null_t<formatter_ptr_t> formatter, allocator_t allocator = {})
MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<allocator_t>)
: base_t(std::move(formatter), std::move(allocator)) {}
[[nodiscard]]
int getMinStderrLevel() const MIJIN_NOEXCEPT { return mMinStderrLevel; }
void setMinStderrLevel(int level) MIJIN_NOEXCEPT { mMinStderrLevel = level; }
void setMinStderrLevel(const BaseLogLevel<char_t>& level) MIJIN_NOEXCEPT { mMinStderrLevel = level.value; }
void handleMessageFormatted(const message_t& message, const char_t* formatted) MIJIN_NOEXCEPT override
{
FILE* stream = (message.level->value >= mMinStderrLevel) ? stderr : stdout;
if constexpr (std::is_same_v<char_t, char>)
{
std::fputs(formatted, stream);
std::fputc('\n', stream);
}
else if constexpr (std::is_same_v<char_t, wchar_t>)
{
std::fputws(formatted, stream);
std::fputwc(L'\n', stream);
}
else if constexpr (sizeof(char_t) == sizeof(char))
{
// char8_t etc.
std::fputs(std::bit_cast<const char*>(formatted), stream);
std::fputc('\n', stream);
}
else
{
static_assert(always_false_v<char_t>, "Character type not supported.");
}
std::fflush(stream);
}
};
#define SINK_SET_ARGS(chr_type) chr_type, std::char_traits<chr_type>, TAllocator, TDeleter
MIJIN_DEFINE_CHAR_VERSIONS_TMPL(StdioSink, MIJIN_FORMATTING_SINK_COMMON_ARGS, SINK_SET_ARGS)
#undef SINK_SET_ARGS
} // namespace mijin
#endif // !defined(MIJIN_LOGGING_STDIO_SINK_HPP_INCLUDED)

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#pragma once
#if !defined(MIJIN_MEMORY_DYNAMIC_POINTER_HPP_INCLUDED)
#define MIJIN_MEMORY_DYNAMIC_POINTER_HPP_INCLUDED 1
#include <bit>
#include <cstdint>
#include <utility>
#include "../internal/common.hpp"
#include "../memory/memutil.hpp"
#include "../util/concepts.hpp"
#include "../util/flag.hpp"
namespace mijin
{
MIJIN_DEFINE_FLAG(Owning);
template<typename T, deleter_type<T> TDeleter = std::default_delete<T>>
class DynamicPointer
{
public:
using pointer = T*;
using element_type = T;
using deleter_t = TDeleter;
private:
std::uintptr_t mData = 0;
[[no_unique_address]] TDeleter mDeleter;
public:
constexpr DynamicPointer(std::nullptr_t = nullptr) MIJIN_NOEXCEPT {}
DynamicPointer(const DynamicPointer&) = delete;
constexpr DynamicPointer(pointer ptr, Owning owning, TDeleter deleter = {}) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<TDeleter>)
: mData(std::bit_cast<std::uintptr_t>(ptr) | (owning ? 1 : 0)), mDeleter(std::move(deleter))
{
MIJIN_ASSERT((std::bit_cast<std::uintptr_t>(ptr) & 1) == 0, "Invalid address, DynamicPointer requires addresses to be divisible by two.");
}
template<typename TOther, typename TOtherDeleter> requires (std::is_constructible_v<TDeleter, TOtherDeleter&&>)
constexpr DynamicPointer(DynamicPointer<TOther, TOtherDeleter>&& other) MIJIN_NOEXCEPT_IF((std::is_nothrow_convertible_v<TOtherDeleter, TDeleter>))
: mData(std::exchange(other.mData, 0)), mDeleter(std::move(other.mDeleter)) {
MIJIN_ASSERT(other.mData == 0, "");
}
constexpr ~DynamicPointer() noexcept
{
reset();
}
DynamicPointer& operator=(const DynamicPointer&) = delete;
DynamicPointer& operator=(std::nullptr_t) MIJIN_NOEXCEPT
{
reset();
return *this;
}
template<typename TOther, typename TOtherDeleter> requires(std::is_assignable_v<TDeleter, TOtherDeleter>)
DynamicPointer& operator=(DynamicPointer<TOther, TOtherDeleter>&& other) MIJIN_NOEXCEPT_IF((std::is_nothrow_assignable_v<TDeleter, TOtherDeleter>))
{
if (this != &other)
{
reset();
mData = std::exchange(other.mData, 0);
mDeleter = std::move(other.mDeleter);
}
return *this;
}
template<typename TOther, typename TOtherDeleter> requires(std::equality_comparable_with<T, TOther>)
auto operator<=>(const DynamicPointer<TOther, TOtherDeleter>& other) MIJIN_NOEXCEPT
{
return mData <=> other.mData;
}
constexpr bool operator==(std::nullptr_t) const MIJIN_NOEXCEPT
{
return empty();
}
constexpr bool operator!=(std::nullptr_t) const MIJIN_NOEXCEPT
{
return !empty();
}
constexpr operator bool() const MIJIN_NOEXCEPT
{
return !empty();
}
constexpr bool operator!() const MIJIN_NOEXCEPT
{
return empty();
}
constexpr pointer operator->() const MIJIN_NOEXCEPT
{
return get();
}
constexpr element_type& operator*() const MIJIN_NOEXCEPT
{
return *get();
}
[[nodiscard]]
constexpr bool isOwning() const MIJIN_NOEXCEPT
{
return (mData & 1) == 1;
}
[[nodiscard]]
constexpr bool empty() const MIJIN_NOEXCEPT
{
return mData == 0;
}
[[nodiscard]]
constexpr pointer get() const MIJIN_NOEXCEPT
{
return std::bit_cast<pointer>(mData & ~1);
}
constexpr void reset(pointer ptr, Owning owning) MIJIN_NOEXCEPT
{
if (isOwning())
{
mDeleter(get());
}
mData = std::bit_cast<std::uintptr_t>(ptr) | (owning ? 1 : 0);
}
constexpr void reset() MIJIN_NOEXCEPT
{
reset(nullptr, Owning::NO);
}
[[nodiscard]]
pointer release() MIJIN_NOEXCEPT
{
return std::bit_cast<pointer>(std::exchange(mData, 0) & ~1);
}
template<typename TOther, deleter_type<TOther> TOtherDeleter>
friend class DynamicPointer;
};
template<typename T, typename TDeleter>
bool operator==(std::nullptr_t, const DynamicPointer<T, TDeleter>& pointer) MIJIN_NOEXCEPT
{
return pointer == nullptr;
}
template<typename T, typename TDeleter>
bool operator!=(std::nullptr_t, const DynamicPointer<T, TDeleter>& pointer) MIJIN_NOEXCEPT
{
return pointer != nullptr;
}
template<typename T, typename... TArgs>
DynamicPointer<T, std::default_delete<T>> makeDynamic(TArgs&&... args) MIJIN_NOEXCEPT_IF((std::is_nothrow_constructible_v<T, TArgs...>))
{
return DynamicPointer<T, std::default_delete<T>>(new T(std::forward<TArgs>(args)...), Owning::YES);
}
template<typename T, allocator_type_for<T> TAllocator, typename... TArgs>
DynamicPointer<T, AllocatorDeleter<TAllocator>> makeDynamicWithAllocator(TAllocator allocator, TArgs&&... args)
MIJIN_NOEXCEPT_IF((std::is_nothrow_constructible_v<T, TArgs...> && std::is_nothrow_move_constructible_v<TAllocator>))
{
T* obj = allocator.allocate(1);
if (obj != nullptr)
{
::new(obj) T(std::forward<TArgs>(args)...);
}
return DynamicPointer<T, AllocatorDeleter<TAllocator>>(obj, Owning::YES, AllocatorDeleter<TAllocator>(std::move(allocator)));
}
} // namespace mijin
#endif // !defined(MIJIN_MEMORY_DYNAMIC_POINTER_HPP_INCLUDED)

