mirror of
https://github.com/clementine-player/Clementine
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311 lines
14 KiB
C++
311 lines
14 KiB
C++
// -*- mode: C++ -*-
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// Copyright (c) 2010 Google Inc. All Rights Reserved.
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//
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// Redistribution and use in source and binary forms, with or without
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// modification, are permitted provided that the following conditions are
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// met:
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//
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// * Redistributions of source code must retain the above copyright
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// notice, this list of conditions and the following disclaimer.
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// * Redistributions in binary form must reproduce the above
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// copyright notice, this list of conditions and the following disclaimer
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// in the documentation and/or other materials provided with the
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// distribution.
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// * Neither the name of Google Inc. nor the names of its
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// contributors may be used to endorse or promote products derived from
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// this software without specific prior written permission.
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//
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// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
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// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
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// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
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// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
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// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
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// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
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// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
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// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
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// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
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// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
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// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
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#ifndef COMMON_DWARF_BYTEREADER_H__
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#define COMMON_DWARF_BYTEREADER_H__
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#include <string>
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#include "common/dwarf/types.h"
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#include "common/dwarf/dwarf2enums.h"
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namespace dwarf2reader {
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// We can't use the obvious name of LITTLE_ENDIAN and BIG_ENDIAN
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// because it conflicts with a macro
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enum Endianness {
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ENDIANNESS_BIG,
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ENDIANNESS_LITTLE
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};
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// A ByteReader knows how to read single- and multi-byte values of
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// various endiannesses, sizes, and encodings, as used in DWARF
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// debugging information and Linux C++ exception handling data.
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class ByteReader {
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public:
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// Construct a ByteReader capable of reading one-, two-, four-, and
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// eight-byte values according to ENDIANNESS, absolute machine-sized
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// addresses, DWARF-style "initial length" values, signed and
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// unsigned LEB128 numbers, and Linux C++ exception handling data's
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// encoded pointers.
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explicit ByteReader(enum Endianness endianness);
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virtual ~ByteReader();
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// Read a single byte from BUFFER and return it as an unsigned 8 bit
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// number.
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uint8 ReadOneByte(const char* buffer) const;
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// Read two bytes from BUFFER and return them as an unsigned 16 bit
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// number, using this ByteReader's endianness.
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uint16 ReadTwoBytes(const char* buffer) const;
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// Read four bytes from BUFFER and return them as an unsigned 32 bit
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// number, using this ByteReader's endianness. This function returns
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// a uint64 so that it is compatible with ReadAddress and
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// ReadOffset. The number it returns will never be outside the range
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// of an unsigned 32 bit integer.
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uint64 ReadFourBytes(const char* buffer) const;
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// Read eight bytes from BUFFER and return them as an unsigned 64
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// bit number, using this ByteReader's endianness.
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uint64 ReadEightBytes(const char* buffer) const;
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// Read an unsigned LEB128 (Little Endian Base 128) number from
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// BUFFER and return it as an unsigned 64 bit integer. Set LEN to
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// the number of bytes read.
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//
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// The unsigned LEB128 representation of an integer N is a variable
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// number of bytes:
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//
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// - If N is between 0 and 0x7f, then its unsigned LEB128
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// representation is a single byte whose value is N.
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//
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// - Otherwise, its unsigned LEB128 representation is (N & 0x7f) |
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// 0x80, followed by the unsigned LEB128 representation of N /
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// 128, rounded towards negative infinity.
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//
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// In other words, we break VALUE into groups of seven bits, put
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// them in little-endian order, and then write them as eight-bit
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// bytes with the high bit on all but the last.
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uint64 ReadUnsignedLEB128(const char* buffer, size_t* len) const;
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// Read a signed LEB128 number from BUFFER and return it as an
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// signed 64 bit integer. Set LEN to the number of bytes read.
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//
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// The signed LEB128 representation of an integer N is a variable
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// number of bytes:
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//
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// - If N is between -0x40 and 0x3f, then its signed LEB128
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// representation is a single byte whose value is N in two's
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// complement.
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//
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// - Otherwise, its signed LEB128 representation is (N & 0x7f) |
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// 0x80, followed by the signed LEB128 representation of N / 128,
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// rounded towards negative infinity.
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//
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// In other words, we break VALUE into groups of seven bits, put
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// them in little-endian order, and then write them as eight-bit
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// bytes with the high bit on all but the last.
