courgette/disassembler.cc - Issue 115062: Move Courgette...

Unified Diff: courgette/disassembler.cc

Issue 115062: Move Courgette... (Closed) Base URL: svn://chrome-svn/chrome/trunk/src/

Patch Set: '' Created 11 years, 7 months ago

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Index: courgette/disassembler.cc

===================================================================

--- courgette/disassembler.cc (revision 0)

+++ courgette/disassembler.cc (revision 0)

@@ -0,0 +1,436 @@

+// Use of this source code is governed by a BSD-style license that can be

+// found in the LICENSE file.

+#include "courgette/disassembler.h"

+#include <algorithm>

+#include <iostream>

+#include <string>

+#include <vector>

+#include "base/basictypes.h"

+#include "base/logging.h"

+#include "courgette/assembly_program.h"

+#include "courgette/courgette.h"

+#include "courgette/encoded_program.h"

+#include "courgette/image_info.h"

+// COURGETTE_HISTOGRAM_TARGETS prints out a histogram of how frequently

+// different target addresses are referenced. Purely for debugging.

+#define COURGETTE_HISTOGRAM_TARGETS 0

+namespace courgette {

+class DisassemblerWin32X86 : public Disassembler {

+ public:

+ explicit DisassemblerWin32X86(PEInfo* pe_info)

+ : pe_info_(pe_info),

+ incomplete_disassembly_(false) {

+ }

+ virtual bool Disassemble(AssemblyProgram* target);

+ virtual void Destroy() { delete this; }

+ protected:

+ PEInfo& pe_info() { return *pe_info_; }

+ void ParseFile(AssemblyProgram* target);

+ bool ParseAbs32Relocs();

+ void ParseRel32RelocsFromSections();

+ void ParseRel32RelocsFromSection(const Section* section);

+ void ParseNonSectionFileRegion(uint32 start_file_offset,

+ uint32 end_file_offset,

+ AssemblyProgram* program);

+ void ParseFileRegion(const Section* section,

+ uint32 start_file_offset, uint32 end_file_offset,

+ AssemblyProgram* program);

+#if COURGETTE_HISTOGRAM_TARGETS

+ void HistogramTargets(const char* kind, const std::map<RVA, int>& map);

+#endif

+ PEInfo* pe_info_;

+ bool incomplete_disassembly_; // 'true' if can leave out 'uninteresting' bits

+ std::vector<RVA> abs32_locations_;

+ std::vector<RVA> rel32_locations_;

+#if COURGETTE_HISTOGRAM_TARGETS

+ std::map<RVA, int> abs32_target_rvas_;

+ std::map<RVA, int> rel32_target_rvas_;

+#endif

+};

+bool DisassemblerWin32X86::Disassemble(AssemblyProgram* target) {

+ if (!pe_info().ok())

+ return false;

+ target->set_image_base(pe_info().image_base());

+ if (!ParseAbs32Relocs())

+ return false;

+ ParseRel32RelocsFromSections();

+ ParseFile(target);

+ target->DefaultAssignIndexes();

+ return true;

+static uint32 Read32LittleEndian(const void* address) {

+ return *reinterpret_cast<const uint32*>(address);

+bool DisassemblerWin32X86::ParseAbs32Relocs() {

+ abs32_locations_.clear();

+ if (!pe_info().ParseRelocs(&abs32_locations_))

+ return false;

+ std::sort(abs32_locations_.begin(), abs32_locations_.end());

+#if COURGETTE_HISTOGRAM_TARGETS

+ for (size_t i = 0; i < abs32_locations_.size(); ++i) {

+ RVA rva = abs32_locations_[i];

+ // The 4 bytes at the relocation are a reference to some address.

