#include "ProcFS.h"
#include "Console.h"
#include "KSyms.h"
#include "Process.h"
#include "Scheduler.h"
#include "StdLib.h"
#include <AK/StringBuilder.h>
#include <Kernel/Arch/i386/CPU.h>
#include <Kernel/FileSystem/Custody.h>
#include <Kernel/FileSystem/FileDescription.h>
#include <Kernel/FileSystem/VirtualFileSystem.h>
#include <Kernel/KParams.h>
#include <Kernel/Net/NetworkAdapter.h>
#include <Kernel/PCI.h>
#include <Kernel/VM/MemoryManager.h>
#include <Kernel/kmalloc.h>
#include <LibC/errno_numbers.h>
enum ProcParentDirectory {
PDI_AbstractRoot = 0,
PDI_Root,
PDI_Root_sys,
PDI_PID,
PDI_PID_fd,
};
enum ProcFileType {
FI_Invalid = 0,
FI_Root = 1, // directory
__FI_Root_Start,
FI_Root_mm,
FI_Root_mounts,
FI_Root_df,
FI_Root_kmalloc,
FI_Root_all,
FI_Root_memstat,
FI_Root_summary,
FI_Root_cpuinfo,
FI_Root_inodes,
FI_Root_dmesg,
FI_Root_pci,
FI_Root_uptime,
FI_Root_cmdline,
FI_Root_netadapters,
FI_Root_self, // symlink
FI_Root_sys, // directory
__FI_Root_End,
FI_PID,
__FI_PID_Start,
FI_PID_vm,
FI_PID_vmo,
FI_PID_stack,
FI_PID_regs,
FI_PID_fds,
FI_PID_exe, // symlink
FI_PID_cwd, // symlink
FI_PID_fd, // directory
__FI_PID_End,
FI_MaxStaticFileIndex,
};
static inline pid_t to_pid(const InodeIdentifier& identifier)
{
#ifdef PROCFS_DEBUG
dbgprintf("to_pid, index=%08x -> %u\n", identifier.index(), identifier.index() >> 16);
#endif
return identifier.index() >> 16u;
}
static inline ProcParentDirectory to_proc_parent_directory(const InodeIdentifier& identifier)
{
return (ProcParentDirectory)((identifier.index() >> 12) & 0xf);
}
static inline int to_fd(const InodeIdentifier& identifier)
{
ASSERT(to_proc_parent_directory(identifier) == PDI_PID_fd);
return (identifier.index() & 0xff) - FI_MaxStaticFileIndex;
}
static inline int to_sys_index(const InodeIdentifier& identifier)
{
ASSERT(to_proc_parent_directory(identifier) == PDI_Root_sys);
return identifier.index() & 0xff;
}
static inline InodeIdentifier to_identifier(unsigned fsid, ProcParentDirectory parent, pid_t pid, ProcFileType proc_file_type)
{
return { fsid, ((unsigned)parent << 12u) | ((unsigned)pid << 16u) | (unsigned)proc_file_type };
}
static inline InodeIdentifier to_identifier_with_fd(unsigned fsid, pid_t pid, int fd)
{
return { fsid, (PDI_PID_fd << 12u) | ((unsigned)pid << 16u) | (FI_MaxStaticFileIndex + fd) };
}
static inline InodeIdentifier sys_var_to_identifier(unsigned fsid, unsigned index)
{
ASSERT(index < 256);
return { fsid, (PDI_Root_sys << 12u) | index };
}
static inline InodeIdentifier to_parent_id(const InodeIdentifier& identifier)
{
switch (to_proc_parent_directory(identifier)) {
case PDI_AbstractRoot:
case PDI_Root:
return { identifier.fsid(), FI_Root };
case PDI_Root_sys:
return { identifier.fsid(), FI_Root_sys };
case PDI_PID:
return to_identifier(identifier.fsid(), PDI_Root, to_pid(identifier), FI_PID);
case PDI_PID_fd:
return to_identifier(identifier.fsid(), PDI_PID, to_pid(identifier), FI_PID_fd);
}
ASSERT_NOT_REACHED();
}
#if 0
static inline byte to_unused_metadata(const InodeIdentifier& identifier)
{
return (identifier.index() >> 8) & 0xf;
}
#endif
static inline ProcFileType to_proc_file_type(const InodeIdentifier& identifier)
{
return (ProcFileType)(identifier.index() & 0xff);
}
static inline bool is_process_related_file(const InodeIdentifier& identifier)
{
if (to_proc_file_type(identifier) == FI_PID)
return true;
auto proc_parent_directory = to_proc_parent_directory(identifier);
switch (proc_parent_directory) {
case PDI_PID:
case PDI_PID_fd:
return true;
default:
return false;
}
}
static inline bool is_directory(const InodeIdentifier& identifier)
{
auto proc_file_type = to_proc_file_type(identifier);
switch (proc_file_type) {
case FI_Root:
case FI_Root_sys:
case FI_PID:
case FI_PID_fd:
return true;
default:
return false;
}
}
static inline bool is_persistent_inode(const InodeIdentifier& identifier)
{
return to_proc_parent_directory(identifier) == PDI_Root_sys;
}
static ProcFS* s_the;
ProcFS& ProcFS::the()
{
ASSERT(s_the);
return *s_the;
}
NonnullRefPtr<ProcFS> ProcFS::create()
{
return adopt(*new ProcFS);
}
ProcFS::~ProcFS()
{
}
ByteBuffer procfs$pid_fds(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
if (process.number_of_open_file_descriptors() == 0)
return {};
