ladybird/Kernel/ProcessSpecificExposed.cpp
Andreas Kling fa9111ac46 Kernel: Rename ProcFSComponentsRegistrar => ProcFSComponentRegistry
This matches the formatting used in SysFS.
2021-07-11 01:40:26 +02:00

591 lines
23 KiB
C++

/*
* Copyright (c) 2021, Liav A. <liavalb@hotmail.co.il>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/JsonArraySerializer.h>
#include <AK/JsonObjectSerializer.h>
#include <AK/JsonValue.h>
#include <Kernel/Arch/x86/InterruptDisabler.h>
#include <Kernel/FileSystem/Custody.h>
#include <Kernel/KBufferBuilder.h>
#include <Kernel/ProcessExposed.h>
#include <Kernel/VM/AnonymousVMObject.h>
#include <Kernel/VM/MemoryManager.h>
namespace Kernel {
class ProcFSProcessStacks;
class ProcFSThreadStack final : public ProcFSProcessInformation {
public:
// Note: We pass const ProcFSProcessStacks& to enforce creation with this type of folder
static NonnullRefPtr<ProcFSThreadStack> create(const ProcFSProcessDirectory& process_folder, const ProcFSProcessStacks&, const Thread& thread)
{
return adopt_ref(*new (nothrow) ProcFSThreadStack(process_folder, thread));
}
private:
explicit ProcFSThreadStack(const ProcFSProcessDirectory& process_folder, const Thread& thread)
: ProcFSProcessInformation(String::formatted("{}", thread.tid()), process_folder)
, m_associated_thread(thread)
{
}
virtual bool output(KBufferBuilder& builder) override
{
JsonArraySerializer array { builder };
bool show_kernel_addresses = Process::current()->is_superuser();
bool kernel_address_added = false;
for (auto address : Processor::capture_stack_trace(*m_associated_thread, 1024)) {
if (!show_kernel_addresses && !is_user_address(VirtualAddress { address })) {
if (kernel_address_added)
continue;
address = 0xdeadc0de;
kernel_address_added = true;
}
array.add(address);
}
array.finish();
return true;
}
NonnullRefPtr<Thread> m_associated_thread;
};
class ProcFSProcessStacks final : public ProcFSExposedDirectory {
// Note: This folder is special, because everything that is created here is dynamic!
// This means we don't register anything in the m_components Vector, and every inode
// is created in runtime when called to get it
// Every ProcFSThreadStack (that represents a thread stack) is created only as a temporary object
// therefore, we don't use m_components so when we are done with the ProcFSThreadStack object,
// It should be deleted (as soon as possible)
public:
virtual KResultOr<size_t> entries_count() const override;
virtual KResult traverse_as_directory(unsigned, Function<bool(FileSystem::DirectoryEntryView const&)>) const override;
virtual RefPtr<ProcFSExposedComponent> lookup(StringView name) override;
static NonnullRefPtr<ProcFSProcessStacks> create(const ProcFSProcessDirectory& parent_folder)
{
auto folder = adopt_ref(*new (nothrow) ProcFSProcessStacks(parent_folder));
return folder;
}
virtual void prepare_for_deletion() override
{
ProcFSExposedDirectory::prepare_for_deletion();
m_process_folder.clear();
}
private:
ProcFSProcessStacks(const ProcFSProcessDirectory& parent_folder)
: ProcFSExposedDirectory("stacks"sv, parent_folder)
, m_process_folder(parent_folder)
{
}
WeakPtr<ProcFSProcessDirectory> m_process_folder;
mutable Lock m_lock;
};
KResultOr<size_t> ProcFSProcessStacks::entries_count() const
{
Locker locker(m_lock);
auto parent_folder = m_process_folder.strong_ref();
if (parent_folder.is_null())
return KResult(EINVAL);
return parent_folder->m_associated_process->thread_count();
}
KResult ProcFSProcessStacks::traverse_as_directory(unsigned fsid, Function<bool(FileSystem::DirectoryEntryView const&)> callback) const
{
Locker locker(m_lock);
auto parent_folder = m_process_folder.strong_ref();
if (parent_folder.is_null())
return KResult(EINVAL);
callback({ ".", { fsid, component_index() }, 0 });
callback({ "..", { fsid, parent_folder->component_index() }, 0 });
auto process = parent_folder->m_associated_process;
process->for_each_thread([&](const Thread& thread) {
int tid = thread.tid().value();
InodeIdentifier identifier = { fsid, thread.global_procfs_inode_index() };
callback({ String::number(tid), identifier, 0 });
});
return KSuccess;
}
RefPtr<ProcFSExposedComponent> ProcFSProcessStacks::lookup(StringView name)
{
Locker locker(m_lock);
auto parent_folder = m_process_folder.strong_ref();
if (parent_folder.is_null())
return nullptr;
auto process = parent_folder->m_associated_process;
RefPtr<ProcFSThreadStack> procfd_stack;
// FIXME: Try to exit the loop earlier
process->for_each_thread([&](const Thread& thread) {
int tid = thread.tid().value();
if (name == String::number(tid)) {
procfd_stack = ProcFSThreadStack::create(*parent_folder, *this, thread);
}
});
return procfd_stack;
}
class ProcFSProcessFileDescriptions;
class ProcFSProcessFileDescription final : public ProcFSExposedLink {
public:
// Note: we pass const ProcFSProcessFileDescriptions& just to enforce creation of this in the correct folder.