+ uint32 target_address = Read32LittleEndian(pe_info().RVAToPointer(rva));

+ ++abs32_target_rvas_[target_address - pe_info().image_base()];

+ }

+#endif

+ return true;

+void DisassemblerWin32X86::ParseRel32RelocsFromSections() {

+ uint32 file_offset = 0;

+ while (file_offset < pe_info().length()) {

+ const Section* section = pe_info().FindNextSection(file_offset);

+ if (section == NULL)

+ break;

+ if (file_offset < section->file_offset_of_raw_data)

+ file_offset = section->file_offset_of_raw_data;

+ ParseRel32RelocsFromSection(section);

+ file_offset += section->size_of_raw_data;

+ }

+ std::sort(rel32_locations_.begin(), rel32_locations_.end());

+#if COURGETTE_HISTOGRAM_TARGETS

+ LOG(INFO) << "abs32_locations_ " << abs32_locations_.size();

+ LOG(INFO) << "rel32_locations_ " << rel32_locations_.size();

+ LOG(INFO) << "abs32_target_rvas_ " << abs32_target_rvas_.size();

+ LOG(INFO) << "rel32_target_rvas_ " << rel32_target_rvas_.size();

+ int common = 0;

+ std::map<RVA, int>::iterator abs32_iter = abs32_target_rvas_.begin();

+ std::map<RVA, int>::iterator rel32_iter = rel32_target_rvas_.begin();

+ while (abs32_iter != abs32_target_rvas_.end() &&

+ rel32_iter != rel32_target_rvas_.end()) {

+ if (abs32_iter->first < rel32_iter->first)

+ ++abs32_iter;

+ else if (rel32_iter->first < abs32_iter->first)

+ ++rel32_iter;

+ else {

+ ++common;

+ ++abs32_iter;

+ ++rel32_iter;

+ }

+ LOG(INFO) << "common " << common;

+#endif

+void DisassemblerWin32X86::ParseRel32RelocsFromSection(const Section* section) {

+ // TODO(sra): use characteristic.

+ bool isCode = strcmp(section->name, ".text") == 0;

+ if (!isCode)

+ return;

+ uint32 start_file_offset = section->file_offset_of_raw_data;

+ uint32 end_file_offset = start_file_offset + section->size_of_raw_data;

+ RVA relocs_start_rva = pe_info().base_relocation_table().address_;

+ const uint8* start_pointer = pe_info().FileOffsetToPointer(start_file_offset);

+ const uint8* end_pointer = pe_info().FileOffsetToPointer(end_file_offset);

+ RVA start_rva = pe_info().FileOffsetToRVA(start_file_offset);

+ RVA end_rva = start_rva + section->virtual_size;

+ // Quick way to convert from Pointer to RVA within a single Section is to

+ // subtract 'pointer_to_rva'.

+ const uint8* const adjust_pointer_to_rva = start_pointer - start_rva;

+ std::vector<RVA>::iterator abs32_pos = abs32_locations_.begin();

+ // Find the rel32 relocations.

+ const uint8* p = start_pointer;

+ while (p < end_pointer) {

+ RVA current_rva = p - adjust_pointer_to_rva;

+ if (current_rva == relocs_start_rva) {

+ uint32 relocs_size = pe_info().base_relocation_table().size_;

+ if (relocs_size) {

+ p += relocs_size;

+ continue;

+ }

+ //while (abs32_pos != abs32_locations_.end() && *abs32_pos < current_rva)

+ // ++abs32_pos;

+ // 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* 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 rel32_rva = rel32 - adjust_pointer_to_rva;

+ // Is there an abs32 reloc overlapping the candidate?

+ while (abs32_pos != abs32_locations_.end() && *abs32_pos < rel32_rva - 3)

+ ++abs32_pos;

+ // Now: (*abs32_pos > rel32_rva - 4) i.e. the lowest addressed 4-byte

+ // region that could overlap rel32_rva.

+ if (abs32_pos != abs32_locations_.end()) {

+ if (*abs32_pos < rel32_rva + 4) {

+ // Beginning of abs32 reloc is before end of rel32 reloc so they

+ // overlap. Skip four bytes past the abs32 reloc.

+ p += (*abs32_pos + 4) - current_rva;

+ continue;

+ }

+ RVA target_rva = rel32_rva + 4 + Read32LittleEndian(rel32);

+ // To be valid, rel32 target must be within image, and within this

+ // section.