StringBuilder builder;
for (int i = 0; i < process.max_open_file_descriptors(); ++i) {
auto* description = process.file_description(i);
if (!description)
continue;
builder.appendf("%-3u %s\n", i, description->absolute_path().characters());
}
return builder.to_byte_buffer();
}
ByteBuffer procfs$pid_fd_entry(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
int fd = to_fd(identifier);
auto* description = process.file_description(fd);
if (!description)
return {};
return description->absolute_path().to_byte_buffer();
}
ByteBuffer procfs$pid_vm(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
StringBuilder builder;
builder.appendf("BEGIN END SIZE COMMIT FLAGS NAME\n");
for (auto& region : process.regions()) {
StringBuilder flags_builder;
if (region.is_readable())
flags_builder.append('R');
if (region.is_writable())
flags_builder.append('W');
builder.appendf("%x -- %x %x %x %-4s %s\n",
region.vaddr().get(),
region.vaddr().offset(region.size() - 1).get(),
region.size(),
region.amount_resident(),
flags_builder.to_string().characters(),
region.name().characters());
}
return builder.to_byte_buffer();
}
ByteBuffer procfs$pci(InodeIdentifier)
{
StringBuilder builder;
PCI::enumerate_all([&builder](PCI::Address address, PCI::ID id) {
builder.appendf("%b:%b.%b %w:%w\n", address.bus(), address.slot(), address.function(), id.vendor_id, id.device_id);
});
return builder.to_byte_buffer();
}
ByteBuffer procfs$uptime(InodeIdentifier)
{
StringBuilder builder;
builder.appendf("%u\n", (dword)(g_uptime / 1000));
return builder.to_byte_buffer();
}
ByteBuffer procfs$cmdline(InodeIdentifier)
{
StringBuilder builder;
builder.appendf("%s\n", KParams::the().cmdline().characters());
return builder.to_byte_buffer();
}
ByteBuffer procfs$netadapters(InodeIdentifier)
{
StringBuilder builder;
NetworkAdapter::for_each([&builder](auto& adapter) {
builder.appendf("%s,%s,%s,%s\n",
adapter.name().characters(),
adapter.class_name(),
adapter.mac_address().to_string().characters(),
adapter.ipv4_address().to_string().characters());
});
return builder.to_byte_buffer();
}
ByteBuffer procfs$pid_vmo(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
StringBuilder builder;
builder.appendf("BEGIN END SIZE NAME\n");
for (auto& region : process.regions()) {
builder.appendf("%x -- %x %x %s\n",
region.vaddr().get(),
region.vaddr().offset(region.size() - 1).get(),
region.size(),
region.name().characters());
builder.appendf("VMO: %s \"%s\" @ %x(%u)\n",
region.vmo().is_anonymous() ? "anonymous" : "file-backed",
region.vmo().name().characters(),
®ion.vmo(),
region.vmo().ref_count());
for (int i = 0; i < region.vmo().page_count(); ++i) {
auto& physical_page = region.vmo().physical_pages()[i];
builder.appendf("P%x%s(%u) ",
physical_page ? physical_page->paddr().get() : 0,
region.should_cow(i) ? "!" : "",
physical_page ? physical_page->ref_count() : 0);
}
builder.appendf("\n");
}
return builder.to_byte_buffer();
}
ByteBuffer procfs$pid_stack(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
ProcessPagingScope paging_scope(process);
struct RecognizedSymbol {
dword address;
const KSym* ksym;
};
StringBuilder builder;
process.for_each_thread([&](Thread& thread) {
builder.appendf("Thread %d:\n", thread.tid());
Vector<RecognizedSymbol, 64> recognized_symbols;
recognized_symbols.append({ thread.tss().eip, ksymbolicate(thread.tss().eip) });
for (dword* stack_ptr = (dword*)thread.frame_ptr(); process.validate_read_from_kernel(VirtualAddress((dword)stack_ptr)); stack_ptr = (dword*)*stack_ptr) {
dword retaddr = stack_ptr[1];
recognized_symbols.append({ retaddr, ksymbolicate(retaddr) });
}
for (auto& symbol : recognized_symbols) {
if (!symbol.address)
break;
if (!symbol.ksym) {
builder.appendf("%p\n", symbol.address);
continue;
}
unsigned offset = symbol.address - symbol.ksym->address;
if (symbol.ksym->address == ksym_highest_address && offset > 4096)
builder.appendf("%p\n", symbol.address);
else
builder.appendf("%p %s +%u\n", symbol.address, symbol.ksym->name, offset);
}
return IterationDecision::Continue;
});
return builder.to_byte_buffer();
}
ByteBuffer procfs$pid_regs(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
StringBuilder builder;
process.for_each_thread([&](Thread& thread) {
