chrome/browser/safe_browsing/incident_reporting/module_integrity_verifier_win.cc - chromium/src - Git at Google

 // Copyright 2014 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 "chrome/browser/safe_browsing/incident_reporting/module_integrity_verifier_win.h"

 #include <stddef.h>

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

 #include "base/files/file_path.h"
 #include "base/files/memory_mapped_file.h"
 #include "base/metrics/histogram_functions.h"
 #include "base/scoped_native_library.h"
 #include "base/stl_util.h"
 #include "base/strings/utf_string_conversions.h"
 #include "base/win/pe_image.h"
 #include "components/safe_browsing/proto/csd.pb.h"

 namespace safe_browsing {

 namespace {

 // The maximum amount of bytes that can be reported as modified by VerifyModule.
 const int kMaxModuleModificationBytes = 256;

 struct Export {
   Export(void* addr, const std::string& name);
   ~Export();

   bool operator<(const Export& other) const {
     return addr < other.addr;
   }

   void* addr;
   std::string name;
 };

 Export::Export(void* addr, const std::string& name) : addr(addr), name(name) {
 }

 Export::~Export() {
 }

 struct ModuleVerificationState {
   explicit ModuleVerificationState(HMODULE hModule);
   ~ModuleVerificationState();

   base::win::PEImageAsData disk_peimage;

   // The module's preferred base address minus the base address it actually
   // loaded at.
   intptr_t image_base_delta;

   // The location of the disk_peimage module's code section minus that of the
   // mem_peimage module's code section.
   intptr_t code_section_delta;

   // Set true if the relocation table contains a reloc of type that we don't
   // currently handle.
   bool unknown_reloc_type;

   // The start of the code section of the in-memory binary.
   uint8_t* mem_code_addr;

   // The start of the code section of the on-disk binary.
   uint8_t* disk_code_addr;

   // The size of the binary's code section.
   uint32_t code_size;

   // The exports of the DLL, sorted by address in ascending order.
   std::vector<Export> exports;

   // The location in the in-memory binary of the latest reloc encountered by
   // |EnumRelocsCallback|.
   uint8_t* last_mem_reloc_position;

   // The location in the on-disk binary of the latest reloc encountered by
   // |EnumRelocsCallback|.
   uint8_t* last_disk_reloc_position;

   // The number of bytes with a different value on disk and in memory, as
   // computed by |VerifyModule|.
   int bytes_different;

   // The module state protobuf object that |VerifyModule| will populate.
   ClientIncidentReport_EnvironmentData_Process_ModuleState* module_state;

  private:
   DISALLOW_COPY_AND_ASSIGN(ModuleVerificationState);
 };

 ModuleVerificationState::ModuleVerificationState(HMODULE hModule)
     : disk_peimage(hModule),
       image_base_delta(0),
       code_section_delta(0),
       unknown_reloc_type(false),
       mem_code_addr(nullptr),
       disk_code_addr(nullptr),
       code_size(0),
       last_mem_reloc_position(nullptr),
       last_disk_reloc_position(nullptr),
       bytes_different(0),
       module_state(nullptr) {
 }

 ModuleVerificationState::~ModuleVerificationState() {
 }

 // Find which export a modification at address |mem_address| is in. Looks for
 // the largest export address still smaller than |mem_address|. |start| and
 // |end| must come from a sorted collection.
 std::vector<Export>::const_iterator FindModifiedExport(
     uint8_t* mem_address,
     std::vector<Export>::const_iterator start,
     std::vector<Export>::const_iterator end) {
   // We get the largest export address still smaller than |addr|.  It is
   // possible that |addr| belongs to some nonexported function located
   // between this export and the following one.
   Export addr(reinterpret_cast<void*>(mem_address), std::string());
   return std::upper_bound(start, end, addr);
 }