+ if (pe_info().IsValidRVA(target_rva) &&

+ start_rva <= target_rva && target_rva < end_rva) {

+ rel32_locations_.push_back(rel32_rva);

+#if COURGETTE_HISTOGRAM_TARGETS

+ ++rel32_target_rvas_[target_rva];

+#endif

+ p += 4;

+ continue;

+ }

+ p += 1;

+ }

+void DisassemblerWin32X86::ParseFile(AssemblyProgram* program) {

+ // Walk all the bytes in the file, whether or not in a section.

+ uint32 file_offset = 0;

+ while (file_offset < pe_info().length()) {

+ const Section* section = pe_info().FindNextSection(file_offset);

+ if (section == NULL) {

+ // No more sections. There should not be extra stuff following last

+ // section.

+ // ParseNonSectionFileRegion(file_offset, pe_info().length(), program);

+ break;

+ }

+ if (file_offset < section->file_offset_of_raw_data) {

+ uint32 section_start_offset = section->file_offset_of_raw_data;

+ ParseNonSectionFileRegion(file_offset, section_start_offset, program);

+ file_offset = section_start_offset;

+ }

+ uint32 end = file_offset + section->size_of_raw_data;

+ ParseFileRegion(section, file_offset, end, program);

+ file_offset = end;

+ }

+#if COURGETTE_HISTOGRAM_TARGETS

+ HistogramTargets("abs32 relocs", abs32_target_rvas_);

+ HistogramTargets("rel32 relocs", rel32_target_rvas_);

+#endif

+void DisassemblerWin32X86::ParseNonSectionFileRegion(

+ uint32 start_file_offset,

+ uint32 end_file_offset,

+ AssemblyProgram* program) {

+ if (incomplete_disassembly_)

+ return;

+ const uint8* start = pe_info().FileOffsetToPointer(start_file_offset);

+ const uint8* end = pe_info().FileOffsetToPointer(end_file_offset);

+ const uint8* p = start;

+ while (p < end) {

+ program->EmitByteInstruction(*p);

+ ++p;

+ }

+void DisassemblerWin32X86::ParseFileRegion(

+ const Section* section,

+ uint32 start_file_offset, uint32 end_file_offset,

+ AssemblyProgram* program) {

+ RVA relocs_start_rva = pe_info().base_relocation_table().address_;

+ const uint8* start_pointer = pe_info().FileOffsetToPointer(start_file_offset);

+ const uint8* end_pointer = pe_info().FileOffsetToPointer(end_file_offset);

+ RVA start_rva = pe_info().FileOffsetToRVA(start_file_offset);

+ RVA end_rva = start_rva + section->virtual_size;

+ // Quick way to convert from Pointer to RVA within a single Section is to

+ // subtract 'pointer_to_rva'.

+ const uint8* const adjust_pointer_to_rva = start_pointer - start_rva;

+ std::vector<RVA>::iterator rel32_pos = rel32_locations_.begin();

+ std::vector<RVA>::iterator abs32_pos = abs32_locations_.begin();

+ program->EmitOriginInstruction(start_rva);

+ const uint8* p = start_pointer;

+ while (p < end_pointer) {

+ RVA current_rva = p - adjust_pointer_to_rva;

+ // The base relocation table is usually in the .relocs section, but it could

+ // actually be anywhere. Make sure we skip it because we will regenerate it

+ // during assembly.

+ if (current_rva == relocs_start_rva) {

+ program->EmitMakeRelocsInstruction();

+ uint32 relocs_size = pe_info().base_relocation_table().size_;

+ if (relocs_size) {

+ p += relocs_size;

+ continue;

+ }

+ while (abs32_pos != abs32_locations_.end() && *abs32_pos < current_rva)

+ ++abs32_pos;

+ if (abs32_pos != abs32_locations_.end() && *abs32_pos == current_rva) {

+ uint32 target_address = Read32LittleEndian(p);

+ RVA target_rva = target_address - pe_info().image_base();

+ // TODO(sra): target could be Label+offset. It is not clear how to guess

+ // which it might be. We assume offset==0.

