courgette/disassembler_elf_32_x86.cc - chromium/src - Git at Google

 // Copyright (c) 2012 The Chromium Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "courgette/disassembler_elf_32_x86.h"

 #include <stddef.h>
 #include <stdint.h>

 #include <algorithm>
 #include <string>
 #include <vector>

 #include "base/logging.h"

 #include "courgette/assembly_program.h"
 #include "courgette/courgette.h"
 #include "courgette/encoded_program.h"

 namespace courgette {

 DisassemblerElf32X86::DisassemblerElf32X86(const void* start, size_t length)
   : DisassemblerElf32(start, length) {
 }

 // Convert an ELF relocation struction into an RVA
 CheckBool DisassemblerElf32X86::RelToRVA(Elf32_Rel rel, RVA* result) const {

   // The rightmost byte of r_info is the type...
   elf32_rel_386_type_values type =
       (elf32_rel_386_type_values)(unsigned char)rel.r_info;

   // The other 3 bytes of r_info are the symbol
   uint32_t symbol = rel.r_info >> 8;

   switch(type)
   {
     case R_386_NONE:
     case R_386_32:
     case R_386_PC32:
     case R_386_GOT32:
     case R_386_PLT32:
     case R_386_COPY:
     case R_386_GLOB_DAT:
     case R_386_JMP_SLOT:
       return false;

     case R_386_RELATIVE:
       if (symbol != 0)
         return false;

       // This is a basic ABS32 relocation address
       *result = rel.r_offset;
       return true;

     case R_386_GOTOFF:
     case R_386_GOTPC:
     case R_386_TLS_TPOFF:
       return false;
   }

   return false;
 }

 CheckBool DisassemblerElf32X86::ParseRelocationSection(
     const Elf32_Shdr *section_header,
       AssemblyProgram* program) {
   // We can reproduce the R_386_RELATIVE entries in one of the relocation
   // table based on other information in the patch, given these
   // conditions....
   //
   // All R_386_RELATIVE entries are:
   //   1) In the same relocation table
   //   2) Are consecutive
   //   3) Are sorted in memory address order
   //
   // Happily, this is normally the case, but it's not required by spec
   // so we check, and just don't do it if we don't match up.

   // The expectation is that one relocation section will contain
   // all of our R_386_RELATIVE entries in the expected order followed
   // by assorted other entries we can't use special handling for.

   bool match = true;

   // Walk all the bytes in the section, matching relocation table or not
   size_t file_offset = section_header->sh_offset;
   size_t section_end = section_header->sh_offset + section_header->sh_size;

   Elf32_Rel *section_relocs_iter =
       (Elf32_Rel *)OffsetToPointer(section_header->sh_offset);

   uint32_t section_relocs_count =
       section_header->sh_size / section_header->sh_entsize;

   if (abs32_locations_.empty())
     match = false;

   if (abs32_locations_.size() > section_relocs_count)
     match = false;

   std::vector<RVA>::iterator reloc_iter = abs32_locations_.begin();

   while (match && (reloc_iter !=  abs32_locations_.end())) {
     if (section_relocs_iter->r_info != R_386_RELATIVE ||
         section_relocs_iter->r_offset != *reloc_iter)
       match = false;
     section_relocs_iter++;
     reloc_iter++;
   }

   if (match) {
     // Skip over relocation tables
     if (!program->EmitElfRelocationInstruction())
       return false;
     file_offset += sizeof(Elf32_Rel) * abs32_locations_.size();
   }

   return ParseSimpleRegion(file_offset, section_end, program);
 }

 CheckBool DisassemblerElf32X86::ParseRel32RelocsFromSection(
     const Elf32_Shdr* section_header) {
   uint32_t start_file_offset = section_header->sh_offset;
   uint32_t end_file_offset = start_file_offset + section_header->sh_size;

   const uint8_t* start_pointer = OffsetToPointer(start_file_offset);
   const uint8_t* end_pointer = OffsetToPointer(end_file_offset);