static NonnullRefPtr<ProcFSProcessFileDescription> create(unsigned fd_number, const FileDescription& fd, InodeIndex preallocated_index, const ProcFSProcessFileDescriptions&)
{
return adopt_ref(*new (nothrow) ProcFSProcessFileDescription(fd_number, fd, preallocated_index));
}
private:
explicit ProcFSProcessFileDescription(unsigned fd_number, const FileDescription& fd, InodeIndex preallocated_index)
: ProcFSExposedLink(String::formatted("{}", fd_number), preallocated_index)
, m_associated_file_description(fd)
{
}
virtual bool acquire_link(KBufferBuilder& builder) override
{
builder.append_bytes(m_associated_file_description->absolute_path().bytes());
return true;
}
NonnullRefPtr<FileDescription> m_associated_file_description;
};
class ProcFSProcessFileDescriptions final : public ProcFSExposedDirectory {
// Note: This folder is special, because everything that is created here is dynamic!
// This means we don't register anything in the m_components Vector, and every inode
// is created in runtime when called to get it
// Every ProcFSProcessFileDescription (that represents a file descriptor) is created only as a temporary object
// therefore, we don't use m_components so when we are done with the ProcFSProcessFileDescription object,
// It should be deleted (as soon as possible)
public:
virtual KResultOr<size_t> entries_count() const override;
virtual KResult traverse_as_directory(unsigned, Function<bool(FileSystem::DirectoryEntryView const&)>) const override;
virtual RefPtr<ProcFSExposedComponent> lookup(StringView name) override;
static NonnullRefPtr<ProcFSProcessFileDescriptions> create(const ProcFSProcessDirectory& parent_folder)
{
return adopt_ref(*new (nothrow) ProcFSProcessFileDescriptions(parent_folder));
}
virtual void prepare_for_deletion() override
{
ProcFSExposedDirectory::prepare_for_deletion();
m_process_folder.clear();
}
private:
explicit ProcFSProcessFileDescriptions(const ProcFSProcessDirectory& parent_folder)
: ProcFSExposedDirectory("fd"sv, parent_folder)
, m_process_folder(parent_folder)
{
}
WeakPtr<ProcFSProcessDirectory> m_process_folder;
mutable Lock m_lock;
};
KResultOr<size_t> ProcFSProcessFileDescriptions::entries_count() const
{
Locker locker(m_lock);
auto parent_folder = m_process_folder.strong_ref();
if (parent_folder.is_null())
return KResult(EINVAL);
return parent_folder->m_associated_process->fds().open_count();
}
KResult ProcFSProcessFileDescriptions::traverse_as_directory(unsigned fsid, Function<bool(FileSystem::DirectoryEntryView const&)> callback) const
{
Locker locker(m_lock);
auto parent_folder = m_process_folder.strong_ref();
if (parent_folder.is_null())
return KResult(EINVAL);
callback({ ".", { fsid, component_index() }, 0 });
callback({ "..", { fsid, parent_folder->component_index() }, 0 });
auto process = parent_folder->m_associated_process;
size_t count = 0;
process->fds().enumerate([&](auto& file_description_metadata) {
if (!file_description_metadata.is_valid()) {
count++;
return;
}
InodeIdentifier identifier = { fsid, file_description_metadata.global_procfs_inode_index() };
callback({ String::number(count), identifier, 0 });
count++;
});
return KSuccess;
}
RefPtr<ProcFSExposedComponent> ProcFSProcessFileDescriptions::lookup(StringView name)
{
Locker locker(m_lock);
auto parent_folder = m_process_folder.strong_ref();
if (parent_folder.is_null())
return nullptr;
auto process = parent_folder->m_associated_process;
RefPtr<ProcFSProcessFileDescription> procfd_fd;
// FIXME: Try to exit the loop earlier
size_t count = 0;
process->fds().enumerate([&](auto& file_description_metadata) {
if (!file_description_metadata.is_valid()) {
count++;
return;
}
if (name == String::number(count)) {
procfd_fd = ProcFSProcessFileDescription::create(count, *file_description_metadata.description(), file_description_metadata.global_procfs_inode_index(), *this);