 // Checks each byte in a subsection of the module's code section against the
 // corresponding byte on disk, returning the number of bytes differing between
 // the two. |state.exports| must be sorted.
 int ExamineByteRangeDiff(uint8_t* disk_start,
                          uint8_t* mem_start,
                          ptrdiff_t range_size,
                          ModuleVerificationState* state) {
   int bytes_different = 0;
   std::vector<Export>::const_iterator export_it = state->exports.begin();

   for (uint8_t* end = mem_start + range_size; mem_start < end;
        ++mem_start, ++disk_start) {
     if (*disk_start == *mem_start)
       continue;

     auto* modification = state->module_state->add_modification();
     // Store the address at which the modification starts on disk, relative to
     // the beginning of the image.
     modification->set_file_offset(
         disk_start - reinterpret_cast<uint8_t*>(state->disk_peimage.module()));

     // Find the export containing this modification.
     std::vector<Export>::const_iterator modified_export_it =
         FindModifiedExport(mem_start, export_it, state->exports.end());
     // No later byte can belong to an earlier export.
     export_it = modified_export_it;
     if (modified_export_it != state->exports.begin())
       modification->set_export_name((modified_export_it - 1)->name);

     const uint8_t* range_start = mem_start;
     while (mem_start < end && *disk_start != *mem_start) {
       ++disk_start;
       ++mem_start;
     }
     int bytes_in_modification = mem_start - range_start;
     bytes_different += bytes_in_modification;
     modification->set_byte_count(bytes_in_modification);
     modification->set_modified_bytes(
         range_start,
         std::min(bytes_in_modification, kMaxModuleModificationBytes));
   }
   return bytes_different;
 }

 bool AddrIsInCodeSection(void* address,
                          uint8_t* code_addr,
                          uint32_t code_size) {
   return (code_addr <= address && address < code_addr + code_size);
 }

 bool EnumRelocsCallback(const base::win::PEImage& mem_peimage,
                         WORD type,
                         void* address,
                         void* cookie) {
   ModuleVerificationState* state =
       reinterpret_cast<ModuleVerificationState*>(cookie);

   // If not in the code section return true to continue to the next reloc.
   if (!AddrIsInCodeSection(address, state->mem_code_addr, state->code_size))
     return true;

   switch (type) {
     case IMAGE_REL_BASED_ABSOLUTE:  // 0
       break;
     case IMAGE_REL_BASED_HIGHLOW:  // 3
       {
         // The range to inspect is from the last reloc to the current one at
         // |ptr|
         uint8_t* ptr = reinterpret_cast<uint8_t*>(address);

         // If the last relocation was not before this one in the binary,
         // there's an issue in the reloc section. We can't really recover from
         // that so flag state as such so the error can be logged.
         if (ptr < state->last_mem_reloc_position)
           return false;

         // Check which bytes of the relocation are not accounted for by the
         // rebase. If the beginning of the relocation is modified by something
         // other than the rebase, extend the verification range to include those
         // bytes since they are considered part of a modification.
         uint32_t relocated = *reinterpret_cast<uint32_t*>(ptr);
         uint32_t original = relocated + state->image_base_delta;
         uint8_t* original_reloc_bytes = reinterpret_cast<uint8_t*>(&original);
         uint8_t* reloc_disk_position = ptr + state->code_section_delta;
         size_t unaccounted_reloc_bytes = 0;
         while (unaccounted_reloc_bytes < sizeof(uint32_t) &&
                original_reloc_bytes[unaccounted_reloc_bytes] !=
                reloc_disk_position[unaccounted_reloc_bytes]) {
           ++unaccounted_reloc_bytes;
         }

         // If the entire reloc was modified, return true to let the next
         // EnumReloc track it as part of a larger modification.
         if (unaccounted_reloc_bytes == sizeof(uint32_t))
           return true;

         ptrdiff_t range_size = ptr +
                                unaccounted_reloc_bytes -
                                state->last_mem_reloc_position;

         state->bytes_different += ExamineByteRangeDiff(
             state->last_disk_reloc_position,
             state->last_mem_reloc_position,
             range_size,
             state);