+ program->EmitAbs32(program->FindOrMakeAbs32Label(target_rva));

+ p += 4;

+ continue;

+ }

+ while (rel32_pos != rel32_locations_.end() && *rel32_pos < current_rva)

+ ++rel32_pos;

+ if (rel32_pos != rel32_locations_.end() && *rel32_pos == current_rva) {

+ RVA target_rva = current_rva + 4 + Read32LittleEndian(p);

+ program->EmitRel32(program->FindOrMakeRel32Label(target_rva));

+ p += 4;

+ continue;

+ }

+ if (incomplete_disassembly_) {

+ if ((abs32_pos == abs32_locations_.end() || end_rva <= *abs32_pos) &&

+ (rel32_pos == rel32_locations_.end() || end_rva <= *rel32_pos) &&

+ (end_rva <= relocs_start_rva || current_rva >= relocs_start_rva)) {

+ // No more relocs in this section, don't bother encoding bytes.

+ break;

+ }

+ program->EmitByteInstruction(*p);

+ p += 1;

+ }

+#if COURGETTE_HISTOGRAM_TARGETS

+// Histogram is printed to std::cout. It is purely for debugging the algorithm

+// and is only enabled manually in 'exploration' builds. I don't want to add

+// command-line configuration for this feature because this code has to be

+// small, which means compiled-out.

+void DisassemblerWin32X86::HistogramTargets(const char* kind,

+ const std::map<RVA, int>& map) {

+ int total = 0;

+ std::map<int, std::vector<RVA> > h;

+ for (std::map<RVA, int>::const_iterator p = map.begin();

+ p != map.end();

+ ++p) {

+ h[p->second].push_back(p->first);

+ total += p->second;

+ }

+ std::cout << total << " " << kind << " to "

+ << map.size() << " unique targets" << std::endl;

+ std::cout << "indegree: #targets-with-indegree (example)" << std::endl;

+ const int kFirstN = 15;

+ bool someSkipped = false;

+ int index = 0;

+ for (std::map<int, std::vector<RVA> >::reverse_iterator p = h.rbegin();

+ p != h.rend();

+ ++p) {

+ ++index;

+ if (index <= kFirstN || p->first <= 3) {

+ if (someSkipped) {

+ std::cout << "..." << std::endl;

+ }

+ size_t count = p->second.size();

+ std::cout << std::dec << p->first << ": " << count;

+ if (count <= 2) {

+ for (size_t i = 0; i < count; ++i)

+ std::cout << " " << pe_info().DescribeRVA(p->second[i]);

+ }

+ std::cout << std::endl;

+ someSkipped = false;

+ } else {

+ someSkipped = true;

+ }

+#endif // COURGETTE_HISTOGRAM_TARGETS

+Disassembler* Disassembler::MakeDisassemberWin32X86(PEInfo* pe_info) {

+ return new DisassemblerWin32X86(pe_info);

+////////////////////////////////////////////////////////////////////////////////

+Status ParseWin32X86PE(const void* buffer, size_t length,

+ AssemblyProgram** output) {

+ *output = NULL;

+ PEInfo* pe_info = new PEInfo();

+ pe_info->Init(buffer, length);

+ if (!pe_info->ParseHeader()) {

+ delete pe_info;

+ return C_INPUT_NOT_RECOGNIZED;

+ }

+ Disassembler* disassembler = Disassembler::MakeDisassemberWin32X86(pe_info);

+ AssemblyProgram* program = new AssemblyProgram();

+ if (!disassembler->Disassemble(program)) {

+ delete program;

+ disassembler->Destroy();

+ delete pe_info;

+ return C_DISASSEMBLY_FAILED;

+ }

+ disassembler->Destroy();

+ delete pe_info;

+ *output = program;

+ return C_OK;

+void DeleteAssemblyProgram(AssemblyProgram* program) {

+ delete program;

+} // namespace courgette

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