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ladybird/Kernel/FileSystem/ProcFS.cpp
Andreas Kling 94ca55cefd Meta: Add license header to source files 
As suggested by Joshua, this commit adds the 2-clause BSD license as a
comment block to the top of every source file.

For the first pass, I've just added myself for simplicity. I encourage
everyone to add themselves as copyright holders of any file they've
added or modified in some significant way. If I've added myself in
error somewhere, feel free to replace it with the appropriate copyright
holder instead.

Going forward, all new source files should include a license header.
2020-01-18 09:45:54 +01:00

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/*
* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
* All rights reserved.
*
* Redistribution and use in source and binary forms, with or without
* modification, are permitted provided that the following conditions are met:
*
* 1. Redistributions of source code must retain the above copyright notice, this
* list of conditions and the following disclaimer.
*
* 2. Redistributions in binary form must reproduce the above copyright notice,
* this list of conditions and the following disclaimer in the documentation
* and/or other materials provided with the distribution.
*
* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS"
* AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE
* IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE
* DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE
* FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL
* DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR
* SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER
* CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
* OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*/
#include "ProcFS.h"
#include "Console.h"
#include "KSyms.h"
#include "Process.h"
#include "Scheduler.h"
#include "StdLib.h"
#include <AK/JsonArraySerializer.h>
#include <AK/JsonObject.h>
#include <AK/JsonObjectSerializer.h>
#include <AK/JsonValue.h>
#include <Kernel/Arch/i386/CPU.h>
#include <Kernel/FileSystem/Custody.h>
#include <Kernel/FileSystem/DiskBackedFileSystem.h>
#include <Kernel/FileSystem/FileDescription.h>
#include <Kernel/FileSystem/VirtualFileSystem.h>
#include <Kernel/Heap/kmalloc.h>
#include <Kernel/KBufferBuilder.h>
#include <Kernel/KParams.h>
#include <Kernel/Module.h>
#include <Kernel/Net/LocalSocket.h>
#include <Kernel/Net/NetworkAdapter.h>
#include <Kernel/Net/Routing.h>
#include <Kernel/Net/TCPSocket.h>
#include <Kernel/Net/UDPSocket.h>
#include <Kernel/PCI/Access.h>
#include <Kernel/Profiling.h>
#include <Kernel/VM/MemoryManager.h>
#include <Kernel/VM/PurgeableVMObject.h>
#include <LibC/errno_numbers.h>
enum ProcParentDirectory {
PDI_AbstractRoot = 0,
PDI_Root,
PDI_Root_sys,
PDI_Root_net,
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_all,
FI_Root_memstat,
FI_Root_cpuinfo,
FI_Root_inodes,
FI_Root_dmesg,
FI_Root_pci,
FI_Root_devices,
FI_Root_uptime,
FI_Root_cmdline,
FI_Root_modules,
FI_Root_profile,
FI_Root_self, // symlink
FI_Root_sys, // directory
FI_Root_net, // directory
__FI_Root_End,
FI_Root_sys_variable,
FI_Root_net_adapters,
FI_Root_net_arp,
FI_Root_net_tcp,
FI_Root_net_udp,
FI_Root_net_local,
FI_PID,
__FI_PID_Start,
FI_PID_vm,
FI_PID_vmobjects,
FI_PID_stack,
FI_PID_regs,
FI_PID_fds,
FI_PID_exe, // symlink
FI_PID_cwd, // symlink
FI_PID_root, // 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 ProcFileType to_proc_file_type(const InodeIdentifier& identifier)
{
return (ProcFileType)(identifier.index() & 0xff);
}
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);
ASSERT(to_proc_file_type(identifier) == FI_Root_sys_variable);
return identifier.index() >> 16u;
}
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 << 16u) | FI_Root_sys_variable };
}
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_Root_net:
return { identifier.fsid(), FI_Root_net };
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 u8 to_unused_metadata(const InodeIdentifier& identifier)
{
return (identifier.index() >> 8) & 0xf;
}
#endif
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_Root_net:
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;
}
NonnullRefPtr<ProcFS> ProcFS::create()
{
return adopt(*new ProcFS);
}
ProcFS::~ProcFS()
{
}
Optional<KBuffer> procfs$pid_fds(InodeIdentifier identifier)
{
KBufferBuilder builder;
JsonArraySerializer array { builder };
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle) {
array.finish();
return builder.build();
}
auto& process = handle->process();
if (process.number_of_open_file_descriptors() == 0) {
array.finish();
return builder.build();
}
for (int i = 0; i < process.max_open_file_descriptors(); ++i) {
auto description = process.file_description(i);
if (!description)
continue;
bool cloexec = process.fd_flags(i) & FD_CLOEXEC;
auto description_object = array.add_object();
description_object.add("fd", i);
description_object.add("absolute_path", description->absolute_path());
description_object.add("seekable", description->file().is_seekable());
description_object.add("class", description->file().class_name());
description_object.add("offset", description->offset());
description_object.add("cloexec", cloexec);
description_object.add("blocking", description->is_blocking());