         // Starting after the verified range, check if the relocation ends with
         // modified bytes. If it does, include them in the following range to be
         // verified as they're considered modified. Otherwise, the following
         // range will start right after the current reloc.
         size_t unmodified_reloc_byte_count = unaccounted_reloc_bytes;
         while (unmodified_reloc_byte_count < sizeof(uint32_t) &&
                original_reloc_bytes[unmodified_reloc_byte_count] ==
                reloc_disk_position[unmodified_reloc_byte_count]) {
           ++unmodified_reloc_byte_count;
         }
         state->last_disk_reloc_position +=
             range_size + unmodified_reloc_byte_count;
         state->last_mem_reloc_position +=
             range_size + unmodified_reloc_byte_count;
       }
       break;
     case IMAGE_REL_BASED_DIR64:  // 10
       break;
     default:
       // TODO(robertshield): Find a reliable description of the behaviour of the
       // remaining types of relocation and handle them.
       base::UmaHistogramSparse("SafeBrowsing.ModuleBaseRelocation", type);
       state->unknown_reloc_type = true;
       break;
   }
   return true;
 }

 bool EnumExportsCallback(const base::win::PEImage& mem_peimage,
                          DWORD ordinal,
                          DWORD hint,
                          LPCSTR name,
                          PVOID function_addr,
                          LPCSTR forward,
                          PVOID cookie) {
   std::vector<Export>* exports = reinterpret_cast<std::vector<Export>*>(cookie);
   if (name)
     exports->push_back(Export(function_addr, std::string(name)));
   return true;
 }

 }  // namespace

 bool GetCodeAddrsAndSize(const base::win::PEImage& mem_peimage,
                          const base::win::PEImageAsData& disk_peimage,
                          uint8_t** mem_code_addr,
                          uint8_t** disk_code_addr,
                          uint32_t* code_size) {
   DWORD base_of_code = mem_peimage.GetNTHeaders()->OptionalHeader.BaseOfCode;

   // Get the address and size of the code section in the loaded module image.
   PIMAGE_SECTION_HEADER mem_code_header =
       mem_peimage.GetImageSectionFromAddr(mem_peimage.RVAToAddr(base_of_code));
   if (mem_code_header == NULL)
     return false;
   *mem_code_addr = reinterpret_cast<uint8_t*>(
       mem_peimage.RVAToAddr(mem_code_header->VirtualAddress));
   // If the section is padded with zeros when mapped then |VirtualSize| can be
   // larger.  Alternatively, |SizeOfRawData| can be rounded up to align
   // according to OptionalHeader.FileAlignment.
   *code_size = std::min(mem_code_header->Misc.VirtualSize,
                         mem_code_header->SizeOfRawData);

   // Get the address of the code section in the module mapped as data from disk.
   DWORD disk_code_offset = 0;
   if (!mem_peimage.ImageAddrToOnDiskOffset(
           reinterpret_cast<void*>(*mem_code_addr), &disk_code_offset))
     return false;
   *disk_code_addr =
       reinterpret_cast<uint8_t*>(disk_peimage.module()) + disk_code_offset;
   return true;
 }

 bool VerifyModule(
     const wchar_t* module_name,
     ClientIncidentReport_EnvironmentData_Process_ModuleState* module_state,
     int* num_bytes_different) {
   using ModuleState = ClientIncidentReport_EnvironmentData_Process_ModuleState;
   *num_bytes_different = 0;
   module_state->set_name(base::WideToUTF8(module_name));
   module_state->set_modified_state(ModuleState::MODULE_STATE_UNKNOWN);

   // Get module handle, load a copy from disk as data and create PEImages.
   HMODULE module_handle = NULL;
   if (!GetModuleHandleEx(0, module_name, &module_handle))
     return false;
   base::ScopedNativeLibrary native_library(module_handle);

   WCHAR module_path[MAX_PATH] = {};
   DWORD length =
       GetModuleFileName(module_handle, module_path, base::size(module_path));
   if (!length || length == base::size(module_path))
     return false;

   base::MemoryMappedFile mapped_module;
   if (!mapped_module.Initialize(base::FilePath(module_path)))
     return false;
   ModuleVerificationState state(
       reinterpret_cast<HMODULE>(const_cast<uint8_t*>(mapped_module.data())));

   base::win::PEImage mem_peimage(module_handle);
   if (!mem_peimage.VerifyMagic() || !state.disk_peimage.VerifyMagic())
     return false;

   // Get the list of exports and sort them by address for efficient lookups.
   mem_peimage.EnumExports(EnumExportsCallback, &state.exports);
   std::sort(state.exports.begin(), state.exports.end());