}
count++;
});
return procfd_fd;
}
class ProcFSProcessPledge final : public ProcFSProcessInformation {
public:
static NonnullRefPtr<ProcFSProcessPledge> create(const ProcFSProcessDirectory& parent_folder)
{
return adopt_ref(*new (nothrow) ProcFSProcessPledge(parent_folder));
}
private:
explicit ProcFSProcessPledge(const ProcFSProcessDirectory& parent_folder)
: ProcFSProcessInformation("pledge"sv, parent_folder)
{
}
virtual bool output(KBufferBuilder& builder) override
{
auto parent_folder = m_parent_folder.strong_ref();
if (parent_folder.is_null())
return false;
auto process = parent_folder->m_associated_process;
JsonObjectSerializer obj { builder };
#define __ENUMERATE_PLEDGE_PROMISE(x) \
if (process->has_promised(Pledge::x)) { \
if (!builder.is_empty()) \
builder.append(' '); \
builder.append(#x); \
}
if (process->has_promises()) {
StringBuilder builder;
ENUMERATE_PLEDGE_PROMISES
obj.add("promises", builder.build());
}
#undef __ENUMERATE_PLEDGE_PROMISE
obj.finish();
return true;
}
};
class ProcFSProcessUnveil final : public ProcFSProcessInformation {
public:
static NonnullRefPtr<ProcFSProcessUnveil> create(const ProcFSProcessDirectory& parent_folder)
{
return adopt_ref(*new (nothrow) ProcFSProcessUnveil(parent_folder));
}
private:
explicit ProcFSProcessUnveil(const ProcFSProcessDirectory& parent_folder)
: ProcFSProcessInformation("unveil"sv, parent_folder)
{
}
virtual bool output(KBufferBuilder& builder) override
{
auto parent_folder = m_parent_folder.strong_ref();
if (parent_folder.is_null())
return false;
JsonArraySerializer array { builder };
for (auto& unveiled_path : parent_folder->m_associated_process->unveiled_paths()) {
if (!unveiled_path.was_explicitly_unveiled())
continue;
auto obj = array.add_object();
obj.add("path", unveiled_path.path());
StringBuilder permissions_builder;
if (unveiled_path.permissions() & UnveilAccess::Read)
permissions_builder.append('r');
if (unveiled_path.permissions() & UnveilAccess::Write)
permissions_builder.append('w');
if (unveiled_path.permissions() & UnveilAccess::Execute)
permissions_builder.append('x');
if (unveiled_path.permissions() & UnveilAccess::CreateOrRemove)
permissions_builder.append('c');
if (unveiled_path.permissions() & UnveilAccess::Browse)
permissions_builder.append('b');
obj.add("permissions", permissions_builder.to_string());
}
array.finish();
return true;
}
};
class ProcFSProcessPerformanceEvents final : public ProcFSProcessInformation {
public:
static NonnullRefPtr<ProcFSProcessPerformanceEvents> create(const ProcFSProcessDirectory& parent_folder)
{
return adopt_ref(*new (nothrow) ProcFSProcessPerformanceEvents(parent_folder));
}
private:
explicit ProcFSProcessPerformanceEvents(const ProcFSProcessDirectory& parent_folder)
: ProcFSProcessInformation("perf_events"sv, parent_folder)
{
}
virtual bool output(KBufferBuilder& builder) override
{
InterruptDisabler disabler;
auto parent_folder = m_parent_folder.strong_ref();
if (parent_folder.is_null())
return false;
auto process = parent_folder->m_associated_process;
if (!process->perf_events()) {
dbgln("ProcFS: No perf events for {}", process->pid());
return false;
}
return process->perf_events()->to_json(builder);
}
};
class ProcFSProcessOverallFileDescriptions final : public ProcFSProcessInformation {
public:
static NonnullRefPtr<ProcFSProcessOverallFileDescriptions> create(const ProcFSProcessDirectory& parent_folder)
{
return adopt_ref(*new (nothrow) ProcFSProcessOverallFileDescriptions(parent_folder));
}
private:
explicit ProcFSProcessOverallFileDescriptions(const ProcFSProcessDirectory& parent_folder)
: ProcFSProcessInformation("fds"sv, parent_folder)
{
}
virtual bool output(KBufferBuilder& builder) override
{
auto parent_folder = m_parent_folder.strong_ref();
if (parent_folder.is_null())
