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ladybird/Kernel/Heap/kmalloc.cpp
kleines Filmröllchen e2c9578390 Kernel: Allow preventing kmalloc and kfree 
For "destructive" disallowance of allocations throughout the system,
Thread gains a member that controls whether allocations are currently
allowed or not. kmalloc checks this member on both allocations and
deallocations (with the exception of early boot) and panics the kernel
if allocations are disabled. This will allow for critical sections that
can't be allowed to allocate to fail-fast, making for easier debugging.

PS: My first proper Kernel commit :^)
2022-01-11 00:08:58 +01:00

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/*
* Copyright (c) 2018-2021, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Assertions.h>
#include <AK/Types.h>
#include <Kernel/Debug.h>
#include <Kernel/Heap/Heap.h>
#include <Kernel/Heap/kmalloc.h>
#include <Kernel/KSyms.h>
#include <Kernel/Locking/Spinlock.h>
#include <Kernel/Memory/MemoryManager.h>
#include <Kernel/Panic.h>
#include <Kernel/PerformanceManager.h>
#include <Kernel/Sections.h>
#include <Kernel/StdLib.h>
#if ARCH(I386)
static constexpr size_t CHUNK_SIZE = 32;
#else
static constexpr size_t CHUNK_SIZE = 64;
#endif
static constexpr size_t INITIAL_KMALLOC_MEMORY_SIZE = 2 * MiB;
// Treat the heap as logically separate from .bss
__attribute__((section(".heap"))) static u8 initial_kmalloc_memory[INITIAL_KMALLOC_MEMORY_SIZE];
namespace std {
const nothrow_t nothrow;
}
static RecursiveSpinlock s_lock; // needs to be recursive because of dump_backtrace()
struct KmallocSubheap {
KmallocSubheap(u8* base, size_t size)
: allocator(base, size)
{
}
IntrusiveListNode<KmallocSubheap> list_node;
using List = IntrusiveList<&KmallocSubheap::list_node>;
Heap<CHUNK_SIZE, KMALLOC_SCRUB_BYTE, KFREE_SCRUB_BYTE> allocator;
};
class KmallocSlabBlock {
public:
static constexpr size_t block_size = 64 * KiB;
static constexpr FlatPtr block_mask = ~(block_size - 1);
KmallocSlabBlock(size_t slab_size)
{
size_t slab_count = (block_size - sizeof(KmallocSlabBlock)) / slab_size;
for (size_t i = 0; i < slab_count; ++i) {
auto* freelist_entry = (FreelistEntry*)(void*)(&m_data[i * slab_size]);
freelist_entry->next = m_freelist;
m_freelist = freelist_entry;
}
}
void* allocate()
{
VERIFY(m_freelist);
return exchange(m_freelist, m_freelist->next);
}
void deallocate(void* ptr)
{
VERIFY(ptr >= &m_data && ptr < ((u8*)this + block_size));
auto* freelist_entry = (FreelistEntry*)ptr;
freelist_entry->next = m_freelist;
m_freelist = freelist_entry;
}
bool is_full() const
{
return m_freelist == nullptr;
}
IntrusiveListNode<KmallocSlabBlock> list_node;
using List = IntrusiveList<&KmallocSlabBlock::list_node>;
private:
struct FreelistEntry {
FreelistEntry* next;
};
FreelistEntry* m_freelist { nullptr };
[[gnu::aligned(16)]] u8 m_data[];
};
class KmallocSlabheap {
public:
KmallocSlabheap(size_t slab_size)
: m_slab_size(slab_size)
{
}
size_t slab_size() const { return m_slab_size; }
void* allocate()
{
if (m_usable_blocks.is_empty()) {
// FIXME: This allocation wastes `block_size` bytes due to the implementation of kmalloc_aligned().
// Handle this with a custom VM+page allocator instead of using kmalloc_aligned().
auto* slot = kmalloc_aligned(KmallocSlabBlock::block_size, KmallocSlabBlock::block_size);
if (!slot) {
// FIXME: Dare to return nullptr!