   // Get the addresses of the code sections then calculate |code_section_delta|
   // and |image_base_delta|.
   if (!GetCodeAddrsAndSize(mem_peimage,
                            state.disk_peimage,
                            &state.mem_code_addr,
                            &state.disk_code_addr,
                            &state.code_size))
     return false;

   state.module_state = module_state;
   state.last_mem_reloc_position = state.mem_code_addr;
   state.last_disk_reloc_position = state.disk_code_addr;
   state.code_section_delta = state.disk_code_addr - state.mem_code_addr;

   uint8_t* preferred_image_base = reinterpret_cast<uint8_t*>(
       state.disk_peimage.GetNTHeaders()->OptionalHeader.ImageBase);
   state.image_base_delta =
       preferred_image_base - reinterpret_cast<uint8_t*>(mem_peimage.module());

   state.last_mem_reloc_position = state.mem_code_addr;
   state.last_disk_reloc_position = state.disk_code_addr;

   // Enumerate relocations and verify the bytes between them.
   bool scan_complete = mem_peimage.EnumRelocs(EnumRelocsCallback, &state);

   if (scan_complete) {
     size_t range_size =
         state.code_size - (state.last_mem_reloc_position - state.mem_code_addr);
     // Inspect the last chunk spanning from the furthest relocation to the end
     // of the code section.
     state.bytes_different += ExamineByteRangeDiff(
         state.last_disk_reloc_position,
         state.last_mem_reloc_position,
         range_size,
         &state);
   }
   *num_bytes_different = state.bytes_different;

   // Report STATE_MODIFIED if any difference was found, regardless of whether or
   // not the entire module was scanned. Report STATE_UNMODIFIED only if the
   // entire module was scanned and understood.
   if (state.bytes_different)
     module_state->set_modified_state(ModuleState::MODULE_STATE_MODIFIED);
   else if (!state.unknown_reloc_type && scan_complete)
     module_state->set_modified_state(ModuleState::MODULE_STATE_UNMODIFIED);

   return scan_complete;
 }

 }  // namespace safe_browsing
	// Copyright 2014 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 "chrome/browser/safe_browsing/incident_reporting/module_integrity_verifier_win.h"

	#include <stddef.h>

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

	#include "base/files/file_path.h"
	#include "base/files/memory_mapped_file.h"
	#include "base/metrics/histogram_functions.h"
	#include "base/scoped_native_library.h"
	#include "base/stl_util.h"
	#include "base/strings/utf_string_conversions.h"
	#include "base/win/pe_image.h"
	#include "components/safe_browsing/proto/csd.pb.h"

	namespace safe_browsing {

	namespace {

	// The maximum amount of bytes that can be reported as modified by VerifyModule.
	const int kMaxModuleModificationBytes = 256;

	struct Export {
	Export(void* addr, const std::string& name);
	~Export();

	bool operator<(const Export& other) const {
	return addr < other.addr;
	}

	void* addr;
	std::string name;
	};

	Export::Export(void* addr, const std::string& name) : addr(addr), name(name) {
	}

	Export::~Export() {
	}

	struct ModuleVerificationState {
	explicit ModuleVerificationState(HMODULE hModule);
	~ModuleVerificationState();

	base::win::PEImageAsData disk_peimage;

	// The module's preferred base address minus the base address it actually
	// loaded at.
	intptr_t image_base_delta;

	// The location of the disk_peimage module's code section minus that of the
	// mem_peimage module's code section.
	intptr_t code_section_delta;

	// Set true if the relocation table contains a reloc of type that we don't
	// currently handle.
	bool unknown_reloc_type;

	// The start of the code section of the in-memory binary.
	uint8_t* mem_code_addr;

	// The start of the code section of the on-disk binary.
	uint8_t* disk_code_addr;

	// The size of the binary's code section.
	uint32_t code_size;

	// The exports of the DLL, sorted by address in ascending order.
	std::vector<Export> exports;

	// The location in the in-memory binary of the latest reloc encountered by
	// \|EnumRelocsCallback\|.
	uint8_t* last_mem_reloc_position;