description_object.add("can_read", description->can_read());
description_object.add("can_write", description->can_write());
}
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$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();
}
Optional<KBuffer> procfs$pid_vm(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
KBufferBuilder builder;
JsonArraySerializer array { builder };
for (auto& region : process.regions()) {
if (!region.is_user_accessible() && !current->process().is_superuser())
continue;
auto region_object = array.add_object();
region_object.add("readable", region.is_readable());
region_object.add("writable", region.is_writable());
region_object.add("executable", region.is_executable());
region_object.add("stack", region.is_stack());
region_object.add("shared", region.is_shared());
region_object.add("user_accessible", region.is_user_accessible());
region_object.add("purgeable", region.vmobject().is_purgeable());
if (region.vmobject().is_purgeable()) {
region_object.add("volatile", static_cast<const PurgeableVMObject&>(region.vmobject()).is_volatile());
}
region_object.add("purgeable", region.vmobject().is_purgeable());
region_object.add("address", region.vaddr().get());
region_object.add("size", (u32)region.size());
region_object.add("amount_resident", (u32)region.amount_resident());
region_object.add("amount_dirty", (u32)region.amount_dirty());
region_object.add("cow_pages", region.cow_pages());
region_object.add("name", region.name());
}
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$pci(InodeIdentifier)
{
KBufferBuilder builder;
JsonArraySerializer array { builder };
PCI::enumerate_all([&array](PCI::Address address, PCI::ID id) {
auto obj = array.add_object();
obj.add("seg", address.seg());
obj.add("bus", address.bus());
obj.add("slot", address.slot());
obj.add("function", address.function());
obj.add("vendor_id", id.vendor_id);
obj.add("device_id", id.device_id);
obj.add("revision_id", PCI::get_revision_id(address));
obj.add("subclass", PCI::get_subclass(address));
obj.add("class", PCI::get_class(address));
obj.add("subsystem_id", PCI::get_subsystem_id(address));
obj.add("subsystem_vendor_id", PCI::get_subsystem_vendor_id(address));
});
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$devices(InodeIdentifier)
{
KBufferBuilder builder;
JsonArraySerializer array { builder };
Device::for_each([&array](auto& device) {
auto obj = array.add_object();
obj.add("major", device.major());
obj.add("minor", device.minor());
obj.add("class_name", device.class_name());
if (device.is_block_device())
obj.add("type", "block");
else if (device.is_character_device())
obj.add("type", "character");
else
ASSERT_NOT_REACHED();
});
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$uptime(InodeIdentifier)
{
KBufferBuilder builder;
builder.appendf("%u\n", (u32)(g_uptime / 1000));
return builder.build();
}
Optional<KBuffer> procfs$cmdline(InodeIdentifier)
{
KBufferBuilder builder;
builder.appendf("%s\n", KParams::the().cmdline().characters());
return builder.build();
}
Optional<KBuffer> procfs$modules(InodeIdentifier)
{
extern HashMap<String, OwnPtr<Module>>* g_modules;
KBufferBuilder builder;
JsonArraySerializer array { builder };
for (auto& it : *g_modules) {
auto obj = array.add_object();
obj.add("name", it.value->name);
obj.add("module_init", (u32)it.value->module_init);
obj.add("module_fini", (u32)it.value->module_fini);
u32 size = 0;
for (auto& section : it.value->sections) {
size += section.capacity();
}
obj.add("size", size);
}
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$profile(InodeIdentifier)
{
InterruptDisabler disabler;
KBufferBuilder builder;
JsonArraySerializer array(builder);
bool mask_kernel_addresses = !current->process().is_superuser();
Profiling::for_each_sample([&](auto& sample) {
auto object = array.add_object();
object.add("pid", sample.pid);
object.add("tid", sample.tid);
object.add("timestamp", sample.timestamp);
auto frames_array = object.add_array("frames");
for (size_t i = 0; i < Profiling::max_stack_frame_count; ++i) {
if (sample.frames[i] == 0)
break;
auto frame_object = frames_array.add_object();
u32 address = (u32)sample.frames[i];
if (mask_kernel_addresses && !is_user_address(VirtualAddress(address)))
address = 0xdeadc0de;
frame_object.add("address", address);
frame_object.add("symbol", sample.symbolicated_frames[i]);
frame_object.add("offset", JsonValue((u32)sample.offsets[i]));
frame_object.finish();
}
frames_array.finish();
});
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$net_adapters(InodeIdentifier)
{
KBufferBuilder builder;
JsonArraySerializer array { builder };
NetworkAdapter::for_each([&array](auto& adapter) {
auto obj = array.add_object();
obj.add("name", adapter.name());
obj.add("class_name", adapter.class_name());
obj.add("mac_address", adapter.mac_address().to_string());
if (!adapter.ipv4_address().is_zero()) {
obj.add("ipv4_address", adapter.ipv4_address().to_string());
obj.add("ipv4_netmask", adapter.ipv4_netmask().to_string());
}
if (!adapter.ipv4_gateway().is_zero())
obj.add("ipv4_gateway", adapter.ipv4_gateway().to_string());
obj.add("packets_in", adapter.packets_in());
obj.add("bytes_in", adapter.bytes_in());
obj.add("packets_out", adapter.packets_out());
obj.add("bytes_out", adapter.bytes_out());
obj.add("link_up", adapter.link_up());
obj.add("mtu", adapter.mtu());
});