   // Quick way to convert from Pointer to RVA within a single Section is to
   // subtract 'pointer_to_rva'.
   const uint8_t* const adjust_pointer_to_rva =
       start_pointer - section_header->sh_addr;

   // Find the rel32 relocations.
   const uint8_t* p = start_pointer;
   while (p < end_pointer) {
     //RVA current_rva = static_cast<RVA>(p - adjust_pointer_to_rva);

     // Heuristic discovery of rel32 locations in instruction stream: are the
     // next few bytes the start of an instruction containing a rel32
     // addressing mode?
     const uint8_t* rel32 = NULL;

     if (p + 5 <= end_pointer) {
       if (*p == 0xE8 || *p == 0xE9) {  // jmp rel32 and call rel32
         rel32 = p + 1;
       }
     }
     if (p + 6 <= end_pointer) {
       if (*p == 0x0F  &&  (*(p+1) & 0xF0) == 0x80) {  // Jcc long form
         if (p[1] != 0x8A && p[1] != 0x8B)  // JPE/JPO unlikely
           rel32 = p + 2;
       }
     }
     if (rel32) {
       RVA rva = static_cast<RVA>(rel32 - adjust_pointer_to_rva);
       TypedRVAX86* rel32_rva = new TypedRVAX86(rva);

       if (!rel32_rva->ComputeRelativeTarget(rel32)) {
         delete rel32_rva;
         return false;
       }

       RVA target_rva = rel32_rva->rva() + rel32_rva->relative_target();
       // To be valid, rel32 target must be within image, and within this
       // section.
       if (IsValidRVA(target_rva)) {
         rel32_locations_.push_back(rel32_rva);
 #if COURGETTE_HISTOGRAM_TARGETS
         ++rel32_target_rvas_[target_rva];
 #endif
         p = rel32 + 4;
         continue;
       } else {
         delete rel32_rva;
       }
     }
     p += 1;
   }

   return true;
 }

 }  // namespace courgette
	// Copyright (c) 2012 The Chromium Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "courgette/disassembler_elf_32_x86.h"

	#include <stddef.h>
	#include <stdint.h>

	#include <algorithm>
	#include <string>
	#include <vector>

	#include "base/logging.h"

	#include "courgette/assembly_program.h"
	#include "courgette/courgette.h"
	#include "courgette/encoded_program.h"

	namespace courgette {

	DisassemblerElf32X86::DisassemblerElf32X86(const void* start, size_t length)
	: DisassemblerElf32(start, length) {
	}

	// Convert an ELF relocation struction into an RVA
	CheckBool DisassemblerElf32X86::RelToRVA(Elf32_Rel rel, RVA* result) const {

	// The rightmost byte of r_info is the type...
	elf32_rel_386_type_values type =
	(elf32_rel_386_type_values)(unsigned char)rel.r_info;

	// The other 3 bytes of r_info are the symbol
	uint32_t symbol = rel.r_info >> 8;

	switch(type)
	{
	case R_386_NONE:
	case R_386_32:
	case R_386_PC32:
	case R_386_GOT32:
	case R_386_PLT32:
	case R_386_COPY:
	case R_386_GLOB_DAT:
	case R_386_JMP_SLOT:
	return false;

	case R_386_RELATIVE:
	if (symbol != 0)
	return false;

	// This is a basic ABS32 relocation address
	*result = rel.r_offset;
	return true;

	case R_386_GOTOFF:
	case R_386_GOTPC:
	case R_386_TLS_TPOFF:
	return false;
	}

	return false;
	}

	CheckBool DisassemblerElf32X86::ParseRelocationSection(
	const Elf32_Shdr *section_header,
	AssemblyProgram* program) {
	// We can reproduce the R_386_RELATIVE entries in one of the relocation
	// table based on other information in the patch, given these
	// conditions....
	//
	// All R_386_RELATIVE entries are:
	// 1) In the same relocation table
	// 2) Are consecutive
	// 3) Are sorted in memory address order
	//
	// Happily, this is normally the case, but it's not required by spec
	// so we check, and just don't do it if we don't match up.