	// The location in the on-disk binary of the latest reloc encountered by
	// \|EnumRelocsCallback\|.
	uint8_t* last_disk_reloc_position;

	// The number of bytes with a different value on disk and in memory, as
	// computed by \|VerifyModule\|.
	int bytes_different;

	// The module state protobuf object that \|VerifyModule\| will populate.
	ClientIncidentReport_EnvironmentData_Process_ModuleState* module_state;

	private:
	DISALLOW_COPY_AND_ASSIGN(ModuleVerificationState);
	};

	ModuleVerificationState::ModuleVerificationState(HMODULE hModule)
	: disk_peimage(hModule),
	image_base_delta(0),
	code_section_delta(0),
	unknown_reloc_type(false),
	mem_code_addr(nullptr),
	disk_code_addr(nullptr),
	code_size(0),
	last_mem_reloc_position(nullptr),
	last_disk_reloc_position(nullptr),
	bytes_different(0),
	module_state(nullptr) {
	}

	ModuleVerificationState::~ModuleVerificationState() {
	}

	// Find which export a modification at address \|mem_address\| is in. Looks for
	// the largest export address still smaller than \|mem_address\|. \|start\| and
	// \|end\| must come from a sorted collection.
	std::vector<Export>::const_iterator FindModifiedExport(
	uint8_t* mem_address,
	std::vector<Export>::const_iterator start,
	std::vector<Export>::const_iterator end) {
	// We get the largest export address still smaller than \|addr\|. It is
	// possible that \|addr\| belongs to some nonexported function located
	// between this export and the following one.
	Export addr(reinterpret_cast<void*>(mem_address), std::string());
	return std::upper_bound(start, end, addr);
	}

	// Checks each byte in a subsection of the module's code section against the
	// corresponding byte on disk, returning the number of bytes differing between
	// the two. \|state.exports\| must be sorted.
	int ExamineByteRangeDiff(uint8_t* disk_start,
	uint8_t* mem_start,
	ptrdiff_t range_size,
	ModuleVerificationState* state) {
	int bytes_different = 0;
	std::vector<Export>::const_iterator export_it = state->exports.begin();

	for (uint8_t* end = mem_start + range_size; mem_start < end;
	++mem_start, ++disk_start) {
	if (disk_start == mem_start)
	continue;

	auto* modification = state->module_state->add_modification();
	// Store the address at which the modification starts on disk, relative to
	// the beginning of the image.
	modification->set_file_offset(
	disk_start - reinterpret_cast<uint8_t*>(state->disk_peimage.module()));

	// Find the export containing this modification.
	std::vector<Export>::const_iterator modified_export_it =
	FindModifiedExport(mem_start, export_it, state->exports.end());
	// No later byte can belong to an earlier export.
	export_it = modified_export_it;
	if (modified_export_it != state->exports.begin())
	modification->set_export_name((modified_export_it - 1)->name);

	const uint8_t* range_start = mem_start;
	while (mem_start < end && disk_start != mem_start) {
	++disk_start;
	++mem_start;
	}
	int bytes_in_modification = mem_start - range_start;
	bytes_different += bytes_in_modification;
	modification->set_byte_count(bytes_in_modification);
	modification->set_modified_bytes(
	range_start,
	std::min(bytes_in_modification, kMaxModuleModificationBytes));
	}
	return bytes_different;
	}

	bool AddrIsInCodeSection(void* address,
	uint8_t* code_addr,
	uint32_t code_size) {
	return (code_addr <= address && address < code_addr + code_size);
	}

	bool EnumRelocsCallback(const base::win::PEImage& mem_peimage,
	WORD type,
	void* address,
	void* cookie) {
	ModuleVerificationState* state =
	reinterpret_cast<ModuleVerificationState*>(cookie);

	// If not in the code section return true to continue to the next reloc.
	if (!AddrIsInCodeSection(address, state->mem_code_addr, state->code_size))
	return true;

	switch (type) {
	case IMAGE_REL_BASED_ABSOLUTE: // 0
	break;
	case IMAGE_REL_BASED_HIGHLOW: // 3
	{
	// The range to inspect is from the last reloc to the current one at
	// \|ptr\|
	uint8_t* ptr = reinterpret_cast<uint8_t*>(address);