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$net_arp(InodeIdentifier)
{
KBufferBuilder builder;
JsonArraySerializer array { builder };
LOCKER(arp_table().lock());
for (auto& it : arp_table().resource()) {
auto obj = array.add_object();
obj.add("mac_address", it.value.to_string());
obj.add("ip_address", it.key.to_string());
}
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$net_tcp(InodeIdentifier)
{
KBufferBuilder builder;
JsonArraySerializer array { builder };
TCPSocket::for_each([&array](auto& socket) {
auto obj = array.add_object();
obj.add("local_address", socket.local_address().to_string());
obj.add("local_port", socket.local_port());
obj.add("peer_address", socket.peer_address().to_string());
obj.add("peer_port", socket.peer_port());
obj.add("state", TCPSocket::to_string(socket.state()));
obj.add("ack_number", socket.ack_number());
obj.add("sequence_number", socket.sequence_number());
obj.add("packets_in", socket.packets_in());
obj.add("bytes_in", socket.bytes_in());
obj.add("packets_out", socket.packets_out());
obj.add("bytes_out", socket.bytes_out());
});
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$net_udp(InodeIdentifier)
{
KBufferBuilder builder;
JsonArraySerializer array { builder };
UDPSocket::for_each([&array](auto& socket) {
auto obj = array.add_object();
obj.add("local_address", socket.local_address().to_string());
obj.add("local_port", socket.local_port());
obj.add("peer_address", socket.peer_address().to_string());
obj.add("peer_port", socket.peer_port());
});
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$net_local(InodeIdentifier)
{
KBufferBuilder builder;
JsonArraySerializer array { builder };
LocalSocket::for_each([&array](auto& socket) {
auto obj = array.add_object();
obj.add("path", String(socket.socket_path()));
obj.add("origin_pid", socket.origin_pid());
obj.add("origin_uid", socket.origin_uid());
obj.add("origin_gid", socket.origin_gid());
obj.add("acceptor_pid", socket.acceptor_pid());
obj.add("acceptor_uid", socket.acceptor_uid());
obj.add("acceptor_gid", socket.acceptor_gid());
});
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$pid_vmobjects(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
KBufferBuilder builder;
builder.appendf("BEGIN END SIZE NAME\n");
for (auto& region : process.regions()) {
builder.appendf("%x -- %x %x %s\n",
region.vaddr().get(),
region.vaddr().offset(region.size() - 1).get(),
region.size(),
region.name().characters());
builder.appendf("VMO: %s @ %x(%u)\n",
region.vmobject().is_anonymous() ? "anonymous" : "file-backed",
&region.vmobject(),
region.vmobject().ref_count());
for (size_t i = 0; i < region.vmobject().page_count(); ++i) {
auto& physical_page = region.vmobject().physical_pages()[i];
builder.appendf("P%x%s(%u) ",
physical_page ? physical_page->paddr().get() : 0,
region.should_cow(i) ? "!" : "",
physical_page ? physical_page->ref_count() : 0);
}
builder.appendf("\n");
}
return builder.build();
}
Optional<KBuffer> procfs$pid_stack(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
return process.backtrace(*handle);
}
Optional<KBuffer> procfs$pid_regs(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
auto& process = handle->process();
KBufferBuilder builder;
process.for_each_thread([&](Thread& thread) {
builder.appendf("Thread %d:\n", thread.tid());
auto& tss = thread.tss();
builder.appendf("eax: %x\n", tss.eax);
builder.appendf("ebx: %x\n", tss.ebx);
builder.appendf("ecx: %x\n", tss.ecx);
builder.appendf("edx: %x\n", tss.edx);
builder.appendf("esi: %x\n", tss.esi);
builder.appendf("edi: %x\n", tss.edi);
builder.appendf("ebp: %x\n", tss.ebp);
builder.appendf("cr3: %x\n", tss.cr3);
builder.appendf("flg: %x\n", tss.eflags);
builder.appendf("sp: %w:%x\n", tss.ss, tss.esp);
builder.appendf("pc: %w:%x\n", tss.cs, tss.eip);
return IterationDecision::Continue;
});
return builder.build();
}
Optional<KBuffer> procfs$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();
}
Optional<KBuffer> procfs$pid_cwd(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
return handle->process().current_directory().absolute_path().to_byte_buffer();
}
Optional<KBuffer> procfs$pid_root(InodeIdentifier identifier)
{
auto handle = ProcessInspectionHandle::from_pid(to_pid(identifier));
if (!handle)
return {};
return handle->process().root_directory_relative_to_global_root().absolute_path().to_byte_buffer();
}
Optional<KBuffer> procfs$self(InodeIdentifier)
{
char buffer[16];
sprintf(buffer, "%u", current->pid());
return KBuffer::copy((const u8*)buffer, strlen(buffer));
}
Optional<KBuffer> procfs$mm(InodeIdentifier)
{
InterruptDisabler disabler;
KBufferBuilder builder;
u32 vmobject_count = 0;
MemoryManager::for_each_vmobject([&](auto& vmobject) {
++vmobject_count;
builder.appendf("VMObject: %p %s(%u): p:%4u\n",
&vmobject,
vmobject.is_anonymous() ? "anon" : "file",
vmobject.ref_count(),
vmobject.page_count());
return IterationDecision::Continue;
});
builder.appendf("VMO count: %u\n", vmobject_count);
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.build();
}
Optional<KBuffer> procfs$dmesg(InodeIdentifier)
{
InterruptDisabler disabler;
KBufferBuilder builder;
for (char ch : Console::the().logbuffer())
builder.append(ch);
return builder.build();
}
Optional<KBuffer> procfs$mounts(InodeIdentifier)
{
// FIXME: This is obviously racy against the VFS mounts changing.