builder.appendf("Thread %d:\n", thread.tid());
auto& tss = thread.tss();
builder.appendf("eax: %x\n", tss.eax);
builder.appendf("ebx: %x\n", tss.ebx);
builder.appendf("ecx: %x\n", tss.ecx);
builder.appendf("edx: %x\n", tss.edx);
builder.appendf("esi: %x\n", tss.esi);
builder.appendf("edi: %x\n", tss.edi);
builder.appendf("ebp: %x\n", tss.ebp);
builder.appendf("cr3: %x\n", tss.cr3);
builder.appendf("flg: %x\n", tss.eflags);
builder.appendf("sp: %w:%x\n", tss.ss, tss.esp);
builder.appendf("pc: %w:%x\n", tss.cs, tss.eip);
return IterationDecision::Continue;
});
return builder.to_byte_buffer();
}
ByteBuffer procfs$pid_exe(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
auto* custody = process.executable();
ASSERT(custody);
return custody->absolute_path().to_byte_buffer();
}
ByteBuffer procfs$pid_cwd(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
return handle->process().current_directory().absolute_path().to_byte_buffer();
}
ByteBuffer procfs$self(InodeIdentifier)
{
char buffer[16];
ksprintf(buffer, "%u", current->pid());
return ByteBuffer::copy((const byte*)buffer, strlen(buffer));
}
ByteBuffer procfs$mm(InodeIdentifier)
{
// FIXME: Implement
InterruptDisabler disabler;
StringBuilder builder;
for (auto* vmo : MM.m_vmos) {
builder.appendf("VMO: %p %s(%u): p:%4u %s\n",
vmo,
vmo->is_anonymous() ? "anon" : "file",
vmo->ref_count(),
vmo->page_count(),
vmo->name().characters());
}
builder.appendf("VMO count: %u\n", MM.m_vmos.size());
builder.appendf("Free physical pages: %u\n", MM.user_physical_pages() - MM.user_physical_pages_used());
builder.appendf("Free supervisor physical pages: %u\n", MM.super_physical_pages() - MM.super_physical_pages_used());
return builder.to_byte_buffer();
}
ByteBuffer procfs$dmesg(InodeIdentifier)
{
InterruptDisabler disabler;
StringBuilder builder;
for (char ch : Console::the().logbuffer())
builder.append(ch);
return builder.to_byte_buffer();
}
ByteBuffer procfs$mounts(InodeIdentifier)
{
// FIXME: This is obviously racy against the VFS mounts changing.
StringBuilder builder;
VFS::the().for_each_mount([&builder](auto& mount) {
auto& fs = mount.guest_fs();
builder.appendf("%s @ ", fs.class_name());
if (!mount.host().is_valid())
builder.appendf("/");
else {
builder.appendf("%u:%u", mount.host().fsid(), mount.host().index());
builder.append(' ');
builder.append(mount.absolute_path());
}
builder.append('\n');
});
return builder.to_byte_buffer();
}
ByteBuffer procfs$df(InodeIdentifier)
{
// FIXME: This is obviously racy against the VFS mounts changing.
StringBuilder builder;
VFS::the().for_each_mount([&builder](auto& mount) {
auto& fs = mount.guest_fs();
builder.appendf("%s,", fs.class_name());
builder.appendf("%u,", fs.total_block_count());
builder.appendf("%u,", fs.free_block_count());
builder.appendf("%u,", fs.total_inode_count());
builder.appendf("%u,", fs.free_inode_count());
builder.append(mount.absolute_path());
builder.append('\n');
});
return builder.to_byte_buffer();
}
ByteBuffer procfs$cpuinfo(InodeIdentifier)
{
StringBuilder builder;
{
CPUID cpuid(0);
builder.appendf("cpuid: ");
auto emit_dword = [&](dword value) {
builder.appendf("%c%c%c%c",
value & 0xff,
(value >> 8) & 0xff,
(value >> 16) & 0xff,
(value >> 24) & 0xff);
};
emit_dword(cpuid.ebx());
emit_dword(cpuid.edx());
emit_dword(cpuid.ecx());
builder.appendf("\n");
}
{
CPUID cpuid(1);
dword stepping = cpuid.eax() & 0xf;
dword model = (cpuid.eax() >> 4) & 0xf;
dword family = (cpuid.eax() >> 8) & 0xf;
dword type = (cpuid.eax() >> 12) & 0x3;
dword extended_model = (cpuid.eax() >> 16) & 0xf;
dword extended_family = (cpuid.eax() >> 20) & 0xff;
dword display_model;
dword display_family;
if (family == 15) {
display_family = family + extended_family;
display_model = model + (extended_model << 4);
} else if (family == 6) {
display_family = family;
display_model = model + (extended_model << 4);
} else {
display_family = family;
display_model = model;
}
builder.appendf("family: %u\n", display_family);
builder.appendf("model: %u\n", display_model);
builder.appendf("stepping: %u\n", stepping);
builder.appendf("type: %u\n", type);
}
{
// FIXME: Check first that this is supported by calling CPUID with eax=0x80000000
// and verifying that the returned eax>=0x80000004.
