blob: 126d6ddc78c85cffe6d44bb10b68fe6a06910d03 [file] [log] [blame]
/*
* Copyright (C) 2019 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#include "src/kallsyms/kernel_symbol_map.h"
#include "perfetto/base/build_config.h"
#include "perfetto/base/logging.h"
#include "perfetto/ext/base/file_utils.h"
#include "perfetto/ext/base/metatrace.h"
#include "perfetto/ext/base/paged_memory.h"
#include "perfetto/ext/base/scoped_file.h"
#include "perfetto/ext/base/string_view.h"
#include "perfetto/ext/base/utils.h"
#include "perfetto/protozero/proto_utils.h"
#include <inttypes.h>
#include <stdio.h>
#include <algorithm>
#include <functional>
#include <map>
#include <utility>
namespace perfetto {
// On a Pixel 3 this gives an avg. lookup time of 600 ns and a memory usage
// of 1.1 MB for 65k symbols. See go/kallsyms-parser-bench.
size_t KernelSymbolMap::kSymIndexSampling = 16;
size_t KernelSymbolMap::kTokenIndexSampling = 4;
namespace {
using TokenId = KernelSymbolMap::TokenTable::TokenId;
constexpr size_t kSymNameMaxLen = 128;
constexpr size_t kSymMaxSizeBytes = 1024 * 1024;
// Reads a kallsyms file in blocks of 4 pages each and decode its lines using
// a simple FSM. Calls the passed lambda for each valid symbol.
// It skips undefined symbols and other useless stuff.
template <typename Lambda /* void(uint64_t, const char*) */>
void ForEachSym(const std::string& kallsyms_path, Lambda fn) {
base::ScopedFile fd = base::OpenFile(kallsyms_path.c_str(), O_RDONLY);
if (!fd) {
PERFETTO_PLOG("Cannot open %s", kallsyms_path.c_str());
return;
}
// /proc/kallsyms looks as follows:
// 0000000000026a80 A bpf_trace_sds
//
// ffffffffc03a6000 T cpufreq_gov_powersave_init<TAB> [cpufreq_powersave]
// ffffffffc035d000 T cpufreq_gov_userspace_init<TAB> [cpufreq_userspace]
//
// We parse it with a state machine that has four states, one for each column.
// We don't care about the part in the square brackets and ignore everything
// after the symbol name.
static constexpr size_t kBufSize = 16 * 1024;
base::PagedMemory buffer = base::PagedMemory::Allocate(kBufSize);
enum { kSymAddr, kSymType, kSymName, kEatRestOfLine } state = kSymAddr;
uint64_t sym_addr = 0;
char sym_type = '\0';
char sym_name[kSymNameMaxLen + 1];
size_t sym_name_len = 0;
for (;;) {
char* buf = static_cast<char*>(buffer.Get());
auto rsize = base::Read(*fd, buf, kBufSize);
if (rsize < 0) {
PERFETTO_PLOG("read(%s) failed", kallsyms_path.c_str());
return;
}
if (rsize == 0)
return; // EOF
for (size_t i = 0; i < static_cast<size_t>(rsize); i++) {
char c = buf[i];
const bool is_space = c == ' ' || c == '\t';
switch (state) {
case kSymAddr:
if (c >= '0' && c <= '9') {
sym_addr = (sym_addr << 4) | static_cast<uint8_t>(c - '0');
} else if (c >= 'a' && c <= 'f') {
sym_addr = (sym_addr << 4) | static_cast<uint8_t>(c - 'a' + 10);
} else if (is_space) {
state = kSymType;
} else if (c == '\0') {
return;
} else {
PERFETTO_ELOG("kallsyms parser error: chr 0x%x @ off=%zu", c, i);
return;
}
break;
case kSymType:
if (is_space)
break; // Eat leading spaces.
sym_type = c;
state = kSymName;
sym_name_len = 0;
break;
case kSymName:
if (is_space && sym_name_len == 0)
break; // Eat leading spaces.
if (c && c != '\n' && !is_space && sym_name_len < kSymNameMaxLen) {
sym_name[sym_name_len++] = c;
break;
}
sym_name[sym_name_len] = '\0';
fn(sym_addr, sym_type, sym_name);
sym_addr = 0;
sym_type = '\0';
state = c == '\n' ? kSymAddr : kEatRestOfLine;
break;
case kEatRestOfLine:
if (c == '\n')
state = kSymAddr;
break;
} // switch(state)
} // for (char in buf)
} // for (read chunk)
}
// Splits a symbol name into tokens using '_' as a separator, calling the passed
// lambda for each token. It splits tokens in a way that allows the original
// string to be rebuilt as-is by re-joining using a '_' between each token.