KBufferBuilder 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.build();
}
Optional<KBuffer> procfs$df(InodeIdentifier)
{
// FIXME: This is obviously racy against the VFS mounts changing.
KBufferBuilder builder;
JsonArraySerializer array { builder };
VFS::the().for_each_mount([&array](auto& mount) {
auto& fs = mount.guest_fs();
auto fs_object = array.add_object();
fs_object.add("class_name", fs.class_name());
fs_object.add("total_block_count", fs.total_block_count());
fs_object.add("free_block_count", fs.free_block_count());
fs_object.add("total_inode_count", fs.total_inode_count());
fs_object.add("free_inode_count", fs.free_inode_count());
fs_object.add("mount_point", mount.absolute_path());
fs_object.add("block_size", fs.block_size());
fs_object.add("readonly", fs.is_readonly());
fs_object.add("mount_flags", mount.flags());
if (fs.is_disk_backed())
fs_object.add("device", static_cast<const DiskBackedFS&>(fs).device().absolute_path());
else
fs_object.add("device", fs.class_name());
});
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$cpuinfo(InodeIdentifier)
{
KBufferBuilder builder;
{
CPUID cpuid(0);
builder.appendf("cpuid: ");
auto emit_u32 = [&](u32 value) {
builder.appendf("%c%c%c%c",
value & 0xff,
(value >> 8) & 0xff,
(value >> 16) & 0xff,
(value >> 24) & 0xff);
};
emit_u32(cpuid.ebx());
emit_u32(cpuid.edx());
emit_u32(cpuid.ecx());
builder.appendf("\n");
}
{
CPUID cpuid(1);
u32 stepping = cpuid.eax() & 0xf;
u32 model = (cpuid.eax() >> 4) & 0xf;
u32 family = (cpuid.eax() >> 8) & 0xf;
u32 type = (cpuid.eax() >> 12) & 0x3;
u32 extended_model = (cpuid.eax() >> 16) & 0xf;
u32 extended_family = (cpuid.eax() >> 20) & 0xff;
u32 display_model;
u32 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.
alignas(u32) char buffer[48];
u32* bufptr = reinterpret_cast<u32*>(buffer);
auto copy_brand_string_part_to_buffer = [&](u32 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.build();
}
Optional<KBuffer> procfs$memstat(InodeIdentifier)
{
InterruptDisabler disabler;
KBufferBuilder builder;
JsonObjectSerializer<KBufferBuilder> json { builder };
json.add("kmalloc_allocated", (u32)sum_alloc);
json.add("kmalloc_available", (u32)sum_free);
json.add("kmalloc_eternal_allocated", (u32)kmalloc_sum_eternal);
json.add("user_physical_allocated", MM.user_physical_pages_used());
json.add("user_physical_available", MM.user_physical_pages() - MM.user_physical_pages_used());
json.add("super_physical_allocated", MM.super_physical_pages_used());
json.add("super_physical_available", MM.super_physical_pages() - MM.super_physical_pages_used());
json.add("kmalloc_call_count", g_kmalloc_call_count);
json.add("kfree_call_count", g_kfree_call_count);
slab_alloc_stats([&json](size_t slab_size, size_t num_allocated, size_t num_free) {
auto prefix = String::format("slab_%zu", slab_size);
json.add(String::format("%s_num_allocated", prefix.characters()), (u32)num_allocated);
json.add(String::format("%s_num_free", prefix.characters()), (u32)num_free);
});
json.finish();
return builder.build();
}
Optional<KBuffer> procfs$all(InodeIdentifier)
{
InterruptDisabler disabler;
auto processes = Process::all_processes();
KBufferBuilder builder;
JsonArraySerializer array { builder };
// Keep this in sync with CProcessStatistics.