char buffer[48];
dword* bufptr = reinterpret_cast<dword*>(buffer);
auto copy_brand_string_part_to_buffer = [&](dword i) {
CPUID cpuid(0x80000002 + i);
*bufptr++ = cpuid.eax();
*bufptr++ = cpuid.ebx();
*bufptr++ = cpuid.ecx();
*bufptr++ = cpuid.edx();
};
copy_brand_string_part_to_buffer(0);
copy_brand_string_part_to_buffer(1);
copy_brand_string_part_to_buffer(2);
builder.appendf("brandstr: \"%s\"\n", buffer);
}
return builder.to_byte_buffer();
}
ByteBuffer procfs$kmalloc(InodeIdentifier)
{
StringBuilder builder;
builder.appendf(
"eternal: %u\n"
"allocated: %u\n"
"free: %u\n",
kmalloc_sum_eternal,
sum_alloc,
sum_free);
return builder.to_byte_buffer();
}
ByteBuffer procfs$summary(InodeIdentifier)
{
InterruptDisabler disabler;
auto processes = Process::all_processes();
StringBuilder builder;
builder.appendf("PID TPG PGP SID OWNER STATE PPID NSCHED FDS TTY NAME\n");
for (auto* process : processes) {
builder.appendf("%-3u %-3u %-3u %-3u %-4u %-8s %-3u %-9u %-3u %-4s %s\n",
process->pid(),
process->tty() ? process->tty()->pgid() : 0,
process->pgid(),
process->sid(),
process->uid(),
to_string(process->state()),
process->ppid(),
process->main_thread().times_scheduled(), // FIXME(Thread): Bill all scheds to the process
process->number_of_open_file_descriptors(),
process->tty() ? strrchr(process->tty()->tty_name().characters(), '/') + 1 : "n/a",
process->name().characters());
}
return builder.to_byte_buffer();
}
ByteBuffer procfs$memstat(InodeIdentifier)
{
InterruptDisabler disabler;
StringBuilder builder(128);
builder.appendf("%u,%u,%u,%u,%u,%u,%u,%u,%u\n",
kmalloc_sum_eternal,
sum_alloc,
sum_free,
MM.user_physical_pages_used(),
MM.user_physical_pages() - MM.user_physical_pages_used(),
MM.super_physical_pages_used(),
MM.super_physical_pages() - MM.super_physical_pages_used(),
g_kmalloc_call_count,
g_kfree_call_count);
return builder.to_byte_buffer();
}
ByteBuffer procfs$all(InodeIdentifier)
{
InterruptDisabler disabler;
auto processes = Process::all_processes();
StringBuilder builder(processes.size() * 80);
auto build_process_line = [&builder](Process* process) {
builder.appendf("%u,%u,%u,%u,%u,%u,%u,%s,%u,%u,%s,%s,%u,%u,%u,%u,%s,%u\n",
process->pid(),
process->main_thread().times_scheduled(), // FIXME(Thread): Bill all scheds to the process
process->tty() ? process->tty()->pgid() : 0,
process->pgid(),
process->sid(),
process->uid(),
process->gid(),
to_string(process->state()),
process->ppid(),
process->number_of_open_file_descriptors(),
process->tty() ? process->tty()->tty_name().characters() : "notty",
process->name().characters(),
process->amount_virtual(),
process->amount_resident(),
process->amount_shared(),
process->main_thread().ticks(), // FIXME(Thread): Bill all ticks to the process
to_string(process->priority()),
process->syscall_count());
};
build_process_line(Scheduler::colonel());
for (auto* process : processes)
build_process_line(process);
return builder.to_byte_buffer();
}
ByteBuffer procfs$inodes(InodeIdentifier)
{
extern HashTable<Inode*>& all_inodes();
StringBuilder builder;
for (auto it : all_inodes()) {
RefPtr<Inode> inode = *it;
builder.appendf("Inode{K%x} %02u:%08u (%u)\n", inode.ptr(), inode->fsid(), inode->index(), inode->ref_count());
}
return builder.to_byte_buffer();
}
struct SysVariableData final : public ProcFSInodeCustomData {
virtual ~SysVariableData() override {}
enum Type {
Invalid,
Boolean,
String,
};
Type type { Invalid };
Function<void()> notify_callback;
void* address;
};
static ByteBuffer read_sys_bool(InodeIdentifier inode_id)
{
auto inode_ptr = ProcFS::the().get_inode(inode_id);
if (!inode_ptr)
return {};
auto& inode = static_cast<ProcFSInode&>(*inode_ptr);
ASSERT(inode.custom_data());
auto buffer = ByteBuffer::create_uninitialized(2);
auto& custom_data = *static_cast<const SysVariableData*>(inode.custom_data());