// For instance:
// _fo_a_b -> ["", fo, a, b]
// __fo_a_b -> [_, fo, a, b]
// __fo_a_b_ -> [_, fo, a, b, ""]
// __fo_a_b____ -> [_, fo, a, b, ___]
template <typename Lambda /* void(base::StringView) */>
void Tokenize(const char* name, Lambda fn) {
const char* tok_start = name;
bool is_start_of_token = true;
bool tok_is_sep = false;
for (const char* ptr = name;; ptr++) {
const char c = *ptr;
if (is_start_of_token) {
tok_is_sep = *tok_start == '_'; // Deals with tokens made of '_'s.
is_start_of_token = false;
}
// Scan until either the end of string or the next character (which is a '_'
// in nominal cases, or anything != '_' for tokens made by 1+ '_').
if (c == '\0' || (!tok_is_sep && c == '_') || (tok_is_sep && c != '_')) {
size_t tok_len = static_cast<size_t>(ptr - tok_start);
if (tok_is_sep && c != '\0')
--tok_len;
fn(base::StringView(tok_start, tok_len));
if (c == '\0')
return;
tok_start = tok_is_sep ? ptr : ptr + 1;
is_start_of_token = true;
}
}
}
} // namespace
KernelSymbolMap::TokenTable::TokenTable() {
// Insert a null token as id 0. We can't just add "" because the empty string
// is special-cased and doesn't insert an actual token. So we push a string of
// size one that contains only the null character instead.
char null_tok = 0;
Add(std::string(&null_tok, 1));
}
KernelSymbolMap::TokenTable::~TokenTable() = default;
// Adds a new token to the db. Does not dedupe identical token (with the
// exception of the empty string). The caller has to deal with that.
// Supports only ASCII characters in the range [1, 127].
// The last character of the token will have the MSB set.
TokenId KernelSymbolMap::TokenTable::Add(const std::string& token) {
const size_t token_size = token.size();
if (token_size == 0)
return 0;
TokenId id = num_tokens_++;
const size_t buf_size_before_insertion = buf_.size();
if (id % kTokenIndexSampling == 0)
index_.emplace_back(buf_size_before_insertion);
const size_t prev_size = buf_.size();
buf_.resize(prev_size + token_size);
char* tok_wptr = &buf_[prev_size];
for (size_t i = 0; i < token_size - 1; i++) {
PERFETTO_DCHECK((token.at(i) & 0x80) == 0); // |token| must be ASCII only.
*(tok_wptr++) = token.at(i) & 0x7f;
}
*(tok_wptr++) = static_cast<char>(token.at(token_size - 1) | 0x80);
PERFETTO_DCHECK(tok_wptr == buf_.data() + buf_.size());
return id;
}
// NOTE: the caller need to mask the returned chars with 0x7f. The last char of
// the StringView will have its MSB set (it's used as a EOF char internally).
base::StringView KernelSymbolMap::TokenTable::Lookup(TokenId id) {
if (id == 0)
return base::StringView();
if (id > num_tokens_)
return base::StringView("<error>");
// We don't know precisely where the id-th token starts in the buffer. We
// store only one position every kTokenIndexSampling. From there, the token
// can be found with a linear scan of at most kTokenIndexSampling steps.
size_t index_off = id / kTokenIndexSampling;
PERFETTO_DCHECK(index_off < index_.size());
TokenId cur_id = static_cast<TokenId>(index_off * kTokenIndexSampling);
uint32_t begin = index_[index_off];
PERFETTO_DCHECK(begin == 0 || buf_[begin - 1] & 0x80);
const size_t buf_size = buf_.size();
for (uint32_t off = begin; off < buf_size; ++off) {
// Advance |off| until the end of the token (which has the MSB set).
if ((buf_[off] & 0x80) == 0)
continue;
if (cur_id == id)
return base::StringView(&buf_[begin], off - begin + 1);
++cur_id;
begin = off + 1;
}
return base::StringView();
}
size_t KernelSymbolMap::Parse(const std::string& kallsyms_path) {
PERFETTO_METATRACE_SCOPED(TAG_PRODUCER, KALLSYMS_PARSE);
using SymAddr = uint64_t;
struct TokenInfo {
uint32_t count = 0;
TokenId id = 0;
};
// Note if changing the container: the code below relies on stable iterators.
