ladybird/Kernel/KSyms.cpp
Sönke Holz 0c8c0ff412 Kernel/riscv64: Fix backtrace generation on RISC-V
RISC-V uses a different convention for storing stack frame information
described here: https://github.com/riscv-non-isa/riscv-elf-psabi-doc/blob/master/riscv-cc.adoc#frame-pointer-convention
This part of the psABI is not yet in a ratified version, but both GCC
and Clang seem to use this convention.

Note that the backtrace dumping code still won't work for the initial
stack, as it is located before `kernel_mapping_base`.
2023-12-30 23:24:18 +01:00

250 lines
8.7 KiB
C++

/*
* Copyright (c) 2018-2020, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/TemporaryChange.h>
#include <Kernel/Arch/SafeMem.h>
#include <Kernel/Arch/SmapDisabler.h>
#include <Kernel/FileSystem/OpenFileDescription.h>
#include <Kernel/KSyms.h>
#include <Kernel/Sections.h>
#include <Kernel/Tasks/Process.h>
#include <Kernel/Tasks/Scheduler.h>
namespace Kernel {
FlatPtr g_lowest_kernel_symbol_address = 0xffffffff;
FlatPtr g_highest_kernel_symbol_address = 0;
bool g_kernel_symbols_available = false;
extern "C" {
__attribute__((section(".kernel_symbols"))) char kernel_symbols[5 * MiB] {};
}
static KernelSymbol* s_symbols;
static size_t s_symbol_count = 0;
UNMAP_AFTER_INIT static u8 parse_hex_digit(char nibble)
{
if (nibble >= '0' && nibble <= '9')
return nibble - '0';
VERIFY(nibble >= 'a' && nibble <= 'f');
return 10 + (nibble - 'a');
}
FlatPtr address_for_kernel_symbol(StringView name)
{
for (size_t i = 0; i < s_symbol_count; ++i) {
auto const& symbol = s_symbols[i];
if (name == symbol.name)
return symbol.address;
}
return 0;
}
KernelSymbol const* symbolicate_kernel_address(FlatPtr address)
{
if (address < g_lowest_kernel_symbol_address || address > g_highest_kernel_symbol_address)
return nullptr;
for (unsigned i = 0; i < s_symbol_count; ++i) {
if (address < s_symbols[i + 1].address)
return &s_symbols[i];
}
return nullptr;
}
UNMAP_AFTER_INIT static void load_kernel_symbols_from_data(Bytes buffer)
{
g_lowest_kernel_symbol_address = 0xffffffff;
g_highest_kernel_symbol_address = 0;
auto* bufptr = (char*)buffer.data();
auto* start_of_name = bufptr;
FlatPtr address = 0;
for (size_t i = 0; i < 8; ++i)
s_symbol_count = (s_symbol_count << 4) | parse_hex_digit(*(bufptr++));
s_symbols = static_cast<KernelSymbol*>(kmalloc(sizeof(KernelSymbol) * s_symbol_count));
++bufptr; // skip newline
dmesgln("Loading kernel symbol table...");
size_t current_symbol_index = 0;
while ((u8 const*)bufptr < buffer.data() + buffer.size()) {
for (size_t i = 0; i < sizeof(void*) * 2; ++i)
address = (address << 4) | parse_hex_digit(*(bufptr++));
bufptr += 3;
start_of_name = bufptr;
while (*(++bufptr)) {
if (*bufptr == '\n') {
break;
}
}
auto& ksym = s_symbols[current_symbol_index];
// FIXME: Remove this ifdef once the aarch64 kernel is loaded by the Prekernel.
// Currently, the aarch64 kernel is linked at a high virtual memory address, instead
// of zero, so the address of a symbol does not need to be offset by the kernel_load_base.
#if ARCH(X86_64)
ksym.address = kernel_load_base + address;
#elif ARCH(AARCH64) || ARCH(RISCV64)
ksym.address = address;
#else
# error "Unknown architecture"
#endif
ksym.name = start_of_name;
*bufptr = '\0';
if (ksym.address < g_lowest_kernel_symbol_address)
g_lowest_kernel_symbol_address = ksym.address;
if (ksym.address > g_highest_kernel_symbol_address)
g_highest_kernel_symbol_address = ksym.address;
++bufptr;
++current_symbol_index;
}
g_kernel_symbols_available = true;
}
NEVER_INLINE static void dump_backtrace_impl(FlatPtr frame_pointer, bool use_ksyms, PrintToScreen print_to_screen)
{
#define PRINT_LINE(fmtstr, ...) \
do { \
if (print_to_screen == PrintToScreen::No) \
dbgln(fmtstr, __VA_ARGS__); \
else \
critical_dmesgln(fmtstr, __VA_ARGS__); \
} while (0)
SmapDisabler disabler;
if (use_ksyms && !g_kernel_symbols_available)
Processor::halt();
struct RecognizedSymbol {
FlatPtr address;
KernelSymbol const* symbol { nullptr };
};
struct FrameRecord {
FlatPtr previous_frame_pointer;
FlatPtr return_address;