	// The expectation is that one relocation section will contain
	// all of our R_386_RELATIVE entries in the expected order followed
	// by assorted other entries we can't use special handling for.

	bool match = true;

	// Walk all the bytes in the section, matching relocation table or not
	size_t file_offset = section_header->sh_offset;
	size_t section_end = section_header->sh_offset + section_header->sh_size;

	Elf32_Rel *section_relocs_iter =
	(Elf32_Rel *)OffsetToPointer(section_header->sh_offset);

	uint32_t section_relocs_count =
	section_header->sh_size / section_header->sh_entsize;

	if (abs32_locations_.empty())
	match = false;

	if (abs32_locations_.size() > section_relocs_count)
	match = false;

	std::vector<RVA>::iterator reloc_iter = abs32_locations_.begin();

	while (match && (reloc_iter != abs32_locations_.end())) {
	if (section_relocs_iter->r_info != R_386_RELATIVE \|\|
	section_relocs_iter->r_offset != *reloc_iter)
	match = false;
	section_relocs_iter++;
	reloc_iter++;
	}

	if (match) {
	// Skip over relocation tables
	if (!program->EmitElfRelocationInstruction())
	return false;
	file_offset += sizeof(Elf32_Rel) * abs32_locations_.size();
	}

	return ParseSimpleRegion(file_offset, section_end, program);
	}

	CheckBool DisassemblerElf32X86::ParseRel32RelocsFromSection(
	const Elf32_Shdr* section_header) {
	uint32_t start_file_offset = section_header->sh_offset;
	uint32_t end_file_offset = start_file_offset + section_header->sh_size;

	const uint8_t* start_pointer = OffsetToPointer(start_file_offset);
	const uint8_t* end_pointer = OffsetToPointer(end_file_offset);

	// Quick way to convert from Pointer to RVA within a single Section is to
	// subtract 'pointer_to_rva'.
	const uint8_t* const adjust_pointer_to_rva =
	start_pointer - section_header->sh_addr;

	// Find the rel32 relocations.
	const uint8_t* p = start_pointer;
	while (p < end_pointer) {
	//RVA current_rva = static_cast<RVA>(p - adjust_pointer_to_rva);

	// Heuristic discovery of rel32 locations in instruction stream: are the
	// next few bytes the start of an instruction containing a rel32
	// addressing mode?
	const uint8_t* rel32 = NULL;

	if (p + 5 <= end_pointer) {
	if (p == 0xE8 \|\| p == 0xE9) { // jmp rel32 and call rel32
	rel32 = p + 1;
	}
	}
	if (p + 6 <= end_pointer) {
	if (p == 0x0F && ((p+1) & 0xF0) == 0x80) { // Jcc long form
	if (p[1] != 0x8A && p[1] != 0x8B) // JPE/JPO unlikely
	rel32 = p + 2;
	}
	}
	if (rel32) {
	RVA rva = static_cast<RVA>(rel32 - adjust_pointer_to_rva);
	TypedRVAX86* rel32_rva = new TypedRVAX86(rva);

	if (!rel32_rva->ComputeRelativeTarget(rel32)) {
	delete rel32_rva;
	return false;
	}

	RVA target_rva = rel32_rva->rva() + rel32_rva->relative_target();
	// To be valid, rel32 target must be within image, and within this
	// section.
	if (IsValidRVA(target_rva)) {
	rel32_locations_.push_back(rel32_rva);
	#if COURGETTE_HISTOGRAM_TARGETS
	++rel32_target_rvas_[target_rva];
	#endif
	p = rel32 + 4;
	continue;
	} else {
	delete rel32_rva;
	}
	}
	p += 1;
	}

	return true;
	}

	} // namespace courgette