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#pragma once
#if !defined(MIJIN_MEMORY_MEMUTIL_HPP_INCLUDED)
#define MIJIN_MEMORY_MEMUTIL_HPP_INCLUDED 1
#include <memory>
#include "../internal/common.hpp"
namespace mijin
{
template<typename TAllocator>
class AllocatorDeleter
{
public:
using value_type = std::allocator_traits<TAllocator>::value_type;
using pointer = std::allocator_traits<TAllocator>::pointer;
private:
[[no_unique_address]] TAllocator allocator_;
public:
AllocatorDeleter() = default;
explicit AllocatorDeleter(TAllocator allocator) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<TAllocator>)
: allocator_(std::move(allocator)) {}
template<typename TOtherAllocator> requires (std::is_constructible_v<TAllocator, const TOtherAllocator&>)
AllocatorDeleter(const AllocatorDeleter<TOtherAllocator>& other)
MIJIN_NOEXCEPT_IF((std::is_nothrow_constructible_v<TAllocator, TOtherAllocator>))
: allocator_(other.allocator_) {}
template<typename TOtherAllocator> requires (std::is_constructible_v<TAllocator, TOtherAllocator&&>)
AllocatorDeleter(AllocatorDeleter<TOtherAllocator>&& other)
MIJIN_NOEXCEPT_IF((std::is_nothrow_constructible_v<TAllocator, TOtherAllocator&&>))
: allocator_(std::move(other.allocator_)) {}
template<typename TOtherAllocator> requires (std::is_assignable_v<TAllocator&, const TOtherAllocator&>)
AllocatorDeleter& operator=(const AllocatorDeleter<TOtherAllocator>& other)
MIJIN_NOEXCEPT_IF((std::is_nothrow_assignable_v<TAllocator&, const TOtherAllocator&>))
{
if (this != static_cast<const void*>(&other))
{
allocator_ = other.allocator_;
}
return *this;
}
template<typename TOtherAllocator> requires (std::is_assignable_v<TAllocator&, TOtherAllocator&&>)
AllocatorDeleter& operator=(AllocatorDeleter<TOtherAllocator>&& other)
MIJIN_NOEXCEPT_IF((std::is_nothrow_assignable_v<TAllocator&, TOtherAllocator&&>))
{
if (this != static_cast<const void*>(&other))
{
allocator_ = std::move(other.allocator_);
}
return *this;
}
void operator()(pointer ptr) MIJIN_NOEXCEPT_IF(noexcept(allocator_.deallocate(ptr, sizeof(value_type))))
{
allocator_.deallocate(ptr, sizeof(value_type));
}
template<typename TOtherAllocator>
friend class AllocatorDeleter;
};
template<typename T>
class AllocatorDeleter<std::allocator<T>>
{
public:
AllocatorDeleter() noexcept = default;
template<typename TOther>
AllocatorDeleter(std::allocator<TOther>) noexcept {}
template<typename TOther>
AllocatorDeleter(const AllocatorDeleter<std::allocator<TOther>>&) noexcept {}
template<typename TOther>
AllocatorDeleter& operator=(const AllocatorDeleter<std::allocator<TOther>>&) noexcept { return *this; }
void operator()(T* ptr) const MIJIN_NOEXCEPT
{
delete ptr;
}
};
} // namespace mijin
#endif // !defined(MIJIN_MEMORY_MEMUTIL_HPP_INCLUDED)