	// If the last relocation was not before this one in the binary,
	// there's an issue in the reloc section. We can't really recover from
	// that so flag state as such so the error can be logged.
	if (ptr < state->last_mem_reloc_position)
	return false;

	// Check which bytes of the relocation are not accounted for by the
	// rebase. If the beginning of the relocation is modified by something
	// other than the rebase, extend the verification range to include those
	// bytes since they are considered part of a modification.
	uint32_t relocated = reinterpret_cast<uint32_t>(ptr);
	uint32_t original = relocated + state->image_base_delta;
	uint8_t* original_reloc_bytes = reinterpret_cast<uint8_t*>(&original);
	uint8_t* reloc_disk_position = ptr + state->code_section_delta;
	size_t unaccounted_reloc_bytes = 0;
	while (unaccounted_reloc_bytes < sizeof(uint32_t) &&
	original_reloc_bytes[unaccounted_reloc_bytes] !=
	reloc_disk_position[unaccounted_reloc_bytes]) {
	++unaccounted_reloc_bytes;
	}

	// If the entire reloc was modified, return true to let the next
	// EnumReloc track it as part of a larger modification.
	if (unaccounted_reloc_bytes == sizeof(uint32_t))
	return true;

	ptrdiff_t range_size = ptr +
	unaccounted_reloc_bytes -
	state->last_mem_reloc_position;

	state->bytes_different += ExamineByteRangeDiff(
	state->last_disk_reloc_position,
	state->last_mem_reloc_position,
	range_size,
	state);

	// Starting after the verified range, check if the relocation ends with
	// modified bytes. If it does, include them in the following range to be
	// verified as they're considered modified. Otherwise, the following
	// range will start right after the current reloc.
	size_t unmodified_reloc_byte_count = unaccounted_reloc_bytes;
	while (unmodified_reloc_byte_count < sizeof(uint32_t) &&
	original_reloc_bytes[unmodified_reloc_byte_count] ==
	reloc_disk_position[unmodified_reloc_byte_count]) {
	++unmodified_reloc_byte_count;
	}
	state->last_disk_reloc_position +=
	range_size + unmodified_reloc_byte_count;
	state->last_mem_reloc_position +=
	range_size + unmodified_reloc_byte_count;
	}
	break;
	case IMAGE_REL_BASED_DIR64: // 10
	break;
	default:
	// TODO(robertshield): Find a reliable description of the behaviour of the
	// remaining types of relocation and handle them.
	base::UmaHistogramSparse("SafeBrowsing.ModuleBaseRelocation", type);
	state->unknown_reloc_type = true;
	break;
	}
	return true;
	}

	bool EnumExportsCallback(const base::win::PEImage& mem_peimage,
	DWORD ordinal,
	DWORD hint,
	LPCSTR name,
	PVOID function_addr,
	LPCSTR forward,
	PVOID cookie) {
	std::vector<Export>* exports = reinterpret_cast<std::vector<Export>*>(cookie);
	if (name)
	exports->push_back(Export(function_addr, std::string(name)));
	return true;
	}

	} // namespace

	bool GetCodeAddrsAndSize(const base::win::PEImage& mem_peimage,
	const base::win::PEImageAsData& disk_peimage,
	uint8_t** mem_code_addr,
	uint8_t** disk_code_addr,
	uint32_t* code_size) {
	DWORD base_of_code = mem_peimage.GetNTHeaders()->OptionalHeader.BaseOfCode;

	// Get the address and size of the code section in the loaded module image.
	PIMAGE_SECTION_HEADER mem_code_header =
	mem_peimage.GetImageSectionFromAddr(mem_peimage.RVAToAddr(base_of_code));
	if (mem_code_header == NULL)
	return false;
	mem_code_addr = reinterpret_cast<uint8_t>(
	mem_peimage.RVAToAddr(mem_code_header->VirtualAddress));
	// If the section is padded with zeros when mapped then \|VirtualSize\| can be
	// larger. Alternatively, \|SizeOfRawData\| can be rounded up to align
	// according to OptionalHeader.FileAlignment.
	*code_size = std::min(mem_code_header->Misc.VirtualSize,
	mem_code_header->SizeOfRawData);