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int64 ReadSignedLEB128(const char* buffer, size_t* len) const;
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// Indicate that addresses on this architecture are SIZE bytes long. SIZE
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// must be either 4 or 8. (DWARF allows addresses to be any number of
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// bytes in length from 1 to 255, but we only support 32- and 64-bit
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// addresses at the moment.) You must call this before using the
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// ReadAddress member function.
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//
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// For data in a .debug_info section, or something that .debug_info
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// refers to like line number or macro data, the compilation unit
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// header's address_size field indicates the address size to use. Call
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// frame information doesn't indicate its address size (a shortcoming of
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// the spec); you must supply the appropriate size based on the
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// architecture of the target machine.
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void SetAddressSize(uint8 size);
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// Return the current address size, in bytes. This is either 4,
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// indicating 32-bit addresses, or 8, indicating 64-bit addresses.
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uint8 AddressSize() const { return address_size_; }
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// Read an address from BUFFER and return it as an unsigned 64 bit
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// integer, respecting this ByteReader's endianness and address size. You
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// must call SetAddressSize before calling this function.
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uint64 ReadAddress(const char* buffer) const;
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// DWARF actually defines two slightly different formats: 32-bit DWARF
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// and 64-bit DWARF. This is *not* related to the size of registers or
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// addresses on the target machine; it refers only to the size of section
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// offsets and data lengths appearing in the DWARF data. One only needs
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// 64-bit DWARF when the debugging data itself is larger than 4GiB.
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// 32-bit DWARF can handle x86_64 or PPC64 code just fine, unless the
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// debugging data itself is very large.
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//
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// DWARF information identifies itself as 32-bit or 64-bit DWARF: each
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// compilation unit and call frame information entry begins with an
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// "initial length" field, which, in addition to giving the length of the
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// data, also indicates the size of section offsets and lengths appearing
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// in that data. The ReadInitialLength member function, below, reads an
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// initial length and sets the ByteReader's offset size as a side effect.
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// Thus, in the normal process of reading DWARF data, the appropriate
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// offset size is set automatically. So, you should only need to call
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// SetOffsetSize if you are using the same ByteReader to jump from the
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// midst of one block of DWARF data into another.
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// Read a DWARF "initial length" field from START, and return it as
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// an unsigned 64 bit integer, respecting this ByteReader's
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// endianness. Set *LEN to the length of the initial length in
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// bytes, either four or twelve. As a side effect, set this
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// ByteReader's offset size to either 4 (if we see a 32-bit DWARF
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// initial length) or 8 (if we see a 64-bit DWARF initial length).
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//
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// A DWARF initial length is either:
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//
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// - a byte count stored as an unsigned 32-bit value less than
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// 0xffffff00, indicating that the data whose length is being
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// measured uses the 32-bit DWARF format, or
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//
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// - The 32-bit value 0xffffffff, followed by a 64-bit byte count,
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// indicating that the data whose length is being measured uses
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// the 64-bit DWARF format.
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uint64 ReadInitialLength(const char* start, size_t* len);
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// Read an offset from BUFFER and return it as an unsigned 64 bit
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// integer, respecting the ByteReader's endianness. In 32-bit DWARF, the
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// offset is 4 bytes long; in 64-bit DWARF, the offset is eight bytes
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// long. You must call ReadInitialLength or SetOffsetSize before calling
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// this function; see the comments above for details.
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uint64 ReadOffset(const char* buffer) const;
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// Return the current offset size, in bytes.
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// A return value of 4 indicates that we are reading 32-bit DWARF.
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// A return value of 8 indicates that we are reading 64-bit DWARF.
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uint8 OffsetSize() const { return offset_size_; }
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// Indicate that section offsets and lengths are SIZE bytes long. SIZE
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// must be either 4 (meaning 32-bit DWARF) or 8 (meaning 64-bit DWARF).
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// Usually, you should not call this function yourself; instead, let a
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// call to ReadInitialLength establish the data's offset size
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// automatically.
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void SetOffsetSize(uint8 size);
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// The Linux C++ ABI uses a variant of DWARF call frame information
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// for exception handling. This data is included in the program's
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// address space as the ".eh_frame" section, and intepreted at
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// runtime to walk the stack, find exception handlers, and run
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// cleanup code. The format is mostly the same as DWARF CFI, with
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// some adjustments made to provide the additional
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// exception-handling data, and to make the data easier to work with
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// in memory --- for example, to allow it to be placed in read-only
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// memory even when describing position-independent code.
