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Atmosphere/libraries/libstratosphere/include/stratosphere/fssystem/fssystem_utility.hpp

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/*
* Copyright (c) Atmosphère-NX
*
* This program is free software; you can redistribute it and/or modify it
* under the terms and conditions of the GNU General Public License,
* version 2, as published by the Free Software Foundation.
*
* This program is distributed in the hope it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for
* more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
#pragma once
#include <stratosphere/fs/fs_common.hpp>
#include <stratosphere/fs/fs_file.hpp>
#include <stratosphere/fs/fs_directory.hpp>
#include <stratosphere/fs/fs_filesystem.hpp>
#include <stratosphere/fs/fs_path.hpp>
namespace ams::fssystem {
/* ACCURATE_TO_VERSION: 13.4.0.0 */
namespace impl {
template<typename F>
concept IterateDirectoryHandler = requires (F f, const fs::Path &path, const fs::DirectoryEntry &entry) {
{ f(path, entry) } -> std::convertible_to<::ams::Result>;
};
/* Iteration. */
template<IterateDirectoryHandler OnEnterDir, IterateDirectoryHandler OnExitDir, IterateDirectoryHandler OnFile>
Result IterateDirectoryRecursivelyImpl(fs::fsa::IFileSystem *fs, fs::Path &work_path, fs::DirectoryEntry *dir_ent, OnEnterDir on_enter_dir, OnExitDir on_exit_dir, OnFile on_file) {
/* Open the directory. */
std::unique_ptr<fs::fsa::IDirectory> dir;
R_TRY(fs->OpenDirectory(std::addressof(dir), work_path, fs::OpenDirectoryMode_All));
/* Read and handle entries. */
while (true) {
/* Read a single entry. */
s64 read_count = 0;
R_TRY(dir->Read(std::addressof(read_count), dir_ent, 1));
/* If we're out of entries, we're done. */
if (read_count == 0) {
break;
}
/* Append child path. */
R_TRY(work_path.AppendChild(dir_ent->name));
{
if (dir_ent->type == fs::DirectoryEntryType_Directory) {
/* Enter directory. */
R_TRY(on_enter_dir(work_path, *dir_ent));
/* Recurse. */
R_TRY(IterateDirectoryRecursivelyImpl(fs, work_path, dir_ent, on_enter_dir, on_exit_dir, on_file));
/* Exit directory. */
R_TRY(on_exit_dir(work_path, *dir_ent));
} else {
/* Call file handler. */
R_TRY(on_file(work_path, *dir_ent));
}
}
R_TRY(work_path.RemoveChild());
}
R_SUCCEED();
}
/* TODO: Cleanup. */
}
/* Iteration API */
template<impl::IterateDirectoryHandler OnEnterDir, impl::IterateDirectoryHandler OnExitDir, impl::IterateDirectoryHandler OnFile>
Result IterateDirectoryRecursively(fs::fsa::IFileSystem *fs, const fs::Path &root_path, fs::DirectoryEntry *dir_ent_buf, OnEnterDir on_enter_dir, OnExitDir on_exit_dir, OnFile on_file) {
/* Create work path from the root path. */
fs::Path work_path;
R_TRY(work_path.Initialize(root_path));
R_RETURN(impl::IterateDirectoryRecursivelyImpl(fs, work_path, dir_ent_buf, on_enter_dir, on_exit_dir, on_file));
}
template<impl::IterateDirectoryHandler OnEnterDir, impl::IterateDirectoryHandler OnExitDir, impl::IterateDirectoryHandler OnFile>
Result IterateDirectoryRecursively(fs::fsa::IFileSystem *fs, const fs::Path &root_path, OnEnterDir on_enter_dir, OnExitDir on_exit_dir, OnFile on_file) {
fs::DirectoryEntry dir_entry = {};
R_RETURN(IterateDirectoryRecursively(fs, root_path, std::addressof(dir_entry), on_enter_dir, on_exit_dir, on_file));
}
template<impl::IterateDirectoryHandler OnEnterDir, impl::IterateDirectoryHandler OnExitDir, impl::IterateDirectoryHandler OnFile>
Result IterateDirectoryRecursively(fs::fsa::IFileSystem *fs, OnEnterDir on_enter_dir, OnExitDir on_exit_dir, OnFile on_file) {
R_RETURN(IterateDirectoryRecursively(fs, fs::MakeConstantPath("/"), on_enter_dir, on_exit_dir, on_file));
}
/* TODO: Cleanup API */
/* Copy API. */
Result CopyFile(fs::fsa::IFileSystem *dst_fs, fs::fsa::IFileSystem *src_fs, const fs::Path &dst_path, const fs::Path &src_path, void *work_buf, size_t work_buf_size);
ALWAYS_INLINE Result CopyFile(fs::fsa::IFileSystem *fs, const fs::Path &dst_path, const fs::Path &src_path, void *work_buf, size_t work_buf_size) {
R_RETURN(CopyFile(fs, fs, dst_path, src_path, work_buf, work_buf_size));
}
Result CopyDirectoryRecursively(fs::fsa::IFileSystem *dst_fs, fs::fsa::IFileSystem *src_fs, const fs::Path &dst_path, const fs::Path &src_path, fs::DirectoryEntry *entry, void *work_buf, size_t work_buf_size);