return false;
JsonArraySerializer array { builder };
auto process = parent_folder->m_associated_process;
if (process->fds().open_count() == 0) {
array.finish();
return true;
}
size_t count = 0;
process->fds().enumerate([&](auto& file_description_metadata) {
if (!file_description_metadata.is_valid()) {
count++;
return;
}
bool cloexec = file_description_metadata.flags() & FD_CLOEXEC;
RefPtr<FileDescription> description = file_description_metadata.description();
auto description_object = array.add_object();
description_object.add("fd", count);
description_object.add("absolute_path", description->absolute_path());
description_object.add("seekable", description->file().is_seekable());
description_object.add("class", description->file().class_name());
description_object.add("offset", description->offset());
description_object.add("cloexec", cloexec);
description_object.add("blocking", description->is_blocking());
description_object.add("can_read", description->can_read());
description_object.add("can_write", description->can_write());
count++;
});
array.finish();
return true;
}
};
class ProcFSProcessRoot final : public ProcFSExposedLink {
public:
static NonnullRefPtr<ProcFSProcessRoot> create(const ProcFSProcessDirectory& parent_folder)
{
return adopt_ref(*new (nothrow) ProcFSProcessRoot(parent_folder));
}
private:
explicit ProcFSProcessRoot(const ProcFSProcessDirectory& parent_folder)
: ProcFSExposedLink("root"sv)
, m_parent_process_directory(parent_folder)
{
}
virtual bool acquire_link(KBufferBuilder& builder) override
{
auto parent_folder = m_parent_process_directory.strong_ref();
if (parent_folder.is_null())
return false;
builder.append_bytes(parent_folder->m_associated_process->root_directory_relative_to_global_root().absolute_path().to_byte_buffer());
return true;
}
WeakPtr<ProcFSProcessDirectory> m_parent_process_directory;
};
class ProcFSProcessVirtualMemory final : public ProcFSProcessInformation {
public:
static NonnullRefPtr<ProcFSProcessRoot> create(const ProcFSProcessDirectory& parent_folder)
{
return adopt_ref(*new (nothrow) ProcFSProcessVirtualMemory(parent_folder));
}
private:
explicit ProcFSProcessVirtualMemory(const ProcFSProcessDirectory& parent_folder)
: ProcFSProcessInformation("vm"sv, parent_folder)
{
}
virtual bool output(KBufferBuilder& builder) override
{
auto parent_folder = m_parent_folder.strong_ref();
if (parent_folder.is_null())
return false;
auto process = parent_folder->m_associated_process;
JsonArraySerializer array { builder };
{
ScopedSpinLock lock(process->space().get_lock());
for (auto& region : process->space().regions()) {
if (!region->is_user() && !Process::current()->is_superuser())
continue;
auto region_object = array.add_object();
region_object.add("readable", region->is_readable());
region_object.add("writable", region->is_writable());
region_object.add("executable", region->is_executable());
region_object.add("stack", region->is_stack());
region_object.add("shared", region->is_shared());
region_object.add("syscall", region->is_syscall_region());
region_object.add("purgeable", region->vmobject().is_anonymous());
if (region->vmobject().is_anonymous()) {
region_object.add("volatile", static_cast<const AnonymousVMObject&>(region->vmobject()).is_any_volatile());
}
region_object.add("cacheable", region->is_cacheable());
region_object.add("address", region->vaddr().get());
region_object.add("size", region->size());
region_object.add("amount_resident", region->amount_resident());
region_object.add("amount_dirty", region->amount_dirty());
region_object.add("cow_pages", region->cow_pages());
region_object.add("name", region->name());
region_object.add("vmobject", region->vmobject().class_name());
StringBuilder pagemap_builder;
for (size_t i = 0; i < region->page_count(); ++i) {
auto* page = region->physical_page(i);
