chrome/app/image_pre_reader_win.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 "chrome/app/image_pre_reader_win.h"

 #include <windows.h>
 #include <algorithm>
 #include <limits>
 #include <vector>

 #include "base/logging.h"
 #include "base/memory/scoped_ptr.h"
 #include "base/threading/thread_restrictions.h"
 #include "base/win/pe_image.h"
 #include "base/win/scoped_handle.h"
 #include "base/win/windows_version.h"

 namespace {

 // The minimum buffer size to allocate when reading the PE file headers.
 //
 // The PE file headers usually fit into a single 1KB page, and a PE file must
 // at least contain the initial page with the headers. That said, as long as
 // we expect at least sizeof(IMAGE_DOS_HEADER) bytes, we're ok.
 const size_t kMinHeaderBufferSize = 0x400;

 // A handy symbolic constant.
 const size_t kOneHundredPercent = 100;

 void StaticAssertions() {
   COMPILE_ASSERT(kMinHeaderBufferSize >= sizeof(IMAGE_DOS_HEADER),
                  min_header_buffer_size_at_least_as_big_as_the_dos_header);
 }

 // This struct provides a deallocation functor for use with scoped_ptr<T>
 // allocated with ::VirtualAlloc().
 struct VirtualFreeDeleter {
   void operator() (void* ptr) {
     ::VirtualFree(ptr, 0, MEM_RELEASE);
   }
 };

 // A wrapper for the Win32 ::SetFilePointer() function with some error checking.
 bool SetFilePointer(HANDLE file_handle, size_t position) {
   return position <= static_cast<size_t>(std::numeric_limits<LONG>::max()) &&
       ::SetFilePointer(file_handle,
                        static_cast<LONG>(position),
                        NULL,
                        FILE_BEGIN) != INVALID_SET_FILE_POINTER;
 }

 // A helper function to read the next |bytes_to_read| bytes from the file
 // given by |file_handle| into |buffer|.
 bool ReadNextBytes(HANDLE file_handle, void* buffer, size_t bytes_to_read) {
   DCHECK(file_handle != INVALID_HANDLE_VALUE);
   DCHECK(buffer != NULL);
   DCHECK(bytes_to_read > 0);

   DWORD bytes_read = 0;
   return bytes_to_read <= std::numeric_limits<DWORD>::max() &&
       ::ReadFile(file_handle,
                  buffer,
                  static_cast<DWORD>(bytes_to_read),
                  &bytes_read,
                  NULL) &&
       bytes_read == bytes_to_read;
 }

 // A helper function to extend the |current_buffer| of bytes such that it
 // contains |desired_length| bytes read from the file given by |file_handle|.
 //
 // It is assumed that |file_handle| has been used to sequentially populate
 // |current_buffer| thus far and is already positioned at the appropriate
 // read location.
 bool ReadMissingBytes(HANDLE file_handle,
                       std::vector<uint8>* current_buffer,
                       size_t desired_length) {
   DCHECK(file_handle != INVALID_HANDLE_VALUE);
   DCHECK(current_buffer != NULL);

   size_t current_length = current_buffer->size();
   if (current_length >= desired_length)
     return true;

   size_t bytes_to_read = desired_length - current_length;
   current_buffer->resize(desired_length);
   return ReadNextBytes(file_handle,
                        &(current_buffer->at(current_length)),
                        bytes_to_read);
 }

 // Return a |percentage| of the number of initialized bytes in the given
 // |section|.
 //
 // This returns a percentage of the lesser of the size of the raw data in
 // the section and the virtual size of the section.
 //
 // Note that sections can have their tails implicitly initialized to zero
 // (i.e., their virtual size is larger than the raw size) and that raw data
 // is padded to the PE page size if the entire section is initialized (i.e.,
 // their raw data size will be larger than the virtual size).
 //
 // Any data after the initialized portion of the section will be soft-faulted
 // in (very quickly) as needed, so we don't need to include it in the returned
 // length.
 size_t GetPercentageOfSectionLength(const IMAGE_SECTION_HEADER* section,
                                     size_t percentage) {
   DCHECK(section != NULL);
   DCHECK_GT(percentage, 0u);
   DCHECK_LE(percentage, kOneHundredPercent);

   size_t initialized_length = std::min(section->SizeOfRawData,
                                        section->Misc.VirtualSize);

