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serenity/Userland/Libraries/LibSymbolication/Symbolication.cpp
Rodrigo Tobar 08428aadad LibSymbolication: Skip source position calculation if requested 
Calculating source code positions can be expensive, and some
applications (like SystemMonitor's Stack tab) don't even show this
information, making these calculations wasteful.

This commit adds a new enumerated flag to the `symbolicate` functions
for callers to specify whether source positions should be included in
the results; it defaults to "Yes" to preserve old behavior for existing
applications.
2021-10-17 22:07:10 -07:00

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/*
* Copyright (c) 2021, Andreas Kling <kling@serenityos.org>
*
* SPDX-License-Identifier: BSD-2-Clause
*/
#include <AK/Array.h>
#include <AK/Checked.h>
#include <AK/JsonArray.h>
#include <AK/JsonObject.h>
#include <AK/JsonValue.h>
#include <AK/LexicalPath.h>
#include <AK/MappedFile.h>
#include <LibCore/File.h>
#include <LibDebug/DebugInfo.h>
#include <LibSymbolication/Symbolication.h>
namespace Symbolication {
struct CachedELF {
NonnullRefPtr<MappedFile> mapped_file;
NonnullOwnPtr<Debug::DebugInfo> debug_info;
NonnullOwnPtr<ELF::Image> image;
};
static HashMap<String, OwnPtr<CachedELF>> s_cache;
enum class KernelBaseState {
Uninitialized,
Valid,
Invalid,
};
static FlatPtr s_kernel_base;
static KernelBaseState s_kernel_base_state = KernelBaseState::Uninitialized;
Optional<FlatPtr> kernel_base()
{
if (s_kernel_base_state == KernelBaseState::Uninitialized) {
auto file = Core::File::open("/proc/kernel_base", Core::OpenMode::ReadOnly);
if (file.is_error()) {
s_kernel_base_state = KernelBaseState::Invalid;
return {};
}
auto kernel_base_str = String { file.value()->read_all(), NoChomp };
#if ARCH(I386)
using AddressType = u32;
#else
using AddressType = u64;
#endif
auto maybe_kernel_base = kernel_base_str.to_uint<AddressType>();
if (!maybe_kernel_base.has_value()) {
s_kernel_base_state = KernelBaseState::Invalid;
return {};
}
s_kernel_base = maybe_kernel_base.value();
s_kernel_base_state = KernelBaseState::Valid;
}
if (s_kernel_base_state == KernelBaseState::Invalid)
return {};
return s_kernel_base;
}
Optional<Symbol> symbolicate(String const& path, FlatPtr address, IncludeSourcePosition include_source_positions)
{
String full_path = path;
if (!path.starts_with('/')) {
Array<StringView, 2> search_paths { "/usr/lib"sv, "/usr/local/lib"sv };
bool found = false;
for (auto& search_path : search_paths) {
full_path = LexicalPath::join(search_path, path).string();
if (Core::File::exists(full_path)) {
found = true;
break;
}
}
if (!found) {
dbgln("Failed to find candidate for {}", path);
s_cache.set(path, {});
return {};
}
}
if (!s_cache.contains(full_path)) {
auto mapped_file = MappedFile::map(full_path);
if (mapped_file.is_error()) {
dbgln("Failed to map {}: {}", full_path, mapped_file.error().string());
s_cache.set(full_path, {});
return {};
}
auto elf = make<ELF::Image>(mapped_file.value()->bytes());
if (!elf->is_valid()) {
dbgln("ELF not valid: {}", full_path);
s_cache.set(full_path, {});
return {};
}
auto cached_elf = make<CachedELF>(mapped_file.release_value(), make<Debug::DebugInfo>(*elf), move(elf));
s_cache.set(full_path, move(cached_elf));
}
auto it = s_cache.find(full_path);
VERIFY(it != s_cache.end());
auto& cached_elf = it->value;
if (!cached_elf)
return {};
u32 offset = 0;
auto symbol = cached_elf->debug_info->elf().symbolicate(address, &offset);
Vector<Debug::DebugInfo::SourcePosition> positions;
if (include_source_positions == IncludeSourcePosition::Yes) {
auto source_position_with_inlines = cached_elf->debug_info->get_source_position_with_inlines(address);
for (auto& position : source_position_with_inlines.inline_chain) {
if (!positions.contains_slow(position))
positions.append(position);
}
if (source_position_with_inlines.source_position.has_value() && !positions.contains_slow(source_position_with_inlines.source_position.value())) {