auto build_process = [&](const Process& process) {
auto process_object = array.add_object();
StringBuilder pledge_builder;
#define __ENUMERATE_PLEDGE_PROMISE(promise) \
if (process.has_promised(Pledge::promise)) { \
pledge_builder.append(#promise " "); \
}
ENUMERATE_PLEDGE_PROMISES
#undef __ENUMERATE_PLEDGE_PROMISE
process_object.add("pledge", pledge_builder.to_string());
process_object.add("pid", process.pid());
process_object.add("pgid", process.tty() ? process.tty()->pgid() : 0);
process_object.add("pgp", process.pgid());
process_object.add("sid", process.sid());
process_object.add("uid", process.uid());
process_object.add("gid", process.gid());
process_object.add("ppid", process.ppid());
process_object.add("nfds", process.number_of_open_file_descriptors());
process_object.add("name", process.name());
process_object.add("tty", process.tty() ? process.tty()->tty_name() : "notty");
process_object.add("amount_virtual", (u32)process.amount_virtual());
process_object.add("amount_resident", (u32)process.amount_resident());
process_object.add("amount_dirty_private", (u32)process.amount_dirty_private());
process_object.add("amount_clean_inode", (u32)process.amount_clean_inode());
process_object.add("amount_shared", (u32)process.amount_shared());
process_object.add("amount_purgeable_volatile", (u32)process.amount_purgeable_volatile());
process_object.add("amount_purgeable_nonvolatile", (u32)process.amount_purgeable_nonvolatile());
process_object.add("icon_id", process.icon_id());
auto thread_array = process_object.add_array("threads");
process.for_each_thread([&](const Thread& thread) {
auto thread_object = thread_array.add_object();
thread_object.add("tid", thread.tid());
thread_object.add("name", thread.name());
thread_object.add("times_scheduled", thread.times_scheduled());
thread_object.add("ticks", thread.ticks());
thread_object.add("state", thread.state_string());
thread_object.add("priority", thread.priority());
thread_object.add("effective_priority", thread.effective_priority());
thread_object.add("syscall_count", thread.syscall_count());
thread_object.add("inode_faults", thread.inode_faults());
thread_object.add("zero_faults", thread.zero_faults());
thread_object.add("cow_faults", thread.cow_faults());
thread_object.add("file_read_bytes", thread.file_read_bytes());
thread_object.add("file_write_bytes", thread.file_write_bytes());
thread_object.add("unix_socket_read_bytes", thread.unix_socket_read_bytes());
thread_object.add("unix_socket_write_bytes", thread.unix_socket_write_bytes());
thread_object.add("ipv4_socket_read_bytes", thread.ipv4_socket_read_bytes());
thread_object.add("ipv4_socket_write_bytes", thread.ipv4_socket_write_bytes());
return IterationDecision::Continue;
});
};
build_process(*Scheduler::colonel());
for (auto* process : processes)
build_process(*process);
array.finish();
return builder.build();
}
Optional<KBuffer> procfs$inodes(InodeIdentifier)
{
extern InlineLinkedList<Inode>& all_inodes();
KBufferBuilder builder;
InterruptDisabler disabler;
for (auto& inode : all_inodes()) {
builder.appendf("Inode{K%x} %02u:%08u (%u)\n", &inode, inode.fsid(), inode.index(), inode.ref_count());
}
return builder.build();
}
struct SysVariable {
String name;
enum class Type : u8 {
Invalid,
Boolean,
String,
};
Type type { Type::Invalid };
Function<void()> notify_callback;
void* address { nullptr };
static SysVariable& for_inode(InodeIdentifier);
void notify()
{
if (notify_callback)
notify_callback();
}
};
static Vector<SysVariable, 16>* s_sys_variables;
static inline Vector<SysVariable, 16>& sys_variables()
{
if (s_sys_variables == nullptr) {
s_sys_variables = new Vector<SysVariable, 16>;
s_sys_variables->append({ "", SysVariable::Type::Invalid, nullptr, nullptr });
}
return *s_sys_variables;
}
SysVariable& SysVariable::for_inode(InodeIdentifier id)
{
auto index = to_sys_index(id);
if (index >= sys_variables().size())
return sys_variables()[0];
auto& variable = sys_variables()[index];
ASSERT(variable.address);
return variable;
}
static ByteBuffer read_sys_bool(InodeIdentifier inode_id)
{
auto& variable = SysVariable::for_inode(inode_id);
ASSERT(variable.type == SysVariable::Type::Boolean);
auto buffer = ByteBuffer::create_uninitialized(2);