};
auto safe_memcpy_frame_record_from_stack = [](FlatPtr current_frame_pointer) -> ErrorOr<FrameRecord> {
#if ARCH(X86_64) || ARCH(AARCH64)
// x86_64/aarch64 frame record layout:
// rbp/fp+8: return address
// rbp/fp+0: previous base/frame pointer
FlatPtr previous_frame_pointer_and_return_address[2];
void* fault_at;
if (!safe_memcpy(previous_frame_pointer_and_return_address, bit_cast<FlatPtr*>(current_frame_pointer), sizeof(previous_frame_pointer_and_return_address), fault_at))
return EFAULT;
return FrameRecord {
.previous_frame_pointer = previous_frame_pointer_and_return_address[0],
.return_address = previous_frame_pointer_and_return_address[1],
};
#elif ARCH(RISCV64)
// riscv64 frame record layout:
// fp-8: return address
// fp-16: previous frame pointer
FlatPtr previous_frame_pointer_and_return_address[2];
void* fault_at;
if (!safe_memcpy(previous_frame_pointer_and_return_address, bit_cast<FlatPtr*>(current_frame_pointer) - 2, sizeof(previous_frame_pointer_and_return_address), fault_at))
return EFAULT;
return FrameRecord {
.previous_frame_pointer = previous_frame_pointer_and_return_address[0],
.return_address = previous_frame_pointer_and_return_address[1],
};
#else
# error Unknown architecture
#endif
};
constexpr size_t max_recognized_symbol_count = 256;
RecognizedSymbol recognized_symbols[max_recognized_symbol_count];
size_t recognized_symbol_count = 0;
if (use_ksyms) {
FlatPtr current_frame_pointer = frame_pointer;
while (current_frame_pointer != 0 && recognized_symbol_count < max_recognized_symbol_count) {
if (current_frame_pointer < kernel_mapping_base)
break;
auto frame_record_or_error = safe_memcpy_frame_record_from_stack(current_frame_pointer);
if (frame_record_or_error.is_error())
break;
auto frame_record = frame_record_or_error.release_value();
recognized_symbols[recognized_symbol_count++] = { frame_record.return_address, symbolicate_kernel_address(frame_record.return_address) };
current_frame_pointer = frame_record.previous_frame_pointer;
}
} else {
FlatPtr current_frame_pointer = frame_pointer;
while (current_frame_pointer != 0) {
auto frame_record_or_error = safe_memcpy_frame_record_from_stack(current_frame_pointer);
if (frame_record_or_error.is_error())
break;
auto frame_record = frame_record_or_error.release_value();
PRINT_LINE("{:p} (next: {:p})", frame_record.return_address, frame_record.previous_frame_pointer);
current_frame_pointer = frame_record.previous_frame_pointer;
}
return;
}
VERIFY(recognized_symbol_count <= max_recognized_symbol_count);
for (size_t i = 0; i < recognized_symbol_count; ++i) {
auto& symbol = recognized_symbols[i];
if (!symbol.address)
break;
if (!symbol.symbol) {
PRINT_LINE("Kernel + {:p}", symbol.address - kernel_load_base);
continue;
}
size_t offset = symbol.address - symbol.symbol->address;
if (symbol.symbol->address == g_highest_kernel_symbol_address && offset > 4096)
PRINT_LINE("Kernel + {:p}", symbol.address - kernel_load_base);
else
PRINT_LINE("Kernel + {:p} {} +{:#x}", symbol.address - kernel_load_base, symbol.symbol->name, offset);
}
}
void dump_backtrace_from_base_pointer(FlatPtr base_pointer)
{
// FIXME: Change signature of dump_backtrace_impl to use an enum instead of a bool.
dump_backtrace_impl(base_pointer, /*use_ksym=*/false, PrintToScreen::No);
}
void dump_backtrace(PrintToScreen print_to_screen)
{
static bool in_dump_backtrace = false;
if (in_dump_backtrace)
return;
TemporaryChange change(in_dump_backtrace, true);
TemporaryChange disable_kmalloc_stacks(g_dump_kmalloc_stacks, false);
FlatPtr base_pointer = (FlatPtr)__builtin_frame_address(0);
dump_backtrace_impl(base_pointer, g_kernel_symbols_available, print_to_screen);
}
UNMAP_AFTER_INIT void load_kernel_symbol_table()
{
auto kernel_symbols_size = strnlen(kernel_symbols, sizeof(kernel_symbols));
// If we're hitting this VERIFY the kernel symbol file has grown beyond
// the array size of kernel_symbols. Try making the array larger.
VERIFY(kernel_symbols_size != sizeof(kernel_symbols));
load_kernel_symbols_from_data({ kernel_symbols, kernel_symbols_size });
}
}