third_party/perfetto/src/kallsyms/kernel_symbol_map.h - cobalt - Git at Google

 /*
  * 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.
  */

 #ifndef SRC_KALLSYMS_KERNEL_SYMBOL_MAP_H_
 #define SRC_KALLSYMS_KERNEL_SYMBOL_MAP_H_

 #include <stdint.h>

 #include <array>
 #include <forward_list>
 #include <string>
 #include <vector>

 namespace perfetto {

 namespace base {
 class StringView;
 }

 // A parser and memory-efficient container for /proc/kallsyms.
 // It can store a full kernel symbol table in ~1.2MB of memory and perform fast
 // lookups using logarithmic binary searches + bounded linear scans.
 //
 // /proc/kallsyms is a ~10 MB text file that contains the map of kernel symbols,
 // as follows:
 // ffffff8f77682f8c t el0_sync_invalid
 // ffffff8f77683060 t el0_irq_invalid
 // ...
 // In a typipcal Android kernel, it consists of 213K lines. Out of these, only
 // 116K are interesting for the sake of symbolizing kernel functions, the rest
 // are .rodata (variables), weak or other useless symbols.
 // Still, even keeping around 116K pointers would require 116K * 8 ~= 1 MB of
 // memory, without accounting for any strings for the symbols names.
 // The SUM(str.len) for the 116K symbol names adds up to 2.7 MB (without
 // counting their addresses).
 // However consider the following:
 // - Symbol addresses are mostly contiguous. Modulo the initial KASLR loading
 //   address, most symbols are few hundreds bytes apart from each other.
 // - Symbol names are made of tokens that are quite frequent (token: the result
 //   of name.split('_')). If we tokenize the 2.7 MB of strings, the resulting
 //   SUM(distinct_token.len) goes down 2.7MB -> 146 KB. This is because tokens
 //   like "get", "set" or "event" show up thousands of times.
 // - Symbol names are ASCII strings using only 7 out of 8 bits.
 //
 // In the light of this, the in-memory architecture of this data structure is
 // as follows:
 // We keep two tables around: (1) a token table and (2) a symbol table. Both
 // table are a flat byte vector with some sparse lookaside index to make lookups
 // faster and avoid full linear scans.
 //
 // Token table
 // -----------
 // The token table is a flat char buffer. Tokens are variable size (>0). Each
 // token is identified by its ordinality, so token id 3 is the 3rd token in
 // the table. All tokens are concatenated together.
 // Given the ASCII encoding, the MSB is used as a terminator. So instead of
 // wasting an extra NUL byte for each string, the last char of each token has
 // the MSB set.
 // Furthermore, a lookaside index stores the offset of tokens (i.e. Token N
 // starts at offset O in the buffer) to allow fast lookups. In order to avoid
 // wasting too much memory, the index is sparse and track the offsets of only
 // one every kTokenIndexSamplinig tokens.
 // When looking up a token ID N, the table seeks at the offset of the closest
 // token <= N, and then scans linearly the next (at most kTokenIndexSamplinig)
 // tokens, counting the MSBs found, until the right token id is found.
 // buf:   set*get*kernel*load*fpsimd*return*wrapper*el0*skip*sync*neon*bit*aes
 //        ^                   ^                         ^
 //        |                   |                         |
 // index: 0@0                 4@15                      8@21

 // Symbol table
 // ------------
 // The symbol table is a flat char buffer that stores for each symbol: its
 // address + the list of token indexes in the token table. The main caveats are
 // that:
 // - Symbol addresses are delta encoded (delta from prev symbol's addr).
 // - Both delta addresses and token indexes are var-int encoded.
 // - The LSB of token indexes is used as EOF marker (i.e. the next varint is
 //   the delta-addr for the next symbol). This time the LSB is used because of
 //   the varint encoding.
 // At parsing time symbols are ordered by address and tokens are sorted by
 // frequency, so that the top used 64 tokens can be represented with 1 byte.
 // (Rationale for 64: 1 byte = 8 bits. The MSB bit of each byte is used for the
 // varint encoding, the LSB bit of each number is used as end-of-tokens marker.
 // There are 6 bits left -> 64 indexes can be represented using one byte).
 // In summary the symbol table looks as follows:
 //
 // Base address: 0xbeef0000
 // Symbol buffer:
 // 0 1|0  4|0  6|1    // 0xbeef0000: 1,4,6 -> get_fpsimd_wrapper
 // 8 7|0  3|1         // 0xbeef0008: 7,3   -> el0_load
 // ...
 // Like in the case of the token table, a lookaside index keeps track of the
 // offset of one every kSymIndexSamplinig addresses.
 // The Lookup(ADDR) function operates as follows:
 // 1. Performs a logarithmic binary search in the symbols index, finding the
 //    offset of the closest addres <= ADDR.
 // 2. Skip over at most kSymIndexSamplinig until the symbol is found.
 // 3. For each token index, lookup the corresponding token string and
 //    concatenate them to build the symbol name.