using TokenMap = std::map<std::string, TokenInfo>;
using TokenMapPtr = TokenMap::value_type*;
TokenMap tokens;
// Keep the (ordered) list of tokens for each symbol.
struct SymAddrAndTokenPtr {
SymAddr addr;
TokenMapPtr token_map_entry;
bool operator<(const SymAddrAndTokenPtr& other) const {
return addr < other.addr;
}
};
std::vector<SymAddrAndTokenPtr> symbol_tokens;
// Based on `cat /proc/kallsyms | egrep "\b[tT]\b" | wc -l`.
symbol_tokens.reserve(128 * 1024);
ForEachSym(kallsyms_path, [&](SymAddr addr, char type, const char* name) {
if (addr == 0 || (type != 't' && type != 'T') || name[0] == '$') {
return;
}
// Split each symbol name in tokens, using '_' as a separator (so that
// "foo_bar" -> ["foo", "bar"]). For each token hash:
// 1. Keep track of the frequency of each token.
// 2. Keep track of the list of token hashes for each symbol.
Tokenize(name, [&tokens, &symbol_tokens, addr](base::StringView token) {
// Strip the .cfi part if present.
if (token.substr(token.size() - 4) == ".cfi")
token = token.substr(0, token.size() - 4);
auto it_and_ins = tokens.emplace(token.ToStdString(), TokenInfo{});
it_and_ins.first->second.count++;
symbol_tokens.emplace_back(SymAddrAndTokenPtr{addr, &*it_and_ins.first});
});
});
symbol_tokens.shrink_to_fit();
// For each symbol address, T entries are inserted into |symbol_tokens|, one
// for each token. These symbols are added in arbitrary address (as seen in
// /proc/kallsyms). Here we want to sort symbols by addresses, but at the same
// time preserve the order of tokens within each address.
// For instance, if kallsyms has: {0x41: connect_socket, 0x42: write_file}:
// Before sort: [(0x42, write), (0x42, file), (0x41, connect), (0x41, socket)]
// After sort: [(0x41, connect), (0x41, socket), (0x42, write), (0x42, file)]
std::stable_sort(symbol_tokens.begin(), symbol_tokens.end());
// At this point we have broken down each symbol into a set of token hashes.
// Now generate the token ids, putting high freq tokens first, so they use
// only one byte to varint encode.
// This block limits the lifetime of |tokens_by_freq|.
{
std::vector<TokenMapPtr> tokens_by_freq;
tokens_by_freq.resize(tokens.size());
size_t tok_idx = 0;
for (auto& kv : tokens)
tokens_by_freq[tok_idx++] = &kv;
auto comparer = [](TokenMapPtr a, TokenMapPtr b) {
PERFETTO_DCHECK(a && b);
return b->second.count < a->second.count;
};
std::sort(tokens_by_freq.begin(), tokens_by_freq.end(), comparer);
for (TokenMapPtr tinfo : tokens_by_freq) {
tinfo->second.id = tokens_.Add(tinfo->first);
}
}
tokens_.shrink_to_fit();
buf_.resize(2 * 1024 * 1024); // Based on real-word observations.
base_addr_ = symbol_tokens.empty() ? 0 : symbol_tokens.begin()->addr;
SymAddr prev_sym_addr = base_addr_;
uint8_t* wptr = buf_.data();
for (auto it = symbol_tokens.begin(); it != symbol_tokens.end();) {
const SymAddr sym_addr = it->addr;
// Find the iterator to the first token of the next symbol (or the end).
auto sym_start = it;
auto sym_end = it;
while (sym_end != symbol_tokens.end() && sym_end->addr == sym_addr)
++sym_end;
// The range [sym_start, sym_end) has all the tokens for the current symbol.
uint32_t size_before = static_cast<uint32_t>(wptr - buf_.data());
// Make sure there is enough headroom to write the symbol.