PANIC("OOM while growing slabheap ({})", m_slab_size);
}
auto* block = new (slot) KmallocSlabBlock(m_slab_size);
m_usable_blocks.append(*block);
}
auto* block = m_usable_blocks.first();
auto* ptr = block->allocate();
if (block->is_full())
m_full_blocks.append(*block);
memset(ptr, KMALLOC_SCRUB_BYTE, m_slab_size);
return ptr;
}
void deallocate(void* ptr)
{
memset(ptr, KFREE_SCRUB_BYTE, m_slab_size);
auto* block = (KmallocSlabBlock*)((FlatPtr)ptr & KmallocSlabBlock::block_mask);
bool block_was_full = block->is_full();
block->deallocate(ptr);
if (block_was_full)
m_usable_blocks.append(*block);
}
private:
size_t m_slab_size { 0 };
KmallocSlabBlock::List m_usable_blocks;
KmallocSlabBlock::List m_full_blocks;
};
struct KmallocGlobalData {
static constexpr size_t minimum_subheap_size = 1 * MiB;
KmallocGlobalData(u8* initial_heap, size_t initial_heap_size)
{
add_subheap(initial_heap, initial_heap_size);
}
void add_subheap(u8* storage, size_t storage_size)
{
dbgln("Adding kmalloc subheap @ {} with size {}", storage, storage_size);
static_assert(sizeof(KmallocSubheap) <= PAGE_SIZE);
auto* subheap = new (storage) KmallocSubheap(storage + PAGE_SIZE, storage_size - PAGE_SIZE);
subheaps.append(*subheap);
}
void* allocate(size_t size)
{
VERIFY(!expansion_in_progress);
for (auto& slabheap : slabheaps) {
if (size <= slabheap.slab_size())
return slabheap.allocate();
}
for (auto& subheap : subheaps) {
if (auto* ptr = subheap.allocator.allocate(size))
return ptr;
}
if (!try_expand(size)) {
PANIC("OOM when trying to expand kmalloc heap.");
}
return allocate(size);
}
void deallocate(void* ptr, size_t size)
{
VERIFY(!expansion_in_progress);
VERIFY(is_valid_kmalloc_address(VirtualAddress { ptr }));
for (auto& slabheap : slabheaps) {
if (size <= slabheap.slab_size())
return slabheap.deallocate(ptr);
}
for (auto& subheap : subheaps) {
if (subheap.allocator.contains(ptr)) {
subheap.allocator.deallocate(ptr);
return;
}
}
PANIC("Bogus pointer passed to kfree_sized({:p}, {})", ptr, size);
}
size_t allocated_bytes() const
{
size_t total = 0;
for (auto const& subheap : subheaps)
total += subheap.allocator.allocated_bytes();
return total;
}
size_t free_bytes() const
{
size_t total = 0;
for (auto const& subheap : subheaps)
total += subheap.allocator.free_bytes();
return total;
}
bool try_expand(size_t allocation_request)
{
VERIFY(!expansion_in_progress);
TemporaryChange change(expansion_in_progress, true);
auto new_subheap_base = expansion_data->next_virtual_address;
Checked<size_t> padded_allocation_request = allocation_request;
padded_allocation_request *= 2;
padded_allocation_request += PAGE_SIZE;
if (padded_allocation_request.has_overflow()) {
PANIC("Integer overflow during kmalloc heap expansion");
}
auto rounded_allocation_request = Memory::page_round_up(padded_allocation_request.value());
if (rounded_allocation_request.is_error()) {
PANIC("Integer overflow computing pages for kmalloc heap expansion");
}
size_t new_subheap_size = max(minimum_subheap_size, rounded_allocation_request.value());
dbgln("Unable to allocate {}, expanding kmalloc heap", allocation_request);
if (!expansion_data->virtual_range.contains(new_subheap_base, new_subheap_size)) {
// FIXME: Dare to return false and allow kmalloc() to fail!
PANIC("Out of address space when expanding kmalloc heap.");
}
auto physical_pages_or_error = MM.commit_user_physical_pages(new_subheap_size / PAGE_SIZE);
if (physical_pages_or_error.is_error()) {
// FIXME: Dare to return false!