ASSERT(custom_data.type == SysVariableData::Boolean);
ASSERT(custom_data.address);
auto* lockable_bool = reinterpret_cast<Lockable<bool>*>(custom_data.address);
{
LOCKER(lockable_bool->lock());
buffer[0] = lockable_bool->resource() ? '1' : '0';
}
buffer[1] = '\n';
return buffer;
}
static ssize_t write_sys_bool(InodeIdentifier inode_id, const ByteBuffer& data)
{
auto inode_ptr = ProcFS::the().get_inode(inode_id);
if (!inode_ptr)
return {};
auto& inode = static_cast<ProcFSInode&>(*inode_ptr);
ASSERT(inode.custom_data());
if (data.is_empty() || !(data[0] == '0' || data[0] == '1'))
return data.size();
auto& custom_data = *static_cast<const SysVariableData*>(inode.custom_data());
auto* lockable_bool = reinterpret_cast<Lockable<bool>*>(custom_data.address);
{
LOCKER(lockable_bool->lock());
lockable_bool->resource() = data[0] == '1';
}
if (custom_data.notify_callback)
custom_data.notify_callback();
return data.size();
}
static ByteBuffer read_sys_string(InodeIdentifier inode_id)
{
auto inode_ptr = ProcFS::the().get_inode(inode_id);
if (!inode_ptr)
return {};
auto& inode = static_cast<ProcFSInode&>(*inode_ptr);
ASSERT(inode.custom_data());
auto buffer = ByteBuffer::create_uninitialized(2);
auto& custom_data = *static_cast<const SysVariableData*>(inode.custom_data());
ASSERT(custom_data.type == SysVariableData::String);
ASSERT(custom_data.address);
auto* lockable_string = reinterpret_cast<Lockable<String>*>(custom_data.address);
LOCKER(lockable_string->lock());
return lockable_string->resource().to_byte_buffer();
}
static ssize_t write_sys_string(InodeIdentifier inode_id, const ByteBuffer& data)
{
auto inode_ptr = ProcFS::the().get_inode(inode_id);
if (!inode_ptr)
return {};
auto& inode = static_cast<ProcFSInode&>(*inode_ptr);
ASSERT(inode.custom_data());
auto& custom_data = *static_cast<const SysVariableData*>(inode.custom_data());
ASSERT(custom_data.address);
{
auto* lockable_string = reinterpret_cast<Lockable<String>*>(custom_data.address);
LOCKER(lockable_string->lock());
lockable_string->resource() = String((const char*)data.pointer(), data.size());
}
if (custom_data.notify_callback)
custom_data.notify_callback();
return data.size();
}
void ProcFS::add_sys_bool(String&& name, Lockable<bool>& var, Function<void()>&& notify_callback)
{
InterruptDisabler disabler;
int index = m_sys_entries.size();
auto inode = adopt(*new ProcFSInode(*this, sys_var_to_identifier(fsid(), index).index()));
auto data = make<SysVariableData>();
data->type = SysVariableData::Boolean;
data->notify_callback = move(notify_callback);
data->address = &var;
inode->set_custom_data(move(data));
m_sys_entries.append({ strdup(name.characters()), 0, read_sys_bool, write_sys_bool, move(inode) });
}
void ProcFS::add_sys_string(String&& name, Lockable<String>& var, Function<void()>&& notify_callback)
{
InterruptDisabler disabler;
int index = m_sys_entries.size();
auto inode = adopt(*new ProcFSInode(*this, sys_var_to_identifier(fsid(), index).index()));
auto data = make<SysVariableData>();
data->type = SysVariableData::String;
data->notify_callback = move(notify_callback);
data->address = &var;
inode->set_custom_data(move(data));
m_sys_entries.append({ strdup(name.characters()), 0, read_sys_string, write_sys_string, move(inode) });
}
bool ProcFS::initialize()
{
return true;
}
const char* ProcFS::class_name() const
{
return "ProcFS";
}
RefPtr<Inode> ProcFS::create_inode(InodeIdentifier, const String&, mode_t, off_t, dev_t, int&)
{
kprintf("FIXME: Implement ProcFS::create_inode()?\n");
return {};
}
RefPtr<Inode> ProcFS::create_directory(InodeIdentifier, const String&, mode_t, int& error)
{
error = -EROFS;
return nullptr;
}
InodeIdentifier ProcFS::root_inode() const
{
return { fsid(), FI_Root };
}
RefPtr<Inode> ProcFS::get_inode(InodeIdentifier inode_id) const
{
#ifdef PROCFS_DEBUG
dbgprintf("ProcFS::get_inode(%u)\n", inode_id.index());