   if (initialized_length == 0)
     return 0;

   size_t length = (initialized_length * percentage) / kOneHundredPercent;

   return std::max<size_t>(length, 1);
 }

 // Helper function to read through a |percentage| of the given |section|
 // of the file denoted by |file_handle|. The |temp_buffer| is (re)used as
 // a transient storage area as the section is read in chunks of
 // |temp_buffer_size| bytes.
 bool ReadThroughSection(HANDLE file_handle,
                         const IMAGE_SECTION_HEADER* section,
                         size_t percentage,
                         void* temp_buffer,
                         size_t temp_buffer_size) {
   DCHECK(file_handle != INVALID_HANDLE_VALUE);
   DCHECK(section != NULL);
   DCHECK_LE(percentage, kOneHundredPercent);
   DCHECK(temp_buffer != NULL);
   DCHECK(temp_buffer_size > 0);

   size_t bytes_to_read = GetPercentageOfSectionLength(section, percentage);
   if (bytes_to_read == 0)
     return true;

   if (!SetFilePointer(file_handle, section->PointerToRawData))
     return false;

   // Read all chunks except the last one.
   while (bytes_to_read > temp_buffer_size) {
     if (!ReadNextBytes(file_handle, temp_buffer, temp_buffer_size))
       return false;
     bytes_to_read -= temp_buffer_size;
   }

   // Read the last (possibly partial) chunk and return.
   DCHECK(bytes_to_read > 0);
   DCHECK(bytes_to_read <= temp_buffer_size);
   return ReadNextBytes(file_handle, temp_buffer, bytes_to_read);
 }

 // A helper function to touch all pages in the range
 // [base_addr, base_addr + length).
 void TouchPagesInRange(void* base_addr, size_t length) {
   DCHECK(base_addr != NULL);
   DCHECK(length > 0);

   // Get the system info so we know the page size. Also, make sure we use a
   // non-zero value for the page size; GetSystemInfo() is hookable/patchable,
   // and you never know what shenanigans someone could get up to.
   SYSTEM_INFO system_info = {};
   GetSystemInfo(&system_info);
   if (system_info.dwPageSize == 0)
     system_info.dwPageSize = 4096;

   // We don't want to read outside the byte range (which could trigger an
   // access violation), so let's figure out the exact locations of the first
   // and final bytes we want to read.
   volatile uint8* touch_ptr = reinterpret_cast<uint8*>(base_addr);
   volatile uint8* final_touch_ptr = touch_ptr + length - 1;

   // Read the memory in the range [touch_ptr, final_touch_ptr] with a stride
   // of the system page size, to ensure that it's been paged in.
   uint8 dummy;
   while (touch_ptr < final_touch_ptr) {
     dummy = *touch_ptr;
     touch_ptr += system_info.dwPageSize;
   }
   dummy = *final_touch_ptr;
 }

 }  // namespace

 bool ImagePreReader::PartialPreReadImageOnDisk(const wchar_t* file_path,
                                                size_t percentage,
                                                size_t max_chunk_size) {
   // TODO(rogerm): change this to have the number of bytes pre-read per
   //     section be driven by a static table within the PE file (defaulting to
   //     full read if it's not there?) that's initialized by the optimization
   //     toolchain.
   DCHECK(file_path != NULL);

   if (percentage == 0)
     return true;

   if (percentage > kOneHundredPercent)
     percentage = kOneHundredPercent;

   // Validate/setup max_chunk_size, imposing a 1MB minimum on the chunk size.
   const size_t kMinChunkSize = 1024 * 1024;
   max_chunk_size = std::max(max_chunk_size, kMinChunkSize);

   // Open the file.
   base::win::ScopedHandle file(
       CreateFile(file_path,
                  GENERIC_READ,
                  FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE,
                  NULL,
                  OPEN_EXISTING,
                  FILE_FLAG_SEQUENTIAL_SCAN,
                  NULL));

   if (!file.IsValid())
     return false;

   // Allocate a resizable buffer for the headers. We initially reserve as much
   // space as we typically see as the header size for chrome.dll and other
   // PE images.
   std::vector<uint8> headers;
   headers.reserve(kMinHeaderBufferSize);

   // Read, hopefully, all of the headers.
   if (!ReadMissingBytes(file.Get(), &headers, kMinHeaderBufferSize))
     return false;