PANIC("Out of physical pages when expanding kmalloc heap.");
}
auto physical_pages = physical_pages_or_error.release_value();
expansion_data->next_virtual_address = expansion_data->next_virtual_address.offset(new_subheap_size);
auto cpu_supports_nx = Processor::current().has_feature(CPUFeature::NX);
SpinlockLocker mm_locker(Memory::s_mm_lock);
SpinlockLocker pd_locker(MM.kernel_page_directory().get_lock());
for (auto vaddr = new_subheap_base; !physical_pages.is_empty(); vaddr = vaddr.offset(PAGE_SIZE)) {
// FIXME: We currently leak physical memory when mapping it into the kmalloc heap.
auto& page = physical_pages.take_one().leak_ref();
auto* pte = MM.pte(MM.kernel_page_directory(), vaddr);
VERIFY(pte);
pte->set_physical_page_base(page.paddr().get());
pte->set_global(true);
pte->set_user_allowed(false);
pte->set_writable(true);
if (cpu_supports_nx)
pte->set_execute_disabled(true);
pte->set_present(true);
}
MM.flush_tlb(&MM.kernel_page_directory(), new_subheap_base, new_subheap_size / PAGE_SIZE);
add_subheap(new_subheap_base.as_ptr(), new_subheap_size);
return true;
}
void enable_expansion()
{
// FIXME: This range can be much bigger on 64-bit, but we need to figure something out for 32-bit.
auto virtual_range = MM.kernel_page_directory().range_allocator().try_allocate_anywhere(64 * MiB, 1 * MiB);
expansion_data = KmallocGlobalData::ExpansionData {
.virtual_range = virtual_range.value(),
.next_virtual_address = virtual_range.value().base(),
};
// Make sure the entire kmalloc VM range is backed by page tables.
// This avoids having to deal with lazy page table allocation during heap expansion.
SpinlockLocker mm_locker(Memory::s_mm_lock);
SpinlockLocker pd_locker(MM.kernel_page_directory().get_lock());
for (auto vaddr = virtual_range.value().base(); vaddr < virtual_range.value().end(); vaddr = vaddr.offset(PAGE_SIZE)) {
MM.ensure_pte(MM.kernel_page_directory(), vaddr);
}
}
struct ExpansionData {
Memory::VirtualRange virtual_range;
VirtualAddress next_virtual_address;
};
Optional<ExpansionData> expansion_data;
bool is_valid_kmalloc_address(VirtualAddress vaddr) const
{
if (vaddr.as_ptr() >= initial_kmalloc_memory && vaddr.as_ptr() < (initial_kmalloc_memory + INITIAL_KMALLOC_MEMORY_SIZE))
return true;
if (!expansion_data.has_value())
return false;
return expansion_data->virtual_range.contains(vaddr);
}
KmallocSubheap::List subheaps;
KmallocSlabheap slabheaps[6] = { 16, 32, 64, 128, 256, 512 };
bool expansion_in_progress { false };
};
READONLY_AFTER_INIT static KmallocGlobalData* g_kmalloc_global;
alignas(KmallocGlobalData) static u8 g_kmalloc_global_heap[sizeof(KmallocGlobalData)];
static size_t g_kmalloc_call_count;
static size_t g_kfree_call_count;
static size_t g_nested_kfree_calls;
bool g_dump_kmalloc_stacks;
void kmalloc_enable_expand()
{
g_kmalloc_global->enable_expansion();
}
static inline void kmalloc_verify_nospinlock_held()
{
// Catch bad callers allocating under spinlock.
if constexpr (KMALLOC_VERIFY_NO_SPINLOCK_HELD) {
VERIFY(!Processor::in_critical());
}
}
UNMAP_AFTER_INIT void kmalloc_init()
{
// Zero out heap since it's placed after end_of_kernel_bss.
memset(initial_kmalloc_memory, 0, sizeof(initial_kmalloc_memory));
g_kmalloc_global = new (g_kmalloc_global_heap) KmallocGlobalData(initial_kmalloc_memory, sizeof(initial_kmalloc_memory));
s_lock.initialize();
}
void* kmalloc(size_t size)
{
kmalloc_verify_nospinlock_held();
SpinlockLocker lock(s_lock);
++g_kmalloc_call_count;
if (g_dump_kmalloc_stacks && Kernel::g_kernel_symbols_available) {
dbgln("kmalloc({})", size);
Kernel::dump_backtrace();
}
void* ptr = g_kmalloc_global->allocate(size);
Thread* current_thread = Thread::current();
if (!current_thread)
current_thread = Processor::idle_thread();
if (current_thread) {
// FIXME: By the time we check this, we have already allocated above.