#endif
if (inode_id == root_inode())
return m_root_inode;
if (to_proc_parent_directory(inode_id) == ProcParentDirectory::PDI_Root_sys) {
auto sys_index = to_sys_index(inode_id);
if (sys_index < m_sys_entries.size())
return m_sys_entries[sys_index].inode;
}
LOCKER(m_inodes_lock);
auto it = m_inodes.find(inode_id.index());
if (it == m_inodes.end()) {
auto inode = adopt(*new ProcFSInode(const_cast<ProcFS&>(*this), inode_id.index()));
m_inodes.set(inode_id.index(), inode.ptr());
return inode;
}
return (*it).value;
}
ProcFSInode::ProcFSInode(ProcFS& fs, unsigned index)
: Inode(fs, index)
{
}
ProcFSInode::~ProcFSInode()
{
LOCKER(fs().m_inodes_lock);
fs().m_inodes.remove(index());
}
InodeMetadata ProcFSInode::metadata() const
{
#ifdef PROCFS_DEBUG
dbgprintf("ProcFSInode::metadata(%u)\n", index());
#endif
InodeMetadata metadata;
metadata.inode = identifier();
metadata.ctime = mepoch;
metadata.atime = mepoch;
metadata.mtime = mepoch;
auto proc_parent_directory = to_proc_parent_directory(identifier());
auto pid = to_pid(identifier());
auto proc_file_type = to_proc_file_type(identifier());
#ifdef PROCFS_DEBUG
dbgprintf(" -> pid: %d, fi: %u, pdi: %u\n", pid, proc_file_type, proc_parent_directory);
#endif
if (is_process_related_file(identifier())) {
auto handle = ProcessInspectionHandle::from_pid(pid);
metadata.uid = handle->process().sys$getuid();
metadata.gid = handle->process().sys$getgid();
}
if (proc_parent_directory == PDI_PID_fd) {
metadata.mode = 00120777;
return metadata;
}
if (proc_parent_directory == PDI_Root_sys) {
metadata.mode = 00100644;
return metadata;
}
switch (proc_file_type) {
case FI_Root_self:
case FI_PID_cwd:
case FI_PID_exe:
metadata.mode = 0120777;
break;
case FI_Root:
case FI_Root_sys:
case FI_PID:
case FI_PID_fd:
metadata.mode = 040777;
break;
default:
metadata.mode = 0100644;
break;
}
#ifdef PROCFS_DEBUG
dbgprintf("Returning mode %o\n", metadata.mode);
#endif
return metadata;
}
ssize_t ProcFSInode::read_bytes(off_t offset, ssize_t count, byte* buffer, FileDescription* description) const
{
#ifdef PROCFS_DEBUG
dbgprintf("ProcFS: read_bytes %u\n", index());
#endif
ASSERT(offset >= 0);
ASSERT(buffer);
auto* directory_entry = fs().get_directory_entry(identifier());
Function<ByteBuffer(InodeIdentifier)> callback_tmp;
Function<ByteBuffer(InodeIdentifier)>* read_callback { nullptr };
if (directory_entry) {
read_callback = &directory_entry->read_callback;
} else {
if (to_proc_parent_directory(identifier()) == PDI_PID_fd) {
callback_tmp = procfs$pid_fd_entry;
read_callback = &callback_tmp;
}
}
ASSERT(read_callback);
ByteBuffer generated_data;
if (!description) {
generated_data = (*read_callback)(identifier());
} else {
if (!description->generator_cache())
description->generator_cache() = (*read_callback)(identifier());
generated_data = description->generator_cache();
}
auto& data = generated_data;
ssize_t nread = min(static_cast<off_t>(data.size() - offset), static_cast<off_t>(count));
memcpy(buffer, data.pointer() + offset, nread);
if (nread == 0 && description && description->generator_cache())
description->generator_cache().clear();
return nread;
}
InodeIdentifier ProcFS::ProcFSDirectoryEntry::identifier(unsigned fsid) const
{
return to_identifier(fsid, PDI_Root, 0, (ProcFileType)proc_file_type);
}
bool ProcFSInode::traverse_as_directory(Function<bool(const FS::DirectoryEntry&)> callback) const
{
#ifdef PROCFS_DEBUG
dbgprintf("ProcFS: traverse_as_directory %u\n", index());
#endif
if (!::is_directory(identifier()))
return false;
auto pid = to_pid(identifier());
auto proc_file_type = to_proc_file_type(identifier());
auto parent_id = to_parent_id(identifier());
callback({ ".", 1, identifier(), 2 });
callback({ "..", 2, parent_id, 2 });
switch (proc_file_type) {
case FI_Root:
for (auto& entry : fs().m_entries) {
// FIXME: strlen() here is sad.