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#pragma once
#if !defined(MIJIN_MEMORY_STACK_ALLOCATOR_HPP_INCLUDED)
#define MIJIN_MEMORY_STACK_ALLOCATOR_HPP_INCLUDED 1
#include <memory>
#include <utility>
#include "../debug/assert.hpp"
#include "../internal/common.hpp"
#include "../util/align.hpp"
#include "../util/concepts.hpp"
#include "../util/traits.hpp"
#if !defined(MIJIN_STACK_ALLOCATOR_DEBUG)
#if defined(MIJIN_DEBUG)
#define MIJIN_STACK_ALLOCATOR_DEBUG 1
#else
#define MIJIN_STACK_ALLOCATOR_DEBUG 0
#endif
#endif // !defined(MIJIN_STACK_ALLOCATOR_DEBUG)
#if MIJIN_STACK_ALLOCATOR_DEBUG > 1
#include <print>
#include <unordered_map>
#include "../debug/stacktrace.hpp"
#endif
namespace mijin
{
template<typename TValue, typename TStackAllocator>
class StlStackAllocator
{
public:
using value_type = TValue;
private:
TStackAllocator* base_;
public:
explicit StlStackAllocator(TStackAllocator& base) MIJIN_NOEXCEPT : base_(&base) {}
template<typename TOtherValue>
StlStackAllocator(const StlStackAllocator<TOtherValue, TStackAllocator>& other) MIJIN_NOEXCEPT : base_(other.base_) {}
template<typename TOtherValue>
StlStackAllocator& operator=(const StlStackAllocator<TOtherValue, TStackAllocator>& other) MIJIN_NOEXCEPT
{
base_ = other.base_;
return *this;
}
auto operator<=>(const StlStackAllocator&) const noexcept = default;
[[nodiscard]]
TValue* allocate(std::size_t count) const
{
void* result = base_->allocate(alignof(TValue), count * sizeof(TValue));
#if MIJIN_STACK_ALLOCATOR_DEBUG == 1
++base_->numAllocations_;
#elif MIJIN_STACK_ALLOCATOR_DEBUG > 1
base_->activeAllocations_.emplace(result, captureStacktrace(1));
#endif
return static_cast<TValue*>(result);
}
void deallocate([[maybe_unused]] TValue* ptr, std::size_t /* count */) const MIJIN_NOEXCEPT
{
#if MIJIN_STACK_ALLOCATOR_DEBUG == 1
MIJIN_ASSERT(base_->numAllocations_ > 0, "Unbalanced allocations in stack allocators!");
--base_->numAllocations_;
#elif MIJIN_STACK_ALLOCATOR_DEBUG > 1
auto it = base_->activeAllocations_.find(ptr);
if (it != base_->activeAllocations_.end())
{
base_->activeAllocations_.erase(it);
}
else
{
MIJIN_ERROR("Deallocating invalid pointer from StackAllocator.");
}
#endif
}
template<typename TOtherValue, typename TOtherAllocator>
friend class StlStackAllocator;
};
namespace impl
{
struct StackAllocatorSnapshotData
{
struct ChunkSnapshot
{
std::size_t allocated;
};
std::size_t numChunks;
#if MIJIN_STACK_ALLOCATOR_DEBUG == 1
std::size_t numAllocations_ = 0;
#elif MIJIN_STACK_ALLOCATOR_DEBUG > 1
// just for debugging, so we don't care what memory this uses...
std::unordered_map<void*, Result<Stacktrace>> activeAllocations_;
#endif
ChunkSnapshot chunks[1]; // may be bigger than that
};
}
class StackAllocatorSnapshot
{
private:
impl::StackAllocatorSnapshotData* data = nullptr;
impl::StackAllocatorSnapshotData* operator->() const MIJIN_NOEXCEPT { return data; }
template<std::size_t chunkSize, template<typename> typename TBacking> requires (allocator_tmpl<TBacking>)
friend class StackAllocator;
};
template<typename TStackAllocator>
class StackAllocatorScope
{
private:
TStackAllocator* allocator_;
StackAllocatorSnapshot snapshot_;
public:
explicit StackAllocatorScope(TStackAllocator& allocator) : allocator_(&allocator), snapshot_(allocator_->createSnapshot()) {}
StackAllocatorScope(const StackAllocatorScope&) = delete;
StackAllocatorScope(StackAllocatorScope&&) = delete;
~StackAllocatorScope() MIJIN_NOEXCEPT
{
allocator_->restoreSnapshot(snapshot_);
}
StackAllocatorScope& operator=(const StackAllocatorScope&) = delete;
StackAllocatorScope& operator=(StackAllocatorScope&&) = delete;
};
template<std::size_t chunkSize = 4096, template<typename> typename TBacking = MIJIN_DEFAULT_ALLOCATOR> requires (allocator_tmpl<TBacking>)
class StackAllocator
{
public:
using backing_t = TBacking<void>;
static constexpr std::size_t ACTUAL_CHUNK_SIZE = chunkSize - sizeof(void*) - sizeof(std::size_t);
template<typename T>
using stl_allocator_t = StlStackAllocator<T, StackAllocator<chunkSize, TBacking>>;
private:
struct Chunk
{
std::array<std::byte, ACTUAL_CHUNK_SIZE> data;
Chunk* next;
std::size_t allocated;
};
[[no_unique_address]] TBacking<Chunk> backing_;
Chunk* firstChunk_ = nullptr;
#if MIJIN_STACK_ALLOCATOR_DEBUG == 1
std::size_t numAllocations_ = 0;
#elif MIJIN_STACK_ALLOCATOR_DEBUG > 1
// just for debugging, so we don't care what memory this uses...
std::unordered_map<void*, Result<Stacktrace>> activeAllocations_;
#endif
public:
StackAllocator() MIJIN_NOEXCEPT_IF(std::is_nothrow_default_constructible_v<backing_t>) = default;
explicit StackAllocator(backing_t backing) MIJIN_NOEXCEPT_IF((std::is_nothrow_constructible_v<TBacking<Chunk>, backing_t&&>))
: backing_(std::move(backing)) {}
StackAllocator(const StackAllocator&) = delete;
StackAllocator(StackAllocator&& other) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<TBacking<Chunk>>)
: firstChunk_(std::exchange(other.firstChunk_, nullptr)) {}
~StackAllocator() noexcept
{
Chunk* chunk = firstChunk_;
while (chunk != nullptr)
{
Chunk* nextChunk = firstChunk_->next;
backing_.deallocate(chunk, 1);
chunk = nextChunk;
}
}
StackAllocator& operator=(const StackAllocator&) = delete;
StackAllocator& operator=(StackAllocator&& other) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_assignable_v<TBacking<Chunk>>)
{
if (this != &other)
{
backing_ = std::move(other.backing_);
firstChunk_ = std::exchange(other.firstChunk_, nullptr);
}
return *this;
}
void* allocate(std::size_t alignment, std::size_t size)
{
// first check if this can ever fit
if (size > ACTUAL_CHUNK_SIZE)
{
return nullptr;
}
// then try to find space in the current chunks
for (Chunk* chunk = firstChunk_; chunk != nullptr; chunk = chunk->next)
{
const std::size_t remaining = ACTUAL_CHUNK_SIZE - chunk->allocated;
if (remaining < size)
{
continue;
}
std::byte* start = &chunk->data[chunk->allocated];
std::byte* pos = mijin::alignUp(start, alignment);
const std::ptrdiff_t alignmentBytes = pos - start;
const std::size_t combinedSize = size + alignmentBytes;
if (remaining < combinedSize)
{
continue;
}
chunk->allocated += combinedSize;
return pos;
}
// no free space in any chunk? allocate a new one
Chunk* newChunk = backing_.allocate(1);
if (newChunk == nullptr)
{
return nullptr;
}
initAndAddChunk(newChunk);
// now try with the new chunk
std::byte* start = newChunk->data.data();
std::byte* pos = mijin::alignUp(start, alignment);
const std::ptrdiff_t alignmentBytes = pos - start;
const std::size_t combinedSize = size + alignmentBytes;
// doesn't fit (due to alignment), time to give up
if (ACTUAL_CHUNK_SIZE < combinedSize)
{
return nullptr;
}
newChunk->allocated = combinedSize;
return pos;
}
void reset() noexcept
{
#if MIJIN_STACK_ALLOCATOR_DEBUG == 1
MIJIN_ASSERT(numAllocations_ == 0, "Missing deallocation in StackAllocator!");
#elif MIJIN_STACK_ALLOCATOR_DEBUG > 1
if (!activeAllocations_.empty())
{
std::println(stderr, "{} active allocations in StackAllocator when resetting!", activeAllocations_.size());
for (const auto& [ptr, stack] : activeAllocations_)
{
if (stack.isError())
{
std::println(stderr, "at {}, no stacktrace ({})", ptr, stack.getError().message);
}
else
{
std::println(stderr, "at 0x{}:\n{}", ptr, stack.getValue());
}
}
MIJIN_TRAP();
}
#endif
for (Chunk* chunk = firstChunk_; chunk != nullptr; chunk = chunk->next)
{
chunk->allocated = 0;
}
}
bool createChunks(std::size_t count)
{
if (count == 0)
{
return true;
}
Chunk* newChunks = backing_.allocate(count);
if (newChunks == nullptr)
{
return false;
}
// reverse so the chunks are chained from 0 to count (new chunks are inserted in front)
for (std::size_t pos = count; pos > 0; --pos)
{
initAndAddChunk(&newChunks[pos-1]);
}
return true;
}
template<typename T>
stl_allocator_t<T> makeStlAllocator() MIJIN_NOEXCEPT
{
return stl_allocator_t<T>(*this);
}
[[nodiscard]]
std::size_t getNumChunks() const MIJIN_NOEXCEPT
{
std::size_t num = 0;
for (Chunk* chunk = firstChunk_; chunk != nullptr; chunk = chunk->next)
{
++num;
}
return num;
}
[[nodiscard]]
StackAllocatorSnapshot createSnapshot()
{
if (firstChunk_ == nullptr)
{
return {};
}
using impl::StackAllocatorSnapshotData;
std::size_t numChunks = getNumChunks();
std::size_t snapshotSize = calcSnapshotSize(numChunks);
Chunk* prevFirst = firstChunk_;
StackAllocatorSnapshotData* snapshotData = static_cast<StackAllocatorSnapshotData*>(allocate(alignof(StackAllocatorSnapshotData), snapshotSize));
if (snapshotData == nullptr)
{
// couldn't allocate the snapshot
return {};
}
::new (snapshotData) StackAllocatorSnapshotData;
StackAllocatorSnapshot snapshot;
snapshot.data = snapshotData;
if (firstChunk_ != prevFirst)
{
// new chunk has been added, adjust the snapshot
// the snapshot must be inside the new chunk (but not necessarily at the very beginning, due to alignment)
MIJIN_ASSERT(static_cast<const void*>(snapshot.data) == alignUp(firstChunk_->data.data(), alignof(StackAllocatorSnapshot)), "Snapshot not where it was expected.");
// a chunk might be too small for the snapshot if we grow it (unlikely, but not impossible)
if (ACTUAL_CHUNK_SIZE - firstChunk_->allocated < MIJIN_STRIDEOF(StackAllocatorSnapshotData::ChunkSnapshot)) [[unlikely]]
{
firstChunk_->allocated = 0;
return {};
}
// looking good, adjust the numbers
++numChunks;
snapshotSize += MIJIN_STRIDEOF(StackAllocatorSnapshotData::ChunkSnapshot);
firstChunk_->allocated += MIJIN_STRIDEOF(StackAllocatorSnapshotData::ChunkSnapshot);
}
// now fill out the struct
snapshot->numChunks = numChunks;
#if MIJIN_STACK_ALLOCATOR_DEBUG == 1
snapshot->numAllocations_ = numAllocations_;
#elif MIJIN_STACK_ALLOCATOR_DEBUG > 1
// just for debugging, so we don't care what memory this uses...
snapshot->activeAllocations_ = activeAllocations_;
#endif
std::size_t pos = 0;
for (Chunk* chunk = firstChunk_; chunk != nullptr; chunk = chunk->next, ++pos)
{
snapshot->chunks[pos].allocated = chunk->allocated;
}
return snapshot;
}
void restoreSnapshot(StackAllocatorSnapshot snapshot) MIJIN_NOEXCEPT
{
if (snapshot.data == nullptr)
{
return;
}
const std::size_t numChunks = getNumChunks();
MIJIN_ASSERT_FATAL(snapshot->numChunks <= numChunks, "Snapshot contains more chunks than the allocator!");
#if MIJIN_STACK_ALLOCATOR_DEBUG == 1
MIJIN_ASSERT(snapshot->numAllocations_ >= numAllocations_, "Missing deallocation in StackAllocator!");
#elif MIJIN_STACK_ALLOCATOR_DEBUG > 1
// TODO: compare and print changes
unsigned numMismatches = 0;
for (const auto& [ptr, stack] : activeAllocations_)
{
if (snapshot->activeAllocations_.contains(ptr))
{
continue;
}
++numMismatches;
if (stack.isError())
{
std::println(stderr, "Missing deallocation at {}, no stacktrace ({})", ptr, stack.getError().message);
}
else
{
std::println(stderr, "Missing deallocation at 0x{}:\n{}", ptr, stack.getValue());
}
}
#if 0 // deallocating more than expected shouldn't be a problem
for (const auto& [ptr, stack] : snapshot->activeAllocations_)
{
if (activeAllocations_.contains(ptr))
{
continue;
}
++numMismatches;
if (stack.isError())
{
std::println(stderr, "Unexpected deallocation at {}, no stacktrace ({})", ptr, stack.getError().message);
}
else
{
std::println(stderr, "Unexpected deallocation at 0x{}:\n{}", ptr, stack.getValue());
}
}
#endif
if (numMismatches > 0)
{
std::println(stderr, "{} mismatched deallocations when restoring stack allocator snapshot.", numMismatches);
MIJIN_TRAP();
}
#endif
// if we allocated new chunks since the snapshot, these are completely empty now
const std::size_t emptyChunks = numChunks - snapshot->numChunks;
Chunk* chunk = firstChunk_;
for (std::size_t idx = 0; idx < emptyChunks; ++idx)
{
chunk->allocated = 0;
chunk = chunk->next;
}
// the other values are in the snapshot
for (std::size_t idx = 0; idx < snapshot->numChunks; ++idx)
{
chunk->allocated = snapshot->chunks[idx].allocated;
chunk = chunk->next;
}
MIJIN_ASSERT(chunk == nullptr, "Something didn't add up.");
// finally free the space for the snapshot itself
Chunk* snapshotChunk = findChunk(snapshot.data);
MIJIN_ASSERT_FATAL(snapshotChunk != nullptr, "Snapshot not in chunks?");
snapshotChunk->allocated -= calcSnapshotSize(snapshot->numChunks); // note: this might miss the alignment bytes of the snapshot, but that should be fine
snapshot.data->~StackAllocatorSnapshotData();
}
private:
void initAndAddChunk(Chunk* newChunk) noexcept
{
::new (newChunk) Chunk();
// put it in the front
newChunk->next = firstChunk_;
firstChunk_ = newChunk;
}
bool isInChunk(const void* address, const Chunk& chunk) const MIJIN_NOEXCEPT
{
const std::byte* asByte = static_cast<const std::byte*>(address);
return asByte >= chunk.data.data() && asByte < chunk.data.data() + ACTUAL_CHUNK_SIZE;
}
Chunk* findChunk(const void* address) const MIJIN_NOEXCEPT
{
for (Chunk* chunk = firstChunk_; chunk != nullptr; chunk = chunk->next)
{
if (isInChunk(address, *chunk))
{
return chunk;
}
}
return nullptr;
}
static std::size_t calcSnapshotSize(std::size_t numChunks) MIJIN_NOEXCEPT
{
return sizeof(impl::StackAllocatorSnapshotData) + ((numChunks - 1) * MIJIN_STRIDEOF(impl::StackAllocatorSnapshotData::ChunkSnapshot));
}
template<typename TValue, typename TStackAllocator>
friend class StlStackAllocator;
};
} // namespace mijin
#endif // !defined(MIJIN_MEMORY_STACK_ALLOCATOR_HPP_INCLUDED)