// This means that in the case of an infinite recursion, we can't catch it this way.
VERIFY(current_thread->is_allocation_enabled());
PerformanceManager::add_kmalloc_perf_event(*current_thread, size, (FlatPtr)ptr);
}
return ptr;
}
void kfree_sized(void* ptr, size_t size)
{
if (!ptr)
return;
VERIFY(size > 0);
kmalloc_verify_nospinlock_held();
SpinlockLocker lock(s_lock);
++g_kfree_call_count;
++g_nested_kfree_calls;
if (g_nested_kfree_calls == 1) {
Thread* current_thread = Thread::current();
if (!current_thread)
current_thread = Processor::idle_thread();
if (current_thread) {
VERIFY(current_thread->is_allocation_enabled());
PerformanceManager::add_kfree_perf_event(*current_thread, 0, (FlatPtr)ptr);
}
}
g_kmalloc_global->deallocate(ptr, size);
--g_nested_kfree_calls;
}
size_t kmalloc_good_size(size_t size)
{
return size;
}
void* kmalloc_aligned(size_t size, size_t alignment)
{
Checked<size_t> real_allocation_size = size;
real_allocation_size += alignment;
real_allocation_size += sizeof(ptrdiff_t) + sizeof(size_t);
void* ptr = kmalloc(real_allocation_size.value());
if (ptr == nullptr)
return nullptr;
size_t max_addr = (size_t)ptr + alignment;
void* aligned_ptr = (void*)(max_addr - (max_addr % alignment));
((ptrdiff_t*)aligned_ptr)[-1] = (ptrdiff_t)((u8*)aligned_ptr - (u8*)ptr);
((size_t*)aligned_ptr)[-2] = real_allocation_size.value();
return aligned_ptr;
}
void* operator new(size_t size)
{
void* ptr = kmalloc(size);
VERIFY(ptr);
return ptr;
}
void* operator new(size_t size, const std::nothrow_t&) noexcept
{
return kmalloc(size);
}
void* operator new(size_t size, std::align_val_t al)
{
void* ptr = kmalloc_aligned(size, (size_t)al);
VERIFY(ptr);
return ptr;
}
void* operator new(size_t size, std::align_val_t al, const std::nothrow_t&) noexcept
{
return kmalloc_aligned(size, (size_t)al);
}
void* operator new[](size_t size)
{
void* ptr = kmalloc(size);
VERIFY(ptr);
return ptr;
}
void* operator new[](size_t size, const std::nothrow_t&) noexcept
{
return kmalloc(size);
}
void operator delete(void*) noexcept
{
// All deletes in kernel code should have a known size.
VERIFY_NOT_REACHED();
}
void operator delete(void* ptr, size_t size) noexcept
{
return kfree_sized(ptr, size);
}
void operator delete(void* ptr, size_t, std::align_val_t) noexcept
{
return kfree_aligned(ptr);
}
void operator delete[](void*) noexcept
{
// All deletes in kernel code should have a known size.
VERIFY_NOT_REACHED();
}
void operator delete[](void* ptr, size_t size) noexcept
{
return kfree_sized(ptr, size);
}
void get_kmalloc_stats(kmalloc_stats& stats)
{
SpinlockLocker lock(s_lock);
stats.bytes_allocated = g_kmalloc_global->allocated_bytes();
stats.bytes_free = g_kmalloc_global->free_bytes();
stats.kmalloc_call_count = g_kmalloc_call_count;
stats.kfree_call_count = g_kfree_call_count;
}
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