if (!entry.name)
continue;
if (entry.proc_file_type > __FI_Root_Start && entry.proc_file_type < __FI_Root_End)
callback({ entry.name, (int)strlen(entry.name), to_identifier(fsid(), PDI_Root, 0, (ProcFileType)entry.proc_file_type), 0 });
}
for (auto pid_child : Process::all_pids()) {
char name[16];
int name_length = ksprintf(name, "%u", pid_child);
callback({ name, name_length, to_identifier(fsid(), PDI_Root, pid_child, FI_PID), 0 });
}
break;
case FI_Root_sys:
for (int i = 0; i < fs().m_sys_entries.size(); ++i) {
auto& entry = fs().m_sys_entries[i];
callback({ entry.name, (int)strlen(entry.name), sys_var_to_identifier(fsid(), i), 0 });
}
break;
case FI_PID: {
auto handle = ProcessInspectionHandle::from_pid(pid);
if (!handle)
return false;
auto& process = handle->process();
for (auto& entry : fs().m_entries) {
if (entry.proc_file_type > __FI_PID_Start && entry.proc_file_type < __FI_PID_End) {
if (entry.proc_file_type == FI_PID_exe && !process.executable())
continue;
// FIXME: strlen() here is sad.
callback({ entry.name, (int)strlen(entry.name), to_identifier(fsid(), PDI_PID, pid, (ProcFileType)entry.proc_file_type), 0 });
}
}
} break;
case FI_PID_fd: {
auto handle = ProcessInspectionHandle::from_pid(pid);
if (!handle)
return false;
auto& process = handle->process();
for (int i = 0; i < process.max_open_file_descriptors(); ++i) {
auto* description = process.file_description(i);
if (!description)
continue;
char name[16];
int name_length = ksprintf(name, "%u", i);
callback({ name, name_length, to_identifier_with_fd(fsid(), pid, i), 0 });
}
} break;
default:
return true;
}
return true;
}
InodeIdentifier ProcFSInode::lookup(StringView name)
{
ASSERT(is_directory());
if (name == ".")
return identifier();
if (name == "..")
return to_parent_id(identifier());
auto proc_file_type = to_proc_file_type(identifier());
if (proc_file_type == FI_Root) {
for (auto& entry : fs().m_entries) {
if (entry.name == nullptr)
continue;
if (entry.proc_file_type > __FI_Root_Start && entry.proc_file_type < __FI_Root_End) {
if (name == entry.name) {
return to_identifier(fsid(), PDI_Root, 0, (ProcFileType)entry.proc_file_type);
}
}
}
bool ok;
unsigned name_as_number = name.to_uint(ok);
if (ok) {
bool process_exists = false;
{
InterruptDisabler disabler;
process_exists = Process::from_pid(name_as_number);
}
if (process_exists)
return to_identifier(fsid(), PDI_Root, name_as_number, FI_PID);
}
return {};
}
if (proc_file_type == FI_Root_sys) {
for (int i = 0; i < fs().m_sys_entries.size(); ++i) {
auto& entry = fs().m_sys_entries[i];
if (name == entry.name)
return sys_var_to_identifier(fsid(), i);
}
return {};
}
if (proc_file_type == FI_PID) {
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier()));
if (!handle)
return {};
auto& process = handle->process();
for (auto& entry : fs().m_entries) {
if (entry.proc_file_type > __FI_PID_Start && entry.proc_file_type < __FI_PID_End) {
if (entry.proc_file_type == FI_PID_exe && !process.executable())
continue;
if (entry.name == nullptr)
continue;
if (name == entry.name) {
return to_identifier(fsid(), PDI_PID, to_pid(identifier()), (ProcFileType)entry.proc_file_type);
}
}
}
return {};
}
if (proc_file_type == FI_PID_fd) {
bool ok;
unsigned name_as_number = name.to_uint(ok);
if (ok) {
bool fd_exists = false;
{
InterruptDisabler disabler;
if (auto* process = Process::from_pid(to_pid(identifier())))
fd_exists = process->file_description(name_as_number);
}
if (fd_exists)
return to_identifier_with_fd(fsid(), to_pid(identifier()), name_as_number);
}
}
return {};
}
void ProcFSInode::flush_metadata()
{
}
ssize_t ProcFSInode::write_bytes(off_t offset, ssize_t size, const byte* buffer, FileDescription*)
{
auto* directory_entry = fs().get_directory_entry(identifier());
if (!directory_entry || !directory_entry->write_callback)
return -EPERM;
ASSERT(is_persistent_inode(identifier()));
// FIXME: Being able to write into ProcFS at a non-zero offset seems like something we should maybe support..