auto* lockable_bool = reinterpret_cast<Lockable<bool>*>(variable.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& variable = SysVariable::for_inode(inode_id);
ASSERT(variable.type == SysVariable::Type::Boolean);
if (data.is_empty() || !(data[0] == '0' || data[0] == '1'))
return data.size();
auto* lockable_bool = reinterpret_cast<Lockable<bool>*>(variable.address);
{
LOCKER(lockable_bool->lock());
lockable_bool->resource() = data[0] == '1';
}
variable.notify();
return data.size();
}
static ByteBuffer read_sys_string(InodeIdentifier inode_id)
{
auto& variable = SysVariable::for_inode(inode_id);
ASSERT(variable.type == SysVariable::Type::String);
auto* lockable_string = reinterpret_cast<Lockable<String>*>(variable.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& variable = SysVariable::for_inode(inode_id);
ASSERT(variable.type == SysVariable::Type::String);
{
auto* lockable_string = reinterpret_cast<Lockable<String>*>(variable.address);
LOCKER(lockable_string->lock());
lockable_string->resource() = String((const char*)data.data(), data.size());
}
variable.notify();
return data.size();
}
void ProcFS::add_sys_bool(String&& name, Lockable<bool>& var, Function<void()>&& notify_callback)
{
InterruptDisabler disabler;
SysVariable variable;
variable.name = move(name);
variable.type = SysVariable::Type::Boolean;
variable.notify_callback = move(notify_callback);
variable.address = &var;
sys_variables().append(move(variable));
}
void ProcFS::add_sys_string(String&& name, Lockable<String>& var, Function<void()>&& notify_callback)
{
InterruptDisabler disabler;
SysVariable variable;
variable.name = move(name);
variable.type = SysVariable::Type::String;
variable.notify_callback = move(notify_callback);
variable.address = &var;
sys_variables().append(move(variable));
}
bool ProcFS::initialize()
{
static Lockable<bool>* kmalloc_stack_helper;
if (kmalloc_stack_helper == nullptr) {
kmalloc_stack_helper = new Lockable<bool>();
kmalloc_stack_helper->resource() = g_dump_kmalloc_stacks;
ProcFS::add_sys_bool("kmalloc_stacks", *kmalloc_stack_helper, [] {
g_dump_kmalloc_stacks = kmalloc_stack_helper->resource();
});
}
return true;
}
const char* ProcFS::class_name() const
{
return "ProcFS";
}
RefPtr<Inode> ProcFS::create_inode(InodeIdentifier, const String&, mode_t, off_t, dev_t, uid_t, gid_t, int&)
{
kprintf("FIXME: Implement ProcFS::create_inode()?\n");
return {};
}
RefPtr<Inode> ProcFS::create_directory(InodeIdentifier, const String&, mode_t, uid_t, gid_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;
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$getgid();
}
if (proc_parent_directory == PDI_PID_fd) {
metadata.mode = 00120700;
return metadata;
}
switch (proc_file_type) {
case FI_Root_self:
metadata.mode = 0120444;
break;
case FI_PID_cwd:
case FI_PID_exe:
case FI_PID_root:
metadata.mode = 0120400;
break;
case FI_Root:
case FI_Root_sys:
case FI_Root_net:
metadata.mode = 040555;
break;
case FI_PID:
case FI_PID_fd:
metadata.mode = 040500;
break;
default:
metadata.mode = 0100444;
break;
}
if (proc_file_type > FI_Invalid && proc_file_type < FI_MaxStaticFileIndex) {
if (fs().m_entries[proc_file_type].supervisor_only) {
metadata.uid = 0;
metadata.gid = 0;
metadata.mode &= ~077;
}
}
#ifdef PROCFS_DEBUG
dbgprintf("Returning mode %o\n", metadata.mode);
#endif
return metadata;
}
ssize_t ProcFSInode::read_bytes(off_t offset, ssize_t count, u8* buffer, FileDescription* description) const
{
#ifdef PROCFS_DEBUG
dbgprintf("ProcFS: read_bytes %u\n", index());
#endif
ASSERT(offset >= 0);
ASSERT(buffer);
auto* directory_entry = fs().get_directory_entry(identifier());
Function<Optional<KBuffer>(InodeIdentifier)> callback_tmp;
Function<Optional<KBuffer>(InodeIdentifier)>* read_callback { nullptr };
if (directory_entry)
read_callback = &directory_entry->read_callback;
else
switch (to_proc_parent_directory(identifier())) {
case PDI_PID_fd:
callback_tmp = procfs$pid_fd_entry;
read_callback = &callback_tmp;
break;
case PDI_Root_sys:
switch (SysVariable::for_inode(identifier()).type) {
case SysVariable::Type::Invalid:
ASSERT_NOT_REACHED();
case SysVariable::Type::Boolean:
callback_tmp = read_sys_bool;
break;
case SysVariable::Type::String:
callback_tmp = read_sys_string;
break;
}
read_callback = &callback_tmp;
break;
default:
ASSERT_NOT_REACHED();
}
ASSERT(read_callback);