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#pragma once
#if !defined(MIJIN_MEMORY_VIRTUAL_ALLOCATOR_HPP_INCLUDED)
#define MIJIN_MEMORY_VIRTUAL_ALLOCATOR_HPP_INCLUDED 1
#include "../internal/common.hpp"
#include "../util/annot.hpp"
namespace mijin
{
template<typename T>
class VirtualAllocator
{
public:
virtual ~VirtualAllocator() noexcept = default;
[[nodiscard]]
virtual owner_t<T*> allocate(std::size_t count) noexcept;
virtual void deallocate(owner_t<T*> ptr, std::size_t count) noexcept;
};
template<typename T, typename TImpl>
class WrappedVirtualAllocator : public VirtualAllocator<T>
{
private:
[[no_unique_address]] TImpl mImpl;
public:
explicit constexpr WrappedVirtualAllocator(TImpl impl = {}) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<TImpl>)
: mImpl(std::move(impl)) {}
constexpr WrappedVirtualAllocator(const WrappedVirtualAllocator&) = default;
constexpr WrappedVirtualAllocator(WrappedVirtualAllocator&&) = default;
WrappedVirtualAllocator& operator=(const WrappedVirtualAllocator&) = default;
WrappedVirtualAllocator& operator=(WrappedVirtualAllocator&&) = default;
[[nodiscard]]
owner_t<T*> allocate(std::size_t count) noexcept override
{
return mImpl.allocate(count);
}
void deallocate(owner_t<T*> ptr, std::size_t count) noexcept override
{
mImpl.deallocate(ptr, count);
}
};
template<typename T>
WrappedVirtualAllocator<typename T::value_type, T> makeVirtualAllocator(T allocator) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<T>)
{
return WrappedVirtualAllocator<typename T::value_type, T>(std::move(allocator));
}
} // namespace mijin
#endif // !defined(MIJIN_MEMORY_VIRTUAL_ALLOCATOR_HPP_INCLUDED)

4
source/mijin/net/http.hpp
View File

@ -44,7 +44,7 @@ struct HTTPRequestOptions
{
std::string method = "GET";
std::multimap<std::string, std::string> headers;
TypelessBuffer body;
BaseTypelessBuffer<std::allocator> body;
};
struct HTTPResponse
@ -53,7 +53,7 @@ struct HTTPResponse
unsigned status;
std::string statusMessage;
std::multimap<std::string, std::string> headers;
TypelessBuffer body;
BaseTypelessBuffer<std::allocator> body;
};
class HTTPStream

6
source/mijin/net/url.hpp
View File

@ -12,7 +12,7 @@
namespace mijin
{
template<typename TChar, typename TTraits = std::char_traits<TChar>, typename TAllocator = std::allocator<TChar>>
template<typename TChar, typename TTraits = std::char_traits<TChar>, typename TAllocator = MIJIN_DEFAULT_ALLOCATOR<TChar>>
class URLBase
{
public:
@ -33,8 +33,8 @@ public:
constexpr URLBase(const URLBase&) = default;
constexpr URLBase(URLBase&&) MIJIN_NOEXCEPT = default;
constexpr URLBase(string_t base) MIJIN_NOEXCEPT : base_(std::move(base)) { parse(); }
constexpr URLBase(string_view_t base) : URLBase(string_t(base.begin(), base.end())) {}
constexpr URLBase(const TChar* base) : URLBase(string_t(base)) {}
constexpr URLBase(string_view_t base, TAllocator allocator = {}) : URLBase(string_t(base.begin(), base.end(), std::move(allocator))) {}
constexpr URLBase(const TChar* base, TAllocator allocator = {}) : URLBase(string_t(base, std::move(allocator))) {}
constexpr URLBase& operator=(const URLBase&) = default;
constexpr URLBase& operator=(URLBase&&) MIJIN_NOEXCEPT = default;

8
source/mijin/util/align.hpp
View File

@ -4,6 +4,8 @@
#if !defined(MIJIN_UTIL_ALIGN_HPP_INCLUDED)
#define MIJIN_UTIL_ALIGN_HPP_INCLUDED 1
#include <bit>
#include <cstdint>
#include "../internal/common.hpp"
namespace mijin
@ -18,6 +20,12 @@ constexpr T alignUp(T value, T alignTo) MIJIN_NOEXCEPT
return value;
}
template<typename T>
T* alignUp(T* pointer, std::uintptr_t alignTo) MIJIN_NOEXCEPT
{
return std::bit_cast<T*>(alignUp(std::bit_cast<std::uintptr_t>(pointer), alignTo));
}
#define MIJIN_STRIDEOF(T) mijin::alignUp(sizeof(T), alignof(T))
} // namespace mijin