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//
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// In particular, exception handling data can select a number of
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// different encodings for pointers that appear in the data, as
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// described by the DwarfPointerEncoding enum. There are actually
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// four axes(!) to the encoding:
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//
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// - The pointer size: pointers can be 2, 4, or 8 bytes long, or use
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// the DWARF LEB128 encoding.
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//
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// - The pointer's signedness: pointers can be signed or unsigned.
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//
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// - The pointer's base address: the data stored in the exception
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// handling data can be the actual address (that is, an absolute
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// pointer), or relative to one of a number of different base
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// addreses --- including that of the encoded pointer itself, for
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// a form of "pc-relative" addressing.
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//
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// - The pointer may be indirect: it may be the address where the
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// true pointer is stored. (This is used to refer to things via
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// global offset table entries, program linkage table entries, or
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// other tricks used in position-independent code.)
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//
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// There are also two options that fall outside that matrix
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// altogether: the pointer may be omitted, or it may have padding to
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// align it on an appropriate address boundary. (That last option
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// may seem like it should be just another axis, but it is not.)
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// Indicate that the exception handling data is loaded starting at
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// SECTION_BASE, and that the start of its buffer in our own memory
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// is BUFFER_BASE. This allows us to find the address that a given
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// byte in our buffer would have when loaded into the program the
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// data describes. We need this to resolve DW_EH_PE_pcrel pointers.
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void SetCFIDataBase(uint64 section_base, const char *buffer_base);
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// Indicate that the base address of the program's ".text" section
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// is TEXT_BASE. We need this to resolve DW_EH_PE_textrel pointers.
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void SetTextBase(uint64 text_base);
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// Indicate that the base address for DW_EH_PE_datarel pointers is
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// DATA_BASE. The proper value depends on the ABI; it is usually the
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// address of the global offset table, held in a designated register in
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// position-independent code. You will need to look at the startup code
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// for the target system to be sure. I tried; my eyes bled.
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void SetDataBase(uint64 data_base);
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// Indicate that the base address for the FDE we are processing is
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// FUNCTION_BASE. This is the start address of DW_EH_PE_funcrel
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// pointers. (This encoding does not seem to be used by the GNU
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// toolchain.)
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void SetFunctionBase(uint64 function_base);
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// Indicate that we are no longer processing any FDE, so any use of
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// a DW_EH_PE_funcrel encoding is an error.
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void ClearFunctionBase();
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// Return true if ENCODING is a valid pointer encoding.
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bool ValidEncoding(DwarfPointerEncoding encoding) const;
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// Return true if we have all the information we need to read a
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// pointer that uses ENCODING. This checks that the appropriate
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// SetFooBase function for ENCODING has been called.
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bool UsableEncoding(DwarfPointerEncoding encoding) const;
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// Read an encoded pointer from BUFFER using ENCODING; return the
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// absolute address it represents, and set *LEN to the pointer's
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// length in bytes, including any padding for aligned pointers.
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//
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// This function calls 'abort' if ENCODING is invalid or refers to a
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// base address this reader hasn't been given, so you should check
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// with ValidEncoding and UsableEncoding first if you would rather
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// die in a more helpful way.
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uint64 ReadEncodedPointer(const char *buffer, DwarfPointerEncoding encoding,
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size_t *len) const;
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private:
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// Function pointer type for our address and offset readers.
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typedef uint64 (ByteReader::*AddressReader)(const char*) const;
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// Read an offset from BUFFER and return it as an unsigned 64 bit
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// integer. DWARF2/3 define offsets as either 4 or 8 bytes,
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// generally depending on the amount of DWARF2/3 info present.
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// This function pointer gets set by SetOffsetSize.
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AddressReader offset_reader_;
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// Read an address from BUFFER and return it as an unsigned 64 bit
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// integer. DWARF2/3 allow addresses to be any size from 0-255
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// bytes currently. Internally we support 4 and 8 byte addresses,
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// and will CHECK on anything else.
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// This function pointer gets set by SetAddressSize.
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AddressReader address_reader_;
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Endianness endian_;
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uint8 address_size_;
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uint8 offset_size_;
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// Base addresses for Linux C++ exception handling data's encoded pointers.
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bool have_section_base_, have_text_base_, have_data_base_;
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bool have_function_base_;
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uint64 section_base_, text_base_, data_base_, function_base_;
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const char *buffer_base_;
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};
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} // namespace dwarf2reader
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#endif // COMMON_DWARF_BYTEREADER_H__
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