ALWAYS_INLINE Result CopyDirectoryRecursively(fs::fsa::IFileSystem *fs, const fs::Path &dst_path, const fs::Path &src_path, fs::DirectoryEntry *entry, void *work_buf, size_t work_buf_size) {
R_RETURN(CopyDirectoryRecursively(fs, fs, dst_path, src_path, entry, work_buf, work_buf_size));
}
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/* Locking utilities. */
class SemaphoreAdaptor : public os::Semaphore {
public:
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SemaphoreAdaptor(int c, int mc) : os::Semaphore(c, mc) { /* ... */ }
bool TryLock(int *out_acquired, int count) {
AMS_ASSERT(count > 0);
for (auto i = 0; i < count; ++i) {
if (!this->TryAcquire()) {
*out_acquired = i;
return false;
}
}
*out_acquired = count;
return true;
}
void Unlock(int count) {
if (count > 0) {
this->Release(count);
}
}
bool try_lock() {
return this->TryAcquire();
}
void unlock() {
this->Release();
}
};
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Result TryAcquireCountSemaphore(util::unique_lock<SemaphoreAdaptor> *out, SemaphoreAdaptor *adaptor);
class IUniqueLock {
NON_COPYABLE(IUniqueLock);
NON_MOVEABLE(IUniqueLock);
public:
virtual ~IUniqueLock() { /* ... */ }
};
template<typename T>
class UniqueLockWithPin final : public IUniqueLock, public ::ams::fs::impl::Newable {
private:
util::unique_lock<SemaphoreAdaptor> m_lock;
T m_pinned_object;
public:
UniqueLockWithPin(util::unique_lock<SemaphoreAdaptor> lock, T obj) : m_lock(std::move(lock)), m_pinned_object(std::move(obj)) { /* ... */ }
virtual ~UniqueLockWithPin() override {
m_lock = {};
}
};
template<typename T>
class MultiLockWithPin final : public IUniqueLock, public ::ams::fs::impl::Newable {
private:
T m_pinned_object;
SemaphoreAdaptor *m_semaphore_adaptor;
int m_lock_count;
public:
MultiLockWithPin(T obj, SemaphoreAdaptor *adaptor) : m_pinned_object(std::move(obj)), m_semaphore_adaptor(adaptor), m_lock_count(0) {
/* ... */
}
virtual ~MultiLockWithPin() override {
if (m_lock_count > 0) {
m_semaphore_adaptor->Unlock(m_lock_count);
}
}
Result Lock(int count) {
AMS_ASSERT(m_lock_count == 0);
R_UNLESS(m_semaphore_adaptor->TryLock(std::addressof(m_lock_count), count), fs::ResultOpenCountLimit());
R_SUCCEED();
}
};
template<typename T>
Result MakeUniqueLockWithPin(std::unique_ptr<IUniqueLock> *out, SemaphoreAdaptor *adaptor, T obj) {
/* Create the semaphore unique lock. */
util::unique_lock<SemaphoreAdaptor> sema_lock;
R_TRY(TryAcquireCountSemaphore(std::addressof(sema_lock), adaptor));
/* Create the output unique lock. */
auto result_lock = std::unique_ptr<UniqueLockWithPin<T>>(new UniqueLockWithPin<T>(std::move(sema_lock), std::move(obj)));
R_UNLESS(result_lock != nullptr, fs::ResultAllocationMemoryFailedNew());
/* Set the output. */
*out = std::move(result_lock);
R_SUCCEED();
}
template<typename T>
Result MakeUniqueLockWithPin(std::unique_ptr<IUniqueLock> *out, SemaphoreAdaptor *adaptor, int count, T obj) {
/* Create the output unique lock. */
auto result_lock = std::unique_ptr<MultiLockWithPin<T>>(new MultiLockWithPin<T>(std::move(obj), adaptor));
R_UNLESS(result_lock != nullptr, fs::ResultAllocationMemoryFailedNew());
/* Acquire the output lock. */
R_TRY(result_lock->Lock(count));
/* Set the output. */
*out = std::move(result_lock);
R_SUCCEED();
}
/* Other utility. */
Result HasFile(bool *out, fs::fsa::IFileSystem *fs, const fs::Path &path);
Result HasDirectory(bool *out, fs::fsa::IFileSystem *fs, const fs::Path &path);
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Result EnsureDirectory(fs::fsa::IFileSystem *fs, const fs::Path &path);
template<s64 RetryMilliSeconds = 100, s32 MaxTryCount = 10>
ALWAYS_INLINE Result RetryFinitelyForTargetLocked(auto f) {
/* Retry sleeping between retries. */
constexpr TimeSpan RetryWaitTime = TimeSpan::FromMilliSeconds(RetryMilliSeconds);
Result result = f();
for (int i = 0; i < MaxTryCount && fs::ResultTargetLocked::Includes(result); ++i) {
os::SleepThread(RetryWaitTime);
result = f();
}
R_RETURN(result);
}
ALWAYS_INLINE Result RetryToAvoidTargetLocked(auto f) {
R_RETURN((RetryFinitelyForTargetLocked<2, 25>(f)));
}
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void AddCounter(void *counter, size_t counter_size, u64 value);
}