179
source/mijin/util/annot.hpp Normal file
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@ -0,0 +1,179 @@
#pragma once
#if !defined(MIJIN_UTIL_ANNOT_HPP_INCLUDED)
#define MIJIN_UTIL_ANNOT_HPP_INCLUDED 1
#include <utility>
#include "../internal/common.hpp"
#include "../debug/assert.hpp"
#if !defined(__has_include)
#define __has_include(x) (false)
#endif
#if !defined(MIJIN_USE_GSL)
#if __has_include(<gsl/gsl>)
#define MIJIN_USE_GSL 1
#else
#define MIJIN_USE_GSL 0
#endif
#endif // !defined(MIJIN_USE_GSL)
#include <concepts>
#include "./concepts.hpp"
#if MIJIN_USE_GSL
#include <gsl/gsl>
#endif
namespace mijin
{
template<typename T>
concept nullable_type = !std::is_same_v<T, std::nullptr_t> && requires(T t) { t == nullptr; };
template<nullable_type T>
class NotNullable
{
private:
T base_;
public:
template<typename U> requires(std::is_same_v<T, U> && std::is_copy_constructible_v<T>)
constexpr NotNullable(U base) MIJIN_NOEXCEPT_IF(std::is_nothrow_copy_constructible_v<T>)
: base_(base)
{
MIJIN_ASSERT(base_ != nullptr, "Constructed non-nullable type with nullptr.");
}
// some compilers apparently need this since they are unable to do proper pattern matching ...
NotNullable(const NotNullable&) MIJIN_NOEXCEPT_IF(std::is_nothrow_copy_constructible_v<T>) = default;
NotNullable(NotNullable&&) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<T>) = default;
template<typename TOther> requires(std::is_constructible_v<T, const TOther&>)
constexpr NotNullable(const NotNullable<TOther>& other) MIJIN_NOEXCEPT_IF((std::is_nothrow_constructible_v<T, const TOther&>))
: base_(other.base_)
{
MIJIN_ASSERT(base_ != nullptr, "Constructed non-nullable type with nullptr.");
}
template<typename TOther> requires(std::is_constructible_v<T, TOther&&>)
constexpr NotNullable(NotNullable<TOther>&& other) MIJIN_NOEXCEPT_IF((std::is_nothrow_constructible_v<T, TOther&&>))
: base_(std::exchange(other.base_, nullptr))
{
MIJIN_ASSERT(base_ != nullptr, "Constructed non-nullable type with nullptr.");
}
template<typename TArg, typename... TArgs> requires(!std::is_same_v<TArg, std::nullptr_t>
&& (!std::is_same_v<TArg, T> && sizeof...(TArgs) == 0)
&& std::is_constructible_v<T, TArg&&, TArgs&&...>)
constexpr NotNullable(TArg&& arg, TArgs&&... args) MIJIN_NOEXCEPT_IF((std::is_nothrow_constructible_v<T, TArg&&, TArgs&&...>))
: base_(std::forward<TArg>(arg), std::forward<TArgs>(args)...)
{
MIJIN_ASSERT(base_ != nullptr, "Constructed non-nullable type with nullptr.");
}
constexpr NotNullable(T&& base) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<T>)
requires(std::is_move_constructible_v<T>)
: base_(std::move(base))
{
MIJIN_ASSERT(base_ != nullptr, "Constructed non-nullable type with nullptr.");
}
constexpr NotNullable(NotNullable&& other) MIJIN_NOEXCEPT_IF(std::is_nothrow_copy_constructible_v<T>)
requires(std::is_copy_constructible_v<T>)
: base_(other.base_)
{
MIJIN_ASSERT(base_ != nullptr, "Constructed non-nullable type with nullptr.");
}
constexpr NotNullable(NotNullable&& other) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<T>)
requires(std::is_move_constructible_v<T>)
: base_(std::exchange(other.base_, nullptr))
{
MIJIN_ASSERT(base_ != nullptr, "Constructed non-nullable type with nullptr.");
}
constexpr NotNullable(std::nullptr_t) MIJIN_DELETE("Type is not nullable.");
// some compilers apparently need this since they are unable to do proper pattern matching ...
NotNullable& operator=(const NotNullable&) MIJIN_NOEXCEPT_IF(std::is_nothrow_copy_constructible_v<T>) = default;
NotNullable& operator=(NotNullable&&) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_constructible_v<T>) = default;
constexpr NotNullable& operator=(const NotNullable& other) MIJIN_NOEXCEPT_IF(std::is_nothrow_copy_assignable_v<T>)
requires(std::is_copy_assignable_v<T>)
{
if (this != &other)
{
this->base_ = other.base_;
}
MIJIN_ASSERT(base_ != nullptr, "Assigned nullptr to non-nullable type."); // might still happen if the other type was moved from
return *this;
}
constexpr NotNullable& operator=(NotNullable&& other) MIJIN_NOEXCEPT_IF(std::is_nothrow_move_assignable_v<T>)
requires(std::is_move_assignable_v<T>)
{
if (this != &other)
{
this->base_ = std::exchange(other.base_, nullptr);
}
MIJIN_ASSERT(base_ != nullptr, "Assigned nullptr to non-nullable type."); // might still happen if the other type was moved from
return *this;
}
constexpr NotNullable& operator=(std::nullptr_t) MIJIN_DELETE("Type is not nullable.");
template<std::equality_comparable_with<T> TOther>
bool operator==(const NotNullable<TOther>& other) MIJIN_NOEXCEPT_IF(noexcept(std::declval<T>() == std::declval<TOther>()))
{
return base_ == other.base_;
}
template<std::equality_comparable_with<T> TOther>
bool operator!=(const NotNullable<TOther>& other) MIJIN_NOEXCEPT_IF(noexcept(std::declval<T>() != std::declval<TOther>()))
{
return base_ != other.base_;
}
template<nullable_type TOther> requires(std::equality_comparable_with<T, TOther> && !std::is_same_v<TOther, std::nullptr_t>)
bool operator==(const TOther& other) MIJIN_NOEXCEPT_IF(noexcept(std::declval<T>() == std::declval<TOther>()))
{
return base_ == other;
}
template<nullable_type TOther> requires(std::equality_comparable_with<T, TOther> && !std::is_same_v<TOther, std::nullptr_t>)
bool operator!=(const TOther& other) MIJIN_NOEXCEPT_IF(noexcept(std::declval<T>() != std::declval<TOther>()))
{
return base_ != other;
}
bool operator==(std::nullptr_t) MIJIN_DELETE("Type is not nullable.");
bool operator!=(std::nullptr_t) MIJIN_DELETE("Type is not nullable.");
constexpr operator const T&() const MIJIN_NOEXCEPT { return get(); }
constexpr operator std::nullptr_t() const MIJIN_DELETE("Type is not nullable.");
constexpr const T& operator->() const MIJIN_NOEXCEPT { return get(); }
constexpr decltype(auto) operator*() const MIJIN_NOEXCEPT_IF(noexcept(*get())) { return *get(); }
NotNullable& operator++() MIJIN_DELETE("Operator disabled for non-nullable types.");
NotNullable& operator--() MIJIN_DELETE("Operator disabled for non-nullable types.");
NotNullable operator++(int) MIJIN_DELETE("Operator disabled for non-nullable types.");
NotNullable operator--(int) MIJIN_DELETE("Operator disabled for non-nullable types.");
NotNullable& operator+=(std::ptrdiff_t) MIJIN_DELETE("Operator disabled for non-nullable types.");
NotNullable& operator-=(std::ptrdiff_t) MIJIN_DELETE("Operator disabled for non-nullable types.");
void operator[](std::ptrdiff_t) const MIJIN_DELETE("Operator disabled for non-nullable types.");
[[nodiscard]]
constexpr const T& get() const MIJIN_NOEXCEPT { return base_; }
template<nullable_type TOther>
friend class NotNullable;
};
#if MIJIN_USE_GSL
template<mijin::pointer_type T>
using owner_t = gsl::owner<T>;
#else
template<mijin::pointer_type T>
using owner_t = T;
#endif
template<typename T>
using not_null_t = NotNullable<T>;
}
#endif // !defined(MIJIN_UTIL_ANNOT_HPP_INCLUDED)