 class KernelSymbolMap {
  public:
   // The two constants below are changeable only for the benchmark use.
   // Trades off size of the root |index_| vs worst-case linear scans size.
   // A higher number makes the index more sparse.
   static size_t kSymIndexSampling;

   // Trades off size of the TokenTable |index_| vs worst-case linear scans size.
   static size_t kTokenIndexSampling;

   // Parses a kallsyms file. Returns the number of valid symbols decoded.
   size_t Parse(const std::string& kallsyms_path);

   // Looks up the closest symbol (i.e. the one with the highest address <=
   // |addr|) from its absolute 64-bit address.
   // Returns an empty string if the symbol is not found (which can happen only
   // if the passed |addr| is < min(addr)).
   std::string Lookup(uint64_t addr);

   // Returns the numberr of valid symbols decoded.
   size_t num_syms() const { return num_syms_; }

   // Returns the size in bytes used by the adddress table (without counting
   // the tokens).
   size_t addr_bytes() const { return buf_.size() + index_.size() * 8; }

   // Returns the total memory usage in bytes.
   size_t size_bytes() const { return addr_bytes() + tokens_.size_bytes(); }

   // Token table.
   class TokenTable {
    public:
     using TokenId = uint32_t;
     TokenTable();
     ~TokenTable();
     TokenId Add(const std::string&);
     base::StringView Lookup(TokenId);
     size_t size_bytes() const { return buf_.size() + index_.size() * 4; }

     void shrink_to_fit() {
       buf_.shrink_to_fit();
       index_.shrink_to_fit();
     }

    private:
     TokenId num_tokens_ = 0;

     std::vector<char> buf_;  // Token buffer.

     // The value i-th in the vector contains the offset (within |buf_|) of the
     // (i * kTokenIndexSamplinig)-th token.
     std::vector<uint32_t> index_;
   };

  private:
   TokenTable tokens_;  // Token table.

   uint64_t base_addr_ = 0;    // Address of the first symbol (after sorting).
   size_t num_syms_ = 0;       // Number of valid symbols stored.
   std::vector<uint8_t> buf_;  // Symbol buffer.

   // The key is (address - base_addr_), the value is the byte offset in |buf_|
   // where the symbol entry starts (i.e. the start of the varint that tells the
   // delta from the previous symbol).
   std::vector<std::pair<uint32_t /*rel_addr*/, uint32_t /*offset*/>> index_;
 };

 }  // namespace perfetto

 #endif  // SRC_KALLSYMS_KERNEL_SYMBOL_MAP_H_
	/*
	* 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.
	*/

	#ifndef SRC_KALLSYMS_KERNEL_SYMBOL_MAP_H_
	#define SRC_KALLSYMS_KERNEL_SYMBOL_MAP_H_

	#include <stdint.h>

	#include <array>
	#include <forward_list>
	#include <string>
	#include <vector>

	namespace perfetto {

	namespace base {
	class StringView;
	}

	// A parser and memory-efficient container for /proc/kallsyms.
	// It can store a full kernel symbol table in ~1.2MB of memory and perform fast
	// lookups using logarithmic binary searches + bounded linear scans.
	//
	// /proc/kallsyms is a ~10 MB text file that contains the map of kernel symbols,
	// as follows:
	// ffffff8f77682f8c t el0_sync_invalid
	// ffffff8f77683060 t el0_irq_invalid
	// ...
	// In a typipcal Android kernel, it consists of 213K lines. Out of these, only
	// 116K are interesting for the sake of symbolizing kernel functions, the rest
	// are .rodata (variables), weak or other useless symbols.
	// Still, even keeping around 116K pointers would require 116K * 8 ~= 1 MB of
	// memory, without accounting for any strings for the symbols names.
	// The SUM(str.len) for the 116K symbol names adds up to 2.7 MB (without
	// counting their addresses).
	// However consider the following:
	// - Symbol addresses are mostly contiguous. Modulo the initial KASLR loading
	// address, most symbols are few hundreds bytes apart from each other.
	// - Symbol names are made of tokens that are quite frequent (token: the result
	// of name.split('_')). If we tokenize the 2.7 MB of strings, the resulting
	// SUM(distinct_token.len) goes down 2.7MB -> 146 KB. This is because tokens
	// like "get", "set" or "event" show up thousands of times.
	// - Symbol names are ASCII strings using only 7 out of 8 bits.
	//
	// In the light of this, the in-memory architecture of this data structure is
	// as follows:
	// We keep two tables around: (1) a token table and (2) a symbol table. Both
	// table are a flat byte vector with some sparse lookaside index to make lookups
	// faster and avoid full linear scans.
	//
	// Token table
	// -----------
	// The token table is a flat char buffer. Tokens are variable size (>0). Each
	// token is identified by its ordinality, so token id 3 is the 3rd token in
	// the table. All tokens are concatenated together.
	// Given the ASCII encoding, the MSB is used as a terminator. So instead of
	// wasting an extra NUL byte for each string, the last char of each token has
	// the MSB set.
	// Furthermore, a lookaside index stores the offset of tokens (i.e. Token N
	// starts at offset O in the buffer) to allow fast lookups. In order to avoid
	// wasting too much memory, the index is sparse and track the offsets of only
	// one every kTokenIndexSamplinig tokens.
	// When looking up a token ID N, the table seeks at the offset of the closest
	// token <= N, and then scans linearly the next (at most kTokenIndexSamplinig)
	// tokens, counting the MSBs found, until the right token id is found.
	// buf: setgetkernelloadfpsimdreturnwrapperel0skipsyncneonbitaes
	// ^ ^ ^
	// \| \| \|
	// index: 0@0 4@15 8@21