ASSERT(offset == 0);
bool success = directory_entry->write_callback(identifier(), ByteBuffer::wrap(buffer, size));
ASSERT(success);
return 0;
}
KResult ProcFSInode::add_child(InodeIdentifier child_id, const StringView& name, mode_t)
{
(void)child_id;
(void)name;
return KResult(-EPERM);
}
KResult ProcFSInode::remove_child(const StringView& name)
{
(void)name;
return KResult(-EPERM);
}
ProcFSInodeCustomData::~ProcFSInodeCustomData()
{
}
size_t ProcFSInode::directory_entry_count() const
{
ASSERT(is_directory());
size_t count = 0;
traverse_as_directory([&count](const FS::DirectoryEntry&) {
++count;
return true;
});
return count;
}
KResult ProcFSInode::chmod(mode_t)
{
return KResult(-EPERM);
}
ProcFS::ProcFS()
{
s_the = this;
m_root_inode = adopt(*new ProcFSInode(*this, 1));
m_entries.resize(FI_MaxStaticFileIndex);
m_entries[FI_Root_mm] = { "mm", FI_Root_mm, procfs$mm };
m_entries[FI_Root_mounts] = { "mounts", FI_Root_mounts, procfs$mounts };
m_entries[FI_Root_df] = { "df", FI_Root_df, procfs$df };
m_entries[FI_Root_kmalloc] = { "kmalloc", FI_Root_kmalloc, procfs$kmalloc };
m_entries[FI_Root_all] = { "all", FI_Root_all, procfs$all };
m_entries[FI_Root_memstat] = { "memstat", FI_Root_memstat, procfs$memstat };
m_entries[FI_Root_summary] = { "summary", FI_Root_summary, procfs$summary };
m_entries[FI_Root_cpuinfo] = { "cpuinfo", FI_Root_cpuinfo, procfs$cpuinfo };
m_entries[FI_Root_inodes] = { "inodes", FI_Root_inodes, procfs$inodes };
m_entries[FI_Root_dmesg] = { "dmesg", FI_Root_dmesg, procfs$dmesg };
m_entries[FI_Root_self] = { "self", FI_Root_self, procfs$self };
m_entries[FI_Root_pci] = { "pci", FI_Root_pci, procfs$pci };
m_entries[FI_Root_uptime] = { "uptime", FI_Root_uptime, procfs$uptime };
m_entries[FI_Root_cmdline] = { "cmdline", FI_Root_cmdline, procfs$cmdline };
m_entries[FI_Root_netadapters] = { "netadapters", FI_Root_netadapters, procfs$netadapters };
m_entries[FI_Root_sys] = { "sys", FI_Root_sys };
m_entries[FI_PID_vm] = { "vm", FI_PID_vm, procfs$pid_vm };
m_entries[FI_PID_vmo] = { "vmo", FI_PID_vmo, procfs$pid_vmo };
m_entries[FI_PID_stack] = { "stack", FI_PID_stack, procfs$pid_stack };
m_entries[FI_PID_regs] = { "regs", FI_PID_regs, procfs$pid_regs };
m_entries[FI_PID_fds] = { "fds", FI_PID_fds, procfs$pid_fds };
m_entries[FI_PID_exe] = { "exe", FI_PID_exe, procfs$pid_exe };
m_entries[FI_PID_cwd] = { "cwd", FI_PID_cwd, procfs$pid_cwd };
m_entries[FI_PID_fd] = { "fd", FI_PID_fd };
m_kmalloc_stack_helper.resource() = g_dump_kmalloc_stacks;
add_sys_bool("kmalloc_stacks", m_kmalloc_stack_helper, [this] {
g_dump_kmalloc_stacks = m_kmalloc_stack_helper.resource();
});
}
ProcFS::ProcFSDirectoryEntry* ProcFS::get_directory_entry(InodeIdentifier identifier) const
{
if (to_proc_parent_directory(identifier) == PDI_Root_sys) {
auto sys_index = to_sys_index(identifier);
if (sys_index < m_sys_entries.size())
return const_cast<ProcFSDirectoryEntry*>(&m_sys_entries[sys_index]);
return nullptr;
}
auto proc_file_type = to_proc_file_type(identifier);
if (proc_file_type != FI_Invalid && proc_file_type < FI_MaxStaticFileIndex)
return const_cast<ProcFSDirectoryEntry*>(&m_entries[proc_file_type]);
return nullptr;
}
KResult ProcFSInode::chown(uid_t, gid_t)
{
return KResult(-EPERM);
}