55
source/mijin/util/ansi_colors.hpp Normal file
View File

@ -0,0 +1,55 @@
#pragma once
#if !defined(MIJIN_UTIL_ANSI_COLORS_HPP_INCLUDED)
#define MIJIN_UTIL_ANSI_COLORS_HPP_INCLUDED 1
#include "../internal/common.hpp"
namespace mijin
{
template<typename TChar = MIJIN_DEFAULT_CHAR_TYPE>
struct BaseAnsiFontEffects
{
using char_t = TChar;
static constexpr const char_t* RESET = MIJIN_SMART_QUOTE(char_t, "0");
static constexpr const char_t* FG_BLACK = MIJIN_SMART_QUOTE(char_t, "30");
static constexpr const char_t* FG_RED = MIJIN_SMART_QUOTE(char_t, "31");
static constexpr const char_t* FG_GREEN = MIJIN_SMART_QUOTE(char_t, "32");
static constexpr const char_t* FG_YELLOW = MIJIN_SMART_QUOTE(char_t, "33");
static constexpr const char_t* FG_BLUE = MIJIN_SMART_QUOTE(char_t, "34");
static constexpr const char_t* FG_MAGENTA = MIJIN_SMART_QUOTE(char_t, "35");
static constexpr const char_t* FG_CYAN = MIJIN_SMART_QUOTE(char_t, "36");
static constexpr const char_t* FG_WHITE = MIJIN_SMART_QUOTE(char_t, "37");
static constexpr const char_t* FG_BRIGHT_BLACK = MIJIN_SMART_QUOTE(char_t, "90");
static constexpr const char_t* FG_BRIGHT_RED = MIJIN_SMART_QUOTE(char_t, "91");
static constexpr const char_t* FG_BRIGHT_GREEN = MIJIN_SMART_QUOTE(char_t, "92");
static constexpr const char_t* FG_BRIGHT_YELLOW = MIJIN_SMART_QUOTE(char_t, "93");
static constexpr const char_t* FG_BRIGHT_BLUE = MIJIN_SMART_QUOTE(char_t, "94");
static constexpr const char_t* FG_BRIGHT_MAGENTA = MIJIN_SMART_QUOTE(char_t, "95");
static constexpr const char_t* FG_BRIGHT_CYAN = MIJIN_SMART_QUOTE(char_t, "96");
static constexpr const char_t* FG_BRIGHT_WHITE = MIJIN_SMART_QUOTE(char_t, "97");
static constexpr const char_t* BG_BLACK = MIJIN_SMART_QUOTE(char_t, "40");
static constexpr const char_t* BG_RED = MIJIN_SMART_QUOTE(char_t, "41");
static constexpr const char_t* BG_GREEN = MIJIN_SMART_QUOTE(char_t, "42");
static constexpr const char_t* BG_YELLOW = MIJIN_SMART_QUOTE(char_t, "43");
static constexpr const char_t* BG_BLUE = MIJIN_SMART_QUOTE(char_t, "44");
static constexpr const char_t* BG_MAGENTA = MIJIN_SMART_QUOTE(char_t, "45");
static constexpr const char_t* BG_CYAN = MIJIN_SMART_QUOTE(char_t, "46");
static constexpr const char_t* BG_WHITE = MIJIN_SMART_QUOTE(char_t, "47");
static constexpr const char_t* BG_BRIGHT_BLACK = MIJIN_SMART_QUOTE(char_t, "100");
static constexpr const char_t* BG_BRIGHT_RED = MIJIN_SMART_QUOTE(char_t, "101");
static constexpr const char_t* BG_BRIGHT_GREEN = MIJIN_SMART_QUOTE(char_t, "102");
static constexpr const char_t* BG_BRIGHT_YELLOW = MIJIN_SMART_QUOTE(char_t, "103");
static constexpr const char_t* BG_BRIGHT_BLUE = MIJIN_SMART_QUOTE(char_t, "104");
static constexpr const char_t* BG_BRIGHT_MAGENTA = MIJIN_SMART_QUOTE(char_t, "105");
static constexpr const char_t* BG_BRIGHT_CYAN = MIJIN_SMART_QUOTE(char_t, "106");
static constexpr const char_t* BG_BRIGHT_WHITE = MIJIN_SMART_QUOTE(char_t, "107");
};
MIJIN_DEFINE_CHAR_VERSIONS(AnsiFontEffects)
}
#endif // !defined(MIJIN_UTIL_ANSI_COLORS_HPP_INCLUDED)

27
source/mijin/util/concepts.hpp
View File

@ -5,6 +5,7 @@
#define MIJIN_UTIL_CONCEPTS_HPP_INCLUDED 1
#include <type_traits>
#include "./traits.hpp"
namespace mijin
{
@ -39,6 +40,32 @@ concept pointer_type = std::is_pointer_v<T>;
template<typename T>
concept reference_type = std::is_reference_v<T>;
namespace impl
{
template<typename T>
using pointer_t = typename T::pointer;
}
template<typename T>
concept allocator_type = requires(T alloc, typename T::value_type value, detect_or_t<typename T::value_type*, impl::pointer_t, T> pointer, int count)
{
typename T::value_type;
{ alloc.allocate(count) } -> std::same_as<decltype(pointer)>;
{ alloc.deallocate(pointer, count) } -> std::same_as<void>;
} && !std::is_const_v<typename T::value_type> && !std::is_volatile_v<typename T::value_type>;
template<typename T, typename TOther>
concept allocator_type_for = allocator_type<T> && std::is_same_v<typename T::value_type, TOther>;
template<template<typename> typename T>
concept allocator_tmpl = allocator_type<T<int>>;
template<typename T, typename TData>
concept deleter_type = requires(T deleter, TData* ptr)
{
deleter(ptr);
};
//
// public functions
//

19
source/mijin/util/hash.hpp
View File

@ -6,6 +6,8 @@
#define MIJIN_UTIL_HASH_HPP_INCLUDED 1
#include <functional>
#include <tuple>
#include <utility>
namespace mijin
{
@ -16,4 +18,21 @@ inline void hashCombine(std::size_t& seed, const T& value, const THasher& hasher
}
}
template<typename... T>
struct std::hash<std::tuple<T...>>
{
std::size_t operator()(const std::tuple<T...>& tuple) const noexcept
{
return hashImpl(tuple, std::index_sequence_for<T...>());
}
template<std::size_t... indices>
std::size_t hashImpl(const std::tuple<T...>& tuple, std::index_sequence<indices...>) const noexcept
{
std::size_t result = 0;
(mijin::hashCombine(result, std::get<indices>(tuple)), ...);
return result;
}
};
#endif // MIJIN_UTIL_HASH_HPP_INCLUDED

42
source/mijin/util/misc.hpp Normal file
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@ -0,0 +1,42 @@
#pragma once
#if !defined(MIJIN_UTIL_MISC_HPP_INCLUDED)
#define MIJIN_UTIL_MISC_HPP_INCLUDED 1
#include <array>
#include <utility>
namespace mijin
{
//
// public functions
//
template<auto V, typename T>
constexpr decltype(auto) idValue(T&& value)
{
return std::forward<T>(value);
}
namespace impl
{
template<typename T, typename... TArgs>
struct ConstructArrayHelper
{
template<std::size_t... I>
static constexpr std::array<T, sizeof...(I)> construct(const TArgs&... args, std::index_sequence<I...>)
{
return {idValue<I>(T(args...))...};
}
};
}
template<typename T, std::size_t count, typename... TArgs>
constexpr std::array<T, count> constructArray(const TArgs&... args)
{
return impl::ConstructArrayHelper<T, TArgs...>::construct(args..., std::make_index_sequence<count>());
}
}
#endif // !defined(MIJIN_UTIL_MISC_HPP_INCLUDED)

39
source/mijin/util/os.cpp
View File

@ -5,11 +5,14 @@
#include "../debug/assert.hpp"
#if MIJIN_TARGET_OS == MIJIN_OS_LINUX
#include <bit>
#include <cstring>
#include <mutex>
#include <dlfcn.h>
#include <pthread.h>
#elif MIJIN_TARGET_OS == MIJIN_OS_WINDOWS
#include <array>
#include <malloc.h>
#include <windows.h>
#include "../util/winundef.hpp"
#endif
@ -139,4 +142,40 @@ std::string getExecutablePath() MIJIN_NOEXCEPT
#endif
}
void* alignedAlloc(std::size_t alignment, std::size_t size) MIJIN_NOEXCEPT
{
#if MIJIN_TARGET_OS == MIJIN_OS_WINDOWS
return _aligned_malloc(size, alignment);
#else
return std::aligned_alloc(alignment, size);
#endif
}
void* alignedRealloc(void* ptr, std::size_t alignment, std::size_t size) MIJIN_NOEXCEPT
{
#if MIJIN_TARGET_OS == MIJIN_OS_WINDOWS
return _aligned_realloc(ptr, size, alignment);
#else
void* newPtr = std::realloc(ptr, size);
if (newPtr == ptr || (std::bit_cast<std::uintptr_t>(newPtr) % alignment) == 0)
{
return newPtr;
}
// bad luck, have to copy a second time
void* newPtr2 = std::aligned_alloc(alignment, size);
std::memcpy(newPtr2, newPtr, size);
std::free(newPtr);
return newPtr2;
#endif
}
void alignedFree(void* ptr)
{
#if MIJIN_TARGET_OS == MIJIN_OS_WINDOWS
_aligned_free(ptr);
#else
std::free(ptr);
#endif
}
} // namespace mijin

4
source/mijin/util/os.hpp
View File

@ -81,6 +81,10 @@ void setCurrentThreadName(const char* threadName) MIJIN_NOEXCEPT;
[[nodiscard]] std::string makeLibraryFilename(std::string_view libraryName) MIJIN_NOEXCEPT;
[[nodiscard]] void* alignedAlloc(std::size_t alignment, std::size_t size) MIJIN_NOEXCEPT;
[[nodiscard]] void* alignedRealloc(void* ptr, std::size_t alignment, std::size_t size) MIJIN_NOEXCEPT;
void alignedFree(void* ptr);
SharedLibrary::~SharedLibrary() MIJIN_NOEXCEPT
{
close();