	// Symbol table
	// ------------
	// The symbol table is a flat char buffer that stores for each symbol: its
	// address + the list of token indexes in the token table. The main caveats are
	// that:
	// - Symbol addresses are delta encoded (delta from prev symbol's addr).
	// - Both delta addresses and token indexes are var-int encoded.
	// - The LSB of token indexes is used as EOF marker (i.e. the next varint is
	// the delta-addr for the next symbol). This time the LSB is used because of
	// the varint encoding.
	// At parsing time symbols are ordered by address and tokens are sorted by
	// frequency, so that the top used 64 tokens can be represented with 1 byte.
	// (Rationale for 64: 1 byte = 8 bits. The MSB bit of each byte is used for the
	// varint encoding, the LSB bit of each number is used as end-of-tokens marker.
	// There are 6 bits left -> 64 indexes can be represented using one byte).
	// In summary the symbol table looks as follows:
	//
	// Base address: 0xbeef0000
	// Symbol buffer:
	// 0 1\|0 4\|0 6\|1 // 0xbeef0000: 1,4,6 -> get_fpsimd_wrapper
	// 8 7\|0 3\|1 // 0xbeef0008: 7,3 -> el0_load
	// ...
	// Like in the case of the token table, a lookaside index keeps track of the
	// offset of one every kSymIndexSamplinig addresses.
	// The Lookup(ADDR) function operates as follows:
	// 1. Performs a logarithmic binary search in the symbols index, finding the
	// offset of the closest addres <= ADDR.
	// 2. Skip over at most kSymIndexSamplinig until the symbol is found.
	// 3. For each token index, lookup the corresponding token string and
	// concatenate them to build the symbol name.

	class KernelSymbolMap {
	public:
	// The two constants below are changeable only for the benchmark use.
	// Trades off size of the root \|index_\| vs worst-case linear scans size.
	// A higher number makes the index more sparse.
	static size_t kSymIndexSampling;

	// Trades off size of the TokenTable \|index_\| vs worst-case linear scans size.
	static size_t kTokenIndexSampling;

	// Parses a kallsyms file. Returns the number of valid symbols decoded.
	size_t Parse(const std::string& kallsyms_path);

	// Looks up the closest symbol (i.e. the one with the highest address <=
	// \|addr\|) from its absolute 64-bit address.
	// Returns an empty string if the symbol is not found (which can happen only
	// if the passed \|addr\| is < min(addr)).
	std::string Lookup(uint64_t addr);

	// Returns the numberr of valid symbols decoded.
	size_t num_syms() const { return num_syms_; }

	// Returns the size in bytes used by the adddress table (without counting
	// the tokens).
	size_t addr_bytes() const { return buf_.size() + index_.size() * 8; }

	// Returns the total memory usage in bytes.
	size_t size_bytes() const { return addr_bytes() + tokens_.size_bytes(); }

	// Token table.
	class TokenTable {
	public:
	using TokenId = uint32_t;
	TokenTable();
	~TokenTable();
	TokenId Add(const std::string&);
	base::StringView Lookup(TokenId);
	size_t size_bytes() const { return buf_.size() + index_.size() * 4; }

	void shrink_to_fit() {
	buf_.shrink_to_fit();
	index_.shrink_to_fit();
	}

	private:
	TokenId num_tokens_ = 0;

	std::vector<char> buf_; // Token buffer.

	// The value i-th in the vector contains the offset (within \|buf_\|) of the
	// (i * kTokenIndexSamplinig)-th token.
	std::vector<uint32_t> index_;
	};

	private:
	TokenTable tokens_; // Token table.

	uint64_t base_addr_ = 0; // Address of the first symbol (after sorting).
	size_t num_syms_ = 0; // Number of valid symbols stored.
	std::vector<uint8_t> buf_; // Symbol buffer.

	// The key is (address - base_addr_), the value is the byte offset in \|buf_\|
	// where the symbol entry starts (i.e. the start of the varint that tells the
	// delta from the previous symbol).
	std::vector<std::pair<uint32_t /rel_addr/, uint32_t /offset/>> index_;
	};

	} // namespace perfetto

	#endif // SRC_KALLSYMS_KERNEL_SYMBOL_MAP_H_