positions.insert(0, source_position_with_inlines.source_position.value());
}
}
return Symbol {
.address = address,
.name = move(symbol),
.object = LexicalPath::basename(path),
.offset = offset,
.source_positions = move(positions),
};
}
Vector<Symbol> symbolicate_thread(pid_t pid, pid_t tid, IncludeSourcePosition include_source_positions)
{
struct RegionWithSymbols {
FlatPtr base { 0 };
size_t size { 0 };
String path;
};
Vector<FlatPtr> stack;
Vector<RegionWithSymbols> regions;
if (auto maybe_kernel_base = kernel_base(); maybe_kernel_base.has_value()) {
regions.append(RegionWithSymbols {
.base = maybe_kernel_base.value(),
.size = 0x3fffffff,
.path = "/boot/Kernel.debug",
});
}
{
auto stack_path = String::formatted("/proc/{}/stacks/{}", pid, tid);
auto file_or_error = Core::File::open(stack_path, Core::OpenMode::ReadOnly);
if (file_or_error.is_error()) {
warnln("Could not open {}: {}", stack_path, file_or_error.error());
return {};
}
auto json = JsonValue::from_string(file_or_error.value()->read_all());
if (!json.has_value() || !json.value().is_array()) {
warnln("Invalid contents in {}", stack_path);
return {};
}
stack.ensure_capacity(json.value().as_array().size());
for (auto& value : json.value().as_array().values()) {
stack.append(value.to_addr());
}
}
{
auto vm_path = String::formatted("/proc/{}/vm", pid);
auto file_or_error = Core::File::open(vm_path, Core::OpenMode::ReadOnly);
if (file_or_error.is_error()) {
warnln("Could not open {}: {}", vm_path, file_or_error.error());
return {};
}
auto json = JsonValue::from_string(file_or_error.value()->read_all());
if (!json.has_value() || !json.value().is_array()) {
warnln("Invalid contents in {}", vm_path);
return {};
}
for (auto& region_value : json.value().as_array().values()) {
auto& region = region_value.as_object();
auto name = region.get("name").to_string();
auto address = region.get("address").to_addr();
auto size = region.get("size").to_addr();
String path;
if (name == "/usr/lib/Loader.so") {
path = name;
} else if (name.ends_with(": .text") || name.ends_with(": .rodata")) {
auto parts = name.split_view(':');
path = parts[0];
} else {
continue;
}
RegionWithSymbols r;
r.base = address;
r.size = size;
r.path = path;
regions.append(move(r));
}
}
Vector<Symbol> symbols;
bool first_frame = true;
for (auto address : stack) {
const RegionWithSymbols* found_region = nullptr;
for (auto& region : regions) {
FlatPtr region_end;
if (Checked<FlatPtr>::addition_would_overflow(region.base, region.size))
region_end = NumericLimits<FlatPtr>::max();
else
region_end = region.base + region.size;
if (address >= region.base && address < region_end) {
found_region = &region;
break;
}
}
if (!found_region) {
outln("{:p} ??", address);
continue;
}
// We found an address inside of a region, but the base of that region
// may not be the base of the ELF image. For example, there could be an
// .rodata mapping at a lower address than the first .text mapping from
// the same image. look for the lowest address region with the same path.
RegionWithSymbols const* base_region = nullptr;
for (auto& region : regions) {
if (region.path != found_region->path)
continue;
if (!base_region || region.base <= base_region->base)
base_region = &region;
}
FlatPtr adjusted_address = address - base_region->base;
// We're subtracting 1 from the address because this is the return address,
// i.e. it is one instruction past the call instruction.
// However, because the first frame represents the current
// instruction pointer rather than the return address we don't
// subtract 1 for that.
auto result = symbolicate(found_region->path, adjusted_address - (first_frame ? 0 : 1), include_source_positions);
first_frame = false;
if (!result.has_value()) {
symbols.append(Symbol {
.address = address,
.source_positions = {},
});
continue;
}
symbols.append(result.value());
}
return symbols;
}
}
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