if (!page)
pagemap_builder.append('N');
else if (page->is_shared_zero_page() || page->is_lazy_committed_page())
pagemap_builder.append('Z');
else
pagemap_builder.append('P');
}
region_object.add("pagemap", pagemap_builder.to_string());
}
}
array.finish();
return true;
}
};
class ProcFSProcessCurrentWorkDirectory final : public ProcFSExposedLink {
public:
static NonnullRefPtr<ProcFSProcessCurrentWorkDirectory> create(const ProcFSProcessDirectory& parent_folder)
{
return adopt_ref(*new (nothrow) ProcFSProcessCurrentWorkDirectory(parent_folder));
}
private:
explicit ProcFSProcessCurrentWorkDirectory(const ProcFSProcessDirectory& parent_folder)
: ProcFSExposedLink("cwd"sv)
, m_parent_process_directory(parent_folder)
{
}
virtual bool acquire_link(KBufferBuilder& builder) override
{
auto parent_folder = m_parent_process_directory.strong_ref();
if (parent_folder.is_null())
return false;
builder.append_bytes(parent_folder->m_associated_process->current_directory().absolute_path().bytes());
return true;
}
WeakPtr<ProcFSProcessDirectory> m_parent_process_directory;
};
class ProcFSProcessBinary final : public ProcFSExposedLink {
public:
static NonnullRefPtr<ProcFSProcessBinary> create(const ProcFSProcessDirectory& parent_folder)
{
return adopt_ref(*new (nothrow) ProcFSProcessBinary(parent_folder));
}
virtual mode_t required_mode() const override
{
auto parent_folder = m_parent_process_directory.strong_ref();
if (parent_folder.is_null())
return false;
if (!parent_folder->m_associated_process->executable())
return 0;
return ProcFSExposedComponent::required_mode();
}
private:
explicit ProcFSProcessBinary(const ProcFSProcessDirectory& parent_folder)
: ProcFSExposedLink("exe"sv)
, m_parent_process_directory(parent_folder)
{
}
virtual bool acquire_link(KBufferBuilder& builder) override
{
auto parent_folder = m_parent_process_directory.strong_ref();
if (parent_folder.is_null())
return false;
auto* custody = parent_folder->m_associated_process->executable();
if (!custody)
return false;
builder.append(custody->absolute_path().bytes());
return true;
}
WeakPtr<ProcFSProcessDirectory> m_parent_process_directory;
};
void ProcFSProcessDirectory::on_attach()
{
VERIFY(m_components.size() == 0);
m_components.append(ProcFSProcessPledge::create(*this));
m_components.append(ProcFSProcessUnveil::create(*this));
m_components.append(ProcFSProcessPerformanceEvents::create(*this));
m_components.append(ProcFSProcessFileDescriptions::create(*this));
m_components.append(ProcFSProcessOverallFileDescriptions::create(*this));
m_components.append(ProcFSProcessRoot::create(*this));
m_components.append(ProcFSProcessVirtualMemory::create(*this));
m_components.append(ProcFSProcessCurrentWorkDirectory::create(*this));
m_components.append(ProcFSProcessBinary::create(*this));
m_components.append(ProcFSProcessStacks::create(*this));
}
RefPtr<ProcFSExposedComponent> ProcFSProcessDirectory::lookup(StringView name)
{
// Note: we need to allocate all sub components when doing a lookup, because
// for some reason, the caller may not call ProcFSInode::attach method before calling this.
if (m_components.size() == 0)
on_attach();
return ProcFSExposedDirectory::lookup(name);
}
KResult ProcFSProcessDirectory::refresh_data(FileDescription&) const
{
if (m_components.size() != 0)
return KSuccess;
const_cast<ProcFSProcessDirectory&>(*this).on_attach();
return KSuccess;
}
NonnullRefPtr<ProcFSProcessDirectory> ProcFSProcessDirectory::create(const Process& process)
{
return adopt_ref_if_nonnull(new (nothrow) ProcFSProcessDirectory(process)).release_nonnull();
}
ProcFSProcessDirectory::ProcFSProcessDirectory(const Process& process)
: ProcFSExposedDirectory(String::formatted("{:d}", process.pid().value()), ProcFSComponentRegistry::the().root_folder())
, m_associated_process(process)
{
}
}