198
source/mijin/util/string.hpp
View File

@ -7,6 +7,9 @@
#include <algorithm>
#include <array>
#include <charconv>
#include <climits>
#include <cstdlib>
#include <cstring>
#include <iterator>
#include <limits>
#include <locale>
@ -17,6 +20,7 @@
#include "./iterators.hpp"
#include "../internal/common.hpp"
#include "../util/traits.hpp"
namespace mijin
{
@ -33,8 +37,56 @@ namespace mijin
// public traits
//
template<typename TString>
using char_type_t = decltype(std::string_view(std::declval<TString>()))::value_type;
template<typename T>
inline constexpr bool is_string_v = is_template_instance_v<std::basic_string, std::remove_cvref_t<T>>;
template<typename T>
concept std_string_type = is_string_v<T>;
template<typename T>
inline constexpr bool is_string_view_v = is_template_instance_v<std::basic_string_view, std::remove_cvref_t<T>>;
template<typename T>
concept std_string_view_type = is_string_view_v<T>;
template<typename T>
inline constexpr bool is_char_v = is_any_type_v<std::remove_cvref_t<T>, char, wchar_t, char8_t, char16_t, char32_t>;
template<typename T>
concept char_type = is_char_v<T>;
template<typename T>
inline constexpr bool is_cstring_v = std::is_pointer_v<T> && is_char_v<std::remove_pointer_t<T>>;
template<typename T>
concept cstring_type = is_cstring_v<T>;
template<typename T>
struct str_char_type
{
using type = void;
};
template<char_type T>
struct str_char_type<T*>
{
using type = std::remove_cvref_t<T>;
};
template<std_string_view_type T>
struct str_char_type<T>
{
using type = typename std::remove_cvref_t<T>::value_type;
};
template<std_string_type T>
struct str_char_type<T>
{
using type = typename std::remove_cvref_t<T>::value_type;
};
template<typename T>
using str_char_type_t = str_char_type<T>::type;
//
// public types
@ -255,7 +307,7 @@ template<typename TString>
[[nodiscard]]
auto trimPrefix(TString&& string)
{
return trimPrefix(string, detail::DEFAULT_TRIM_CHARS<char_type_t<TString>>);
return trimPrefix(string, detail::DEFAULT_TRIM_CHARS<str_char_type_t<TString>>);
}
template<typename TString, typename TChars>
@ -269,7 +321,7 @@ template<typename TString>
[[nodiscard]]
auto trimSuffix(TString&& string)
{
return trimSuffix(string, detail::DEFAULT_TRIM_CHARS<char_type_t<TString>>);
return trimSuffix(string, detail::DEFAULT_TRIM_CHARS<str_char_type_t<TString>>);
}
template<typename TString, typename TChars>
@ -283,7 +335,7 @@ template<typename TString>
[[nodiscard]]
auto trim(TString&& string)
{
return trim(string, detail::DEFAULT_TRIM_CHARS<char_type_t<TString>>);
return trim(string, detail::DEFAULT_TRIM_CHARS<str_char_type_t<TString>>);
}
template<typename TLeft, typename TRight>
@ -433,6 +485,142 @@ auto operator|(TIterable&& iterable, const Join& joiner)
{
return join(std::forward<TIterable>(iterable), joiner.delimiter);
}
} // namespace pipe
struct [[nodiscard]] ConvertCharTypeResult
{
unsigned numRead = 0;
unsigned numWritten = 0;
constexpr operator bool() const MIJIN_NOEXCEPT
{
return numRead != 0 || numWritten != 0;
}
constexpr bool operator !() const MIJIN_NOEXCEPT
{
return !static_cast<bool>(*this);
}
};
template<typename TFrom, typename TTo>
ConvertCharTypeResult convertCharType(const TFrom* chrFrom, std::size_t numFrom, TTo* outTo, std::size_t numTo, std::mbstate_t& mbstate) MIJIN_NOEXCEPT
{
if constexpr (std::is_same_v<TFrom, char>)
{
if constexpr (std::is_same_v<TTo, wchar_t>)
{
const std::size_t result = std::mbrtowc(outTo, chrFrom, numFrom, &mbstate);
if (result == static_cast<std::size_t>(-1))
{
return {};
}
return {
.numRead = static_cast<unsigned>(result),
.numWritten = 1
};
}
if constexpr (std::is_same_v<TTo, char8_t>)
{
}
}
if constexpr (std::is_same_v<TFrom, wchar_t>)
{
if constexpr (std::is_same_v<TTo, char>)
{
if (numTo < MB_CUR_MAX)
{
char tmpBuf[MB_LEN_MAX];
const ConvertCharTypeResult result = convertCharType(chrFrom, numFrom, tmpBuf, MB_LEN_MAX, mbstate);
if (result && result.numWritten <= numTo)
{
std::memcpy(outTo, tmpBuf, result.numWritten);
}
return result;
}
const std::size_t result = std::wcrtomb(outTo, *chrFrom, &mbstate);
if (result == static_cast<std::size_t>(-1))
{
return {};
}
return {
.numRead = 1,
.numWritten = static_cast<unsigned>(result)
};
}
if constexpr (std::is_same_v<TTo, char8_t>)
{
}
}
if constexpr (std::is_same_v<TFrom, char8_t>)
{
}
}
template<typename TFrom, typename TTo>
ConvertCharTypeResult convertCharType(const TFrom* chrFrom, std::size_t numFrom, TTo* outTo, std::size_t numTo) MIJIN_NOEXCEPT
{
std::mbstate_t mbstate;
return convertCharType(chrFrom, numFrom, outTo, numTo, mbstate);
}
template<typename TIterator>
struct [[nodiscard]] ConvertStringTypeResult
{
TIterator iterator;
bool success;
};
template<typename TTo, typename TFrom, typename TFromTraits, std::output_iterator<TTo> TIterator>
ConvertStringTypeResult<TIterator> convertStringType(std::basic_string_view<TFrom, TFromTraits> strFrom, TIterator outIterator)
{
TTo outBuffer[MB_LEN_MAX];
std::mbstate_t mbstate = {};
for (auto it = strFrom.begin(); it != strFrom.end();)
{
const std::size_t remaining = std::distance(it, strFrom.end());
const ConvertCharTypeResult result = convertCharType(&*it, remaining, outBuffer, MB_LEN_MAX, mbstate);
if (!result)
{
return {
.iterator = outIterator,
.success = false
};
}
for (unsigned pos = 0; pos < result.numWritten; ++pos)
{
*outIterator = outBuffer[pos];
++outIterator;
}
it = std::next(it, result.numRead);
}
return {
.iterator = outIterator,
.success = true
};
}
template<typename TFrom, typename TFromTraits, typename TTo, typename TToTraits, typename TToAllocator>
bool convertStringType(std::basic_string_view<TFrom, TFromTraits> strFrom, std::basic_string<TTo, TToTraits, TToAllocator>& outString)
{
if constexpr (std::is_same_v<TTo, TFrom>)
{
outString += strFrom;
return true;
}
else
{
return convertStringType<TTo>(strFrom, std::back_inserter(outString)).success;
}
}
template<typename TFrom, typename TTo, typename TToTraits, typename TToAllocator>
bool convertStringType(const TFrom* strFrom, std::basic_string<TTo, TToTraits, TToAllocator>& outString)
{
return convertStringType(std::basic_string_view<TFrom>(strFrom), outString);
}
} // namespace mijin