Optional<KBuffer> 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;
if (!data.has_value())
return 0;
if ((size_t)offset >= data.value().size())
return 0;
ssize_t nread = min(static_cast<off_t>(data.value().size() - offset), static_cast<off_t>(count));
memcpy(buffer, data.value().data() + 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, 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];
size_t name_length = (size_t)sprintf(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 = 1; i < sys_variables().size(); ++i) {
auto& variable = sys_variables()[i];
callback({ variable.name.characters(), variable.name.length(), sys_var_to_identifier(fsid(), i), 0 });
}
break;
case FI_Root_net:
callback({ "adapters", 8, to_identifier(fsid(), PDI_Root_net, 0, FI_Root_net_adapters), 0 });
callback({ "arp", 3, to_identifier(fsid(), PDI_Root_net, 0, FI_Root_net_arp), 0 });
callback({ "tcp", 3, to_identifier(fsid(), PDI_Root_net, 0, FI_Root_net_tcp), 0 });
callback({ "udp", 3, to_identifier(fsid(), PDI_Root_net, 0, FI_Root_net_udp), 0 });
callback({ "local", 5, to_identifier(fsid(), PDI_Root_net, 0, FI_Root_net_local), 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, 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];
size_t name_length = (size_t)sprintf(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 = 1; i < sys_variables().size(); ++i) {
auto& variable = sys_variables()[i];
if (name == variable.name)
return sys_var_to_identifier(fsid(), i);
}
return {};
}
if (proc_file_type == FI_Root_net) {
if (name == "adapters")
return to_identifier(fsid(), PDI_Root, 0, FI_Root_net_adapters);
if (name == "arp")
return to_identifier(fsid(), PDI_Root, 0, FI_Root_net_arp);
if (name == "tcp")
return to_identifier(fsid(), PDI_Root, 0, FI_Root_net_tcp);
if (name == "udp")
return to_identifier(fsid(), PDI_Root, 0, FI_Root_net_udp);
if (name == "local")
return to_identifier(fsid(), PDI_Root, 0, FI_Root_net_local);
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 u8* buffer, FileDescription*)
{
auto* directory_entry = fs().get_directory_entry(identifier());
Function<ssize_t(InodeIdentifier, const ByteBuffer&)> callback_tmp;
Function<ssize_t(InodeIdentifier, const ByteBuffer&)>* write_callback { nullptr };
if (directory_entry == nullptr) {
if (to_proc_parent_directory(identifier()) == PDI_Root_sys) {
switch (SysVariable::for_inode(identifier()).type) {
case SysVariable::Type::Invalid:
ASSERT_NOT_REACHED();
case SysVariable::Type::Boolean:
callback_tmp = write_sys_bool;
break;
case SysVariable::Type::String:
callback_tmp = write_sys_string;
break;
}
write_callback = &callback_tmp;
} else
return -EPERM;
} else {
if (!directory_entry->write_callback)
return -EPERM;
write_callback = &directory_entry->write_callback;
}
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 = (*write_callback)(identifier(), ByteBuffer::wrap(buffer, size));
ASSERT(success);
return 0;
}
KResultOr<NonnullRefPtr<Custody>> ProcFSInode::resolve_as_link(Custody& base, RefPtr<Custody>* out_parent, int options, int symlink_recursion_level) const
{
if (!is_process_related_file(identifier()))
return Inode::resolve_as_link(base, out_parent, options, symlink_recursion_level);
// FIXME: We should return a custody for FI_PID or FI_PID_fd here
// for correctness. It's impossible to create files in ProcFS,
// so returning null shouldn't break much.
if (out_parent)
*out_parent = nullptr;
auto pid = to_pid(identifier());
auto proc_file_type = to_proc_file_type(identifier());
auto handle = ProcessInspectionHandle::from_pid(pid);
if (!handle)
return KResult(-ENOENT);
auto& process = handle->process();
if (to_proc_parent_directory(identifier()) == PDI_PID_fd) {
if (out_parent)
*out_parent = base;
int fd = to_fd(identifier());
auto description = process.file_description(fd);
if (!description)
return KResult(-ENOENT);
auto proxy_inode = ProcFSProxyInode::create(const_cast<ProcFS&>(fs()), *description);
return Custody::create(&base, "", proxy_inode, base.mount_flags());
}
Custody* res = nullptr;
switch (proc_file_type) {
case FI_PID_cwd:
res = &process.current_directory();
break;
case FI_PID_exe:
res = process.executable();
break;
case FI_PID_root:
// Note: we open root_directory() here, not
// root_directory_relative_to_global_root().