if (buf_.size() - size_before < 1024) {
buf_.resize(buf_.size() + 32768);
wptr = buf_.data() + size_before;
}
uint32_t sym_rel_addr = static_cast<uint32_t>(sym_addr - base_addr_);
const size_t sym_num = num_syms_++;
if (sym_num % kSymIndexSampling == 0)
index_.emplace_back(std::make_pair(sym_rel_addr, size_before));
PERFETTO_DCHECK(sym_addr >= prev_sym_addr);
uint32_t delta = static_cast<uint32_t>(sym_addr - prev_sym_addr);
wptr = protozero::proto_utils::WriteVarInt(delta, wptr);
// Append all the token ids.
for (it = sym_start; it != sym_end;) {
PERFETTO_DCHECK(it->addr == sym_addr);
TokenMapPtr const token_map_entry = it->token_map_entry;
const TokenInfo& token_info = token_map_entry->second;
TokenId token_id = token_info.id << 1;
++it;
token_id |= (it == sym_end) ? 1 : 0; // Last one has LSB set to 1.
wptr = protozero::proto_utils::WriteVarInt(token_id, wptr);
}
prev_sym_addr = sym_addr;
} // for (symbols)
buf_.resize(static_cast<size_t>(wptr - buf_.data()));
buf_.shrink_to_fit();
base::MaybeReleaseAllocatorMemToOS(); // For Scudo, b/170217718.
if (num_syms_ == 0) {
PERFETTO_ELOG(
"Failed to parse kallsyms. Kernel functions will not be symbolized. On "
"Linux this requires either running traced_probes as root or manually "
"lowering /proc/sys/kernel/kptr_restrict");
} else {
PERFETTO_DLOG(
"Loaded %zu kalllsyms entries. Mem usage: %zu B (addresses) + %zu B "
"(tokens), total: %zu B",
num_syms_, addr_bytes(), tokens_.size_bytes(), size_bytes());
}
return num_syms_;
}
std::string KernelSymbolMap::Lookup(uint64_t sym_addr) {
if (index_.empty() || sym_addr < base_addr_)
return "";
// First find the highest symbol address <= sym_addr.
// Start with a binary search using the sparse index.
const uint32_t sym_rel_addr = static_cast<uint32_t>(sym_addr - base_addr_);
auto it = std::upper_bound(index_.cbegin(), index_.cend(),
std::make_pair(sym_rel_addr, 0u));
if (it != index_.cbegin())
--it;
// Then continue with a linear scan (of at most kSymIndexSampling steps).
uint32_t addr = it->first;
uint32_t off = it->second;
const uint8_t* rdptr = &buf_[off];
const uint8_t* const buf_end = buf_.data() + buf_.size();
bool parsing_addr = true;
const uint8_t* next_rdptr = nullptr;
uint64_t sym_start_addr = 0;
for (bool is_first_addr = true;; is_first_addr = false) {
uint64_t v = 0;
const auto* prev_rdptr = rdptr;
rdptr = protozero::proto_utils::ParseVarInt(rdptr, buf_end, &v);
if (rdptr == prev_rdptr)
break;
if (parsing_addr) {
addr += is_first_addr ? 0 : static_cast<uint32_t>(v);
parsing_addr = false;
if (addr > sym_rel_addr)
break;
next_rdptr = rdptr;
sym_start_addr = addr;
} else {
// This is a token. Wait for the EOF maker.
parsing_addr = (v & 1) == 1;
}
}
if (!next_rdptr)
return "";
PERFETTO_DCHECK(sym_rel_addr >= sym_start_addr);
// If this address is too far from the start of the symbol, this is likely
// a pointer to something else (e.g. some vmalloc struct) and we just picked
// the very last symbol for a loader region.
if (sym_rel_addr - sym_start_addr > kSymMaxSizeBytes)
return "";
// The address has been found. Now rejoin the tokens to form the symbol name.
rdptr = next_rdptr;
std::string sym_name;
sym_name.reserve(kSymNameMaxLen);
for (bool eof = false, is_first_token = true; !eof; is_first_token = false) {
uint64_t v = 0;
const auto* old = rdptr;
rdptr = protozero::proto_utils::ParseVarInt(rdptr, buf_end, &v);
if (rdptr == old)
break;
eof = v & 1;
base::StringView token = tokens_.Lookup(static_cast<TokenId>(v >> 1));
if (!is_first_token)
sym_name.push_back('_');
for (size_t i = 0; i < token.size(); i++)
sym_name.push_back(token.at(i) & 0x7f);
}
return sym_name;
}
} // namespace perfetto