151
source/mijin/util/traits.hpp
View File

@ -21,6 +21,9 @@ namespace mijin
// public types
//
struct Type_; // use as typevar
struct Any_; // use as placeholder in templates
template<typename T>
struct always_false
{
@ -95,11 +98,88 @@ struct map_template {
using type_t = TTemplate<TPredicate<T>>;
};
template<typename T, typename... Types>
struct is_any_type : std::disjunction<std::is_same<T, Types>...> {};
template<template<typename...> typename TTemplate, typename TType>
struct is_template_instance : std::false_type {};
template<template<typename...> typename TTemplate, typename... TArgs>
struct is_template_instance<TTemplate, TTemplate<TArgs...>> : std::true_type {};
template<template<typename...> typename TTemplate, typename TType>
constexpr bool is_template_instance_v = is_template_instance<TTemplate, TType>::value;
namespace impl
{
template<template<typename...> typename TTemplate, typename... TArgsTTmpl>
struct tmpl_param_comparator
{
template<typename TTmpl, typename TInstance>
static constexpr bool compare_single = std::is_same_v<TTmpl, TInstance> or std::is_same_v<TTmpl, Any_>;
template<typename T>
struct matches : std::false_type {};
// original (which MSVC didn't like for some reason :/)
// template<typename... TArgsInstance>
// struct matches<TTemplate<TArgsInstance...>> : std::bool_constant<(compare_single<TArgsTTmpl, TArgsInstance> && ...)> {};
template<template<typename...> typename TOtherTemplate, typename... TArgsInstance> requires(is_template_instance_v<TTemplate, TOtherTemplate<TArgsInstance...>>)
struct matches<TOtherTemplate<TArgsInstance...>> : std::bool_constant<(compare_single<TArgsTTmpl, TArgsInstance> && ...)> {};
template<typename T>
using matches_t = matches<T>;
};
}
template<typename TTemplate, typename TType>
struct match_template_type : std::false_type {};
template<template<typename...> typename TTemplate, typename TType, typename... TArgs>
struct match_template_type<TTemplate<TArgs...>, TType> : impl::tmpl_param_comparator<TTemplate, TArgs...>::template matches_t<TType> {};
template<typename TTemplate, typename TType>
constexpr bool match_template_type_v = match_template_type<TTemplate, TType>::value;
// similar to std::is_same, but allows placeholders
// - is_type_or_impl<some_tmpl<Type_>, some_type> resolves to some_tmpl<some_type>
// - is_type_or_impl<some_tmpl<Any_, int>, some_type> checks if some_type is an instance of some_tmpl with int as 2nd parameter
template<typename TMatch, typename TConcrete>
struct type_matches
{
using type = std::is_same<TMatch, TConcrete>;
};
template<template<typename> typename TTmplMatch, typename TConcrete>
struct type_matches<TTmplMatch<Type_>, TConcrete>
{
using type = TTmplMatch<TConcrete>;
};
template<template<typename...> typename TTmplMatch, typename TConcrete, typename... TArgs>
struct type_matches<TTmplMatch<TArgs...>, TConcrete>
{
using type = match_template_type<TTmplMatch<TArgs...>, TConcrete>;
};
template<typename TMatch, typename TConcrete>
using type_matches_t = type_matches<TMatch, TConcrete>::type;
template<typename TMatch, typename TConcrete>
inline constexpr bool type_matches_v = type_matches_t<TMatch, TConcrete>::value;
template<typename TConcrete, typename... TMatches>
struct is_any_type : std::disjunction<std::is_same<TConcrete, TMatches>...> {};
template<typename TConcrete, typename... TMatches>
static constexpr bool is_any_type_v = is_any_type<TConcrete, TMatches...>::value;
template<typename TConcrete, typename... TMatches>
struct match_any_type : std::disjunction<type_matches_t<TMatches, TConcrete>...> {};
template<typename TConcrete, typename... TMatches>
static constexpr bool match_any_type_v = match_any_type<TConcrete, TMatches...>::value;
template<typename T, typename... Types>
static constexpr bool is_any_type_v = is_any_type<T, Types...>::value;
concept union_type = match_any_type_v<T, Types...>;
template<typename TElement, typename TCollection>
struct is_type_member;
@ -139,14 +219,39 @@ struct TypeAtHelper<0, TArg, TArgs...>
template<std::size_t I, typename... TArgs>
using type_at_t = TypeAtHelper<I, TArgs...>::type_t;
template<template<typename...> typename TTemplate, typename TType>
struct is_template_instance : std::false_type {};
template<typename TDefault, template<typename...> typename TOper, typename... TArgs>
struct detect_or
{
using type = TDefault;
static constexpr bool detected = false;
};
template<template<typename...> typename TTemplate, typename... TArgs>
struct is_template_instance<TTemplate, TTemplate<TArgs...>> : std::true_type {};
template<typename TDefault, template<typename...> typename TOper, typename... TArgs>
requires requires { typename TOper<TArgs...>; }
struct detect_or<TDefault, TOper, TArgs...>
{
using type = TOper<TArgs...>;
static constexpr bool detected = true;
};
template<typename TDefault, template<typename...> typename TOper, typename... TArgs>
using detect_or_t = detect_or<TDefault, TOper, TArgs...>::type;
template<template<typename...> typename TTemplate, typename TType>
constexpr bool is_template_instance_v = is_template_instance<TTemplate, TType>::value;
struct empty_type {};
template<typename T, bool enable>
struct optional_base
{
using type = T;
};
template<typename T>
struct optional_base<T, false>
{
using type = empty_type;
};
template<typename T, bool enable>
using optional_base_t = optional_base<T, enable>::type;
//
// public functions
@ -158,6 +263,34 @@ decltype(auto) delayEvaluation(TType&& value)
return static_cast<TType&&>(value);
}
#define MIJIN_STATIC_TESTS 1
#if MIJIN_STATIC_TESTS
namespace test
{
template<typename T, typename U>
struct MyTemplate {};
static_assert(match_template_type_v<MyTemplate<Any_, int>, MyTemplate<int, int>>);
static_assert(match_template_type_v<MyTemplate<Any_, Any_>, MyTemplate<int, int>>);
static_assert(type_matches_v<MyTemplate<Any_, int>, MyTemplate<int, int>>);
static_assert(type_matches_v<MyTemplate<Any_, Any_>, MyTemplate<int, int>>);
static_assert(!type_matches_v<MyTemplate<double, int>, MyTemplate<int, int>>);
static_assert(type_matches_v<MyTemplate<Any_, Any_>, MyTemplate<int, double>>);
static_assert(type_matches_v<std::is_pointer<Type_>, void*>);
static_assert(union_type<int, int>);
static_assert(!union_type<int>);
static_assert(!union_type<int, double>);
static_assert(union_type<MyTemplate<int, int>, MyTemplate<int, int>>);
static_assert(union_type<MyTemplate<int, int>, MyTemplate<Any_, int>>);
static_assert(union_type<MyTemplate<int, int>, MyTemplate<Any_, Any_>>);
static_assert(union_type<MyTemplate<int, int>, MyTemplate<double, double>, MyTemplate<Any_, Any_>>);
static_assert(!union_type<int*, int>);
static_assert(union_type<int*, std::is_pointer<Type_>>);
static_assert(!union_type<int, std::is_pointer<Type_>>);
}
#endif
} // namespace mijin
#endif // !defined(MIJIN_UTIL_TRAITS_HPP_INCLUDED)

4
source/mijin/util/winundef.hpp
View File

@ -22,3 +22,7 @@
#if defined(RELATIVE)
#undef RELATIVE
#endif
#if defined(DEBUG)
#undef DEBUG
#endif

4
source/mijin/virtual_filesystem/memory.cpp
View File

@ -139,7 +139,7 @@ detail::MemoryFolder* MemoryFileSystemAdapter::findFolder(const fs::path& path,
return folder;
}
FileInfo MemoryFileSystemAdapter::folderInfo(const fs::path& path, const detail::MemoryFolder& folder) const noexcept
FileInfo MemoryFileSystemAdapter::folderInfo(const fs::path& path, const detail::MemoryFolder& folder) const MIJIN_NOEXCEPT
{
return {
.path = path,
@ -149,7 +149,7 @@ FileInfo MemoryFileSystemAdapter::folderInfo(const fs::path& path, const detail:
};
}
FileInfo MemoryFileSystemAdapter::fileInfo(const fs::path& path, const detail::MemoryFile& file) const noexcept
FileInfo MemoryFileSystemAdapter::fileInfo(const fs::path& path, const detail::MemoryFile& file) const MIJIN_NOEXCEPT
{
return {
.path = path,

4
source/mijin/virtual_filesystem/memory.hpp
View File

@ -21,8 +21,8 @@ struct MemoryFile
};
struct MemoryFolder
{
VectorMap<std::string, MemoryFile> files;
VectorMap<std::string, MemoryFolder> folders;
VectorMap<std::string, MemoryFile, std::allocator<std::string>, std::allocator<MemoryFile>> files; // TODO: make the FS library allocator aware
VectorMap<std::string, MemoryFolder, std::allocator<std::string>, std::allocator<MemoryFolder>> folders;
};
}

5
source/mijin/virtual_filesystem/stacked.cpp
View File

@ -39,10 +39,15 @@ fs::path StackedFileSystemAdapter::getHomeFolder()
#if MIJIN_COMPILER == MIJIN_COMPILER_MSVC
#pragma warning(push)
#pragma warning(disable : 4996) // yeah, we're using a deprecated function here, in order to implement another deprecated function ¯\_(ツ)_/¯
#elif MIJIN_COMPILER == MIJIN_COMPILER_GCC || MIJIN_COMPILER == MIJIN_COMPILER_CLANG
#pragma GCC diagnostic push
#pragma GCC diagnostic ignored "-Wdeprecated-declarations"
#endif
return adapters_.front()->getHomeFolder();
#if MIJIN_COMPILER == MIJIN_COMPILER_MSVC
#pragma warning(pop)
#elif MIJIN_COMPILER == MIJIN_COMPILER_GCC || MIJIN_COMPILER == MIJIN_COMPILER_CLANG
#pragma GCC diagnostic pop
#endif
}