// This seems more useful.
res = &process.root_directory();
break;
default:
ASSERT_NOT_REACHED();
}
if (!res)
return KResult(-ENOENT);
return *res;
}
ProcFSProxyInode::ProcFSProxyInode(ProcFS& fs, FileDescription& fd)
: Inode(fs, 0)
, m_fd(fd)
{
}
ProcFSProxyInode::~ProcFSProxyInode()
{
}
InodeMetadata ProcFSProxyInode::metadata() const
{
InodeMetadata metadata = m_fd->metadata();
if (m_fd->is_readable())
metadata.mode |= 0444;
else
metadata.mode &= ~0444;
if (m_fd->is_writable())
metadata.mode |= 0222;
else
metadata.mode &= ~0222;
if (!metadata.is_directory())
metadata.mode &= ~0111;
return metadata;
}
KResult ProcFSProxyInode::add_child(InodeIdentifier child_id, const StringView& name, mode_t mode)
{
if (!m_fd->inode())
return KResult(-EINVAL);
return m_fd->inode()->add_child(child_id, name, mode);
}
KResult ProcFSProxyInode::remove_child(const StringView& name)
{
if (!m_fd->inode())
return KResult(-EINVAL);
return m_fd->inode()->remove_child(name);
}
InodeIdentifier ProcFSProxyInode::lookup(StringView name)
{
if (!m_fd->inode())
return {};
return m_fd->inode()->lookup(name);
}
size_t ProcFSProxyInode::directory_entry_count() const
{
if (!m_fd->inode())
return 0;
return m_fd->inode()->directory_entry_count();
}
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);
}
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()
{
m_root_inode = adopt(*new ProcFSInode(*this, 1));
m_entries.resize(FI_MaxStaticFileIndex);
m_entries[FI_Root_mm] = { "mm", FI_Root_mm, true, procfs$mm };
m_entries[FI_Root_mounts] = { "mounts", FI_Root_mounts, false, procfs$mounts };
m_entries[FI_Root_df] = { "df", FI_Root_df, false, procfs$df };
m_entries[FI_Root_all] = { "all", FI_Root_all, false, procfs$all };
m_entries[FI_Root_memstat] = { "memstat", FI_Root_memstat, false, procfs$memstat };
m_entries[FI_Root_cpuinfo] = { "cpuinfo", FI_Root_cpuinfo, false, procfs$cpuinfo };
m_entries[FI_Root_inodes] = { "inodes", FI_Root_inodes, true, procfs$inodes };
m_entries[FI_Root_dmesg] = { "dmesg", FI_Root_dmesg, true, procfs$dmesg };
m_entries[FI_Root_self] = { "self", FI_Root_self, false, procfs$self };
m_entries[FI_Root_pci] = { "pci", FI_Root_pci, false, procfs$pci };
m_entries[FI_Root_devices] = { "devices", FI_Root_devices, false, procfs$devices };
m_entries[FI_Root_uptime] = { "uptime", FI_Root_uptime, false, procfs$uptime };
m_entries[FI_Root_cmdline] = { "cmdline", FI_Root_cmdline, true, procfs$cmdline };
m_entries[FI_Root_modules] = { "modules", FI_Root_modules, true, procfs$modules };
m_entries[FI_Root_profile] = { "profile", FI_Root_profile, false, procfs$profile };
m_entries[FI_Root_sys] = { "sys", FI_Root_sys, true };
m_entries[FI_Root_net] = { "net", FI_Root_net, false };
m_entries[FI_Root_net_adapters] = { "adapters", FI_Root_net_adapters, false, procfs$net_adapters };
m_entries[FI_Root_net_arp] = { "arp", FI_Root_net_arp, true, procfs$net_arp };
m_entries[FI_Root_net_tcp] = { "tcp", FI_Root_net_tcp, false, procfs$net_tcp };
m_entries[FI_Root_net_udp] = { "udp", FI_Root_net_udp, false, procfs$net_udp };
m_entries[FI_Root_net_local] = { "local", FI_Root_net_local, false, procfs$net_local };
m_entries[FI_PID_vm] = { "vm", FI_PID_vm, false, procfs$pid_vm };
m_entries[FI_PID_vmobjects] = { "vmobjects", FI_PID_vmobjects, true, procfs$pid_vmobjects };
m_entries[FI_PID_stack] = { "stack", FI_PID_stack, false, procfs$pid_stack };
m_entries[FI_PID_regs] = { "regs", FI_PID_regs, true, procfs$pid_regs };
m_entries[FI_PID_fds] = { "fds", FI_PID_fds, false, procfs$pid_fds };
m_entries[FI_PID_exe] = { "exe", FI_PID_exe, false, procfs$pid_exe };
m_entries[FI_PID_cwd] = { "cwd", FI_PID_cwd, false, procfs$pid_cwd };
m_entries[FI_PID_root] = { "root", FI_PID_root, false, procfs$pid_root };
m_entries[FI_PID_fd] = { "fd", FI_PID_fd, false };
}
ProcFS::ProcFSDirectoryEntry* ProcFS::get_directory_entry(InodeIdentifier identifier) const
{
auto proc_file_type = to_proc_file_type(identifier);
if (proc_file_type != FI_Invalid && proc_file_type != FI_Root_sys_variable && 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);
}
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