	// Get the address of the code section in the module mapped as data from disk.
	DWORD disk_code_offset = 0;
	if (!mem_peimage.ImageAddrToOnDiskOffset(
	reinterpret_cast<void>(mem_code_addr), &disk_code_offset))
	return false;
	*disk_code_addr =
	reinterpret_cast<uint8_t*>(disk_peimage.module()) + disk_code_offset;
	return true;
	}

	bool VerifyModule(
	const wchar_t* module_name,
	ClientIncidentReport_EnvironmentData_Process_ModuleState* module_state,
	int* num_bytes_different) {
	using ModuleState = ClientIncidentReport_EnvironmentData_Process_ModuleState;
	*num_bytes_different = 0;
	module_state->set_name(base::WideToUTF8(module_name));
	module_state->set_modified_state(ModuleState::MODULE_STATE_UNKNOWN);

	// Get module handle, load a copy from disk as data and create PEImages.
	HMODULE module_handle = NULL;
	if (!GetModuleHandleEx(0, module_name, &module_handle))
	return false;
	base::ScopedNativeLibrary native_library(module_handle);

	WCHAR module_path[MAX_PATH] = {};
	DWORD length =
	GetModuleFileName(module_handle, module_path, base::size(module_path));
	if (!length \|\| length == base::size(module_path))
	return false;

	base::MemoryMappedFile mapped_module;
	if (!mapped_module.Initialize(base::FilePath(module_path)))
	return false;
	ModuleVerificationState state(
	reinterpret_cast<HMODULE>(const_cast<uint8_t*>(mapped_module.data())));

	base::win::PEImage mem_peimage(module_handle);
	if (!mem_peimage.VerifyMagic() \|\| !state.disk_peimage.VerifyMagic())
	return false;

	// Get the list of exports and sort them by address for efficient lookups.
	mem_peimage.EnumExports(EnumExportsCallback, &state.exports);
	std::sort(state.exports.begin(), state.exports.end());

	// Get the addresses of the code sections then calculate \|code_section_delta\|
	// and \|image_base_delta\|.
	if (!GetCodeAddrsAndSize(mem_peimage,
	state.disk_peimage,
	&state.mem_code_addr,
	&state.disk_code_addr,
	&state.code_size))
	return false;

	state.module_state = module_state;
	state.last_mem_reloc_position = state.mem_code_addr;
	state.last_disk_reloc_position = state.disk_code_addr;
	state.code_section_delta = state.disk_code_addr - state.mem_code_addr;

	uint8_t* preferred_image_base = reinterpret_cast<uint8_t*>(
	state.disk_peimage.GetNTHeaders()->OptionalHeader.ImageBase);
	state.image_base_delta =
	preferred_image_base - reinterpret_cast<uint8_t*>(mem_peimage.module());

	state.last_mem_reloc_position = state.mem_code_addr;
	state.last_disk_reloc_position = state.disk_code_addr;

	// Enumerate relocations and verify the bytes between them.
	bool scan_complete = mem_peimage.EnumRelocs(EnumRelocsCallback, &state);

	if (scan_complete) {
	size_t range_size =
	state.code_size - (state.last_mem_reloc_position - state.mem_code_addr);
	// Inspect the last chunk spanning from the furthest relocation to the end
	// of the code section.
	state.bytes_different += ExamineByteRangeDiff(
	state.last_disk_reloc_position,
	state.last_mem_reloc_position,
	range_size,
	&state);
	}
	*num_bytes_different = state.bytes_different;

	// Report STATE_MODIFIED if any difference was found, regardless of whether or
	// not the entire module was scanned. Report STATE_UNMODIFIED only if the
	// entire module was scanned and understood.
	if (state.bytes_different)
	module_state->set_modified_state(ModuleState::MODULE_STATE_MODIFIED);
	else if (!state.unknown_reloc_type && scan_complete)
	module_state->set_modified_state(ModuleState::MODULE_STATE_UNMODIFIED);

	return scan_complete;
	}

	} // namespace safe_browsing