   // The DOS header starts at offset 0 and allows us to get the offset of the
   // NT headers. Let's ensure we've read enough to capture the NT headers.
   size_t nt_headers_start =
       reinterpret_cast<IMAGE_DOS_HEADER*>(&headers[0])->e_lfanew;
   size_t nt_headers_end = nt_headers_start + sizeof(IMAGE_NT_HEADERS);
   if (!ReadMissingBytes(file.Get(), &headers, nt_headers_end))
     return false;

   // Now that we've got the NT headers we can get the total header size,
   // including all of the section headers. Let's ensure we've read enough
   // to capture all of the header data.
   size_t size_of_headers = reinterpret_cast<IMAGE_NT_HEADERS*>(
       &headers[nt_headers_start])->OptionalHeader.SizeOfHeaders;
   if (!ReadMissingBytes(file.Get(), &headers, size_of_headers))
     return false;

   // Now we have all of the headers. This is enough to let us use the PEImage
   // wrapper to query the structure of the image.
   base::win::PEImage pe_image(reinterpret_cast<HMODULE>(&headers[0]));
   CHECK(pe_image.VerifyMagic());

   // Allocate a buffer to hold the pre-read bytes.
   scoped_ptr<uint8, VirtualFreeDeleter> buffer(
       static_cast<uint8*>(
           ::VirtualAlloc(NULL, max_chunk_size, MEM_COMMIT, PAGE_READWRITE)));
   if (buffer.get() == NULL)
     return false;

   // Iterate over each section, reading in a percentage of each.
   const IMAGE_SECTION_HEADER* section = NULL;
   for (UINT i = 0; (section = pe_image.GetSectionHeader(i)) != NULL; ++i) {
     CHECK_LE(reinterpret_cast<const uint8*>(section + 1),
              &headers[0] + headers.size());
     if (!ReadThroughSection(file.Get(), section, percentage, buffer.get(),
                             max_chunk_size)) {
       return false;
     }
   }

   // We're done.
   return true;
 }

 bool ImagePreReader::PartialPreReadImageInMemory(const wchar_t* file_path,
                                                  size_t percentage) {
   // TODO(rogerm): change this to have the number of bytes pre-read per
   //     section be driven by a static table within the PE file (defaulting to
   //     full read if it's not there?) that's initialized by the optimization
   //     toolchain.
   DCHECK(file_path != NULL);

   if (percentage == 0)
     return true;

   if (percentage > kOneHundredPercent)
     percentage = kOneHundredPercent;

   HMODULE dll_module = ::LoadLibraryExW(
       file_path,
       NULL,
       LOAD_WITH_ALTERED_SEARCH_PATH | DONT_RESOLVE_DLL_REFERENCES);

   if (!dll_module)
     return false;

   base::win::PEImage pe_image(dll_module);
   CHECK(pe_image.VerifyMagic());

   // Iterate over each section, stepping through a percentage of each to page
   // it in off the disk.
   const IMAGE_SECTION_HEADER* section = NULL;
   for (UINT i = 0; (section = pe_image.GetSectionHeader(i)) != NULL; ++i) {
     // Get the extent we want to touch.
     size_t length = GetPercentageOfSectionLength(section, percentage);
     if (length == 0)
       continue;
     uint8* start =
         static_cast<uint8*>(pe_image.RVAToAddr(section->VirtualAddress));

     // Verify that the extent we're going to touch falls inside the section
     // we expect it to (and by implication, inside the pe_image).
     CHECK_EQ(section,
              pe_image.GetImageSectionFromAddr(start));
     CHECK_EQ(section,
              pe_image.GetImageSectionFromAddr(start + length - 1));

     // Page in the section range.
     TouchPagesInRange(start, length);
   }

   FreeLibrary(dll_module);

   return true;
 }

 bool ImagePreReader::PreReadImage(const wchar_t* file_path,
                                   size_t size_to_read,
                                   size_t step_size) {
   base::ThreadRestrictions::AssertIOAllowed();
   if (base::win::GetVersion() > base::win::VERSION_XP) {
     // Vista+ branch. On these OSes, the forced reads through the DLL actually
     // slows warm starts. The solution is to sequentially read file contents
     // with an optional cap on total amount to read.
     base::win::ScopedHandle file(
         CreateFile(file_path,
                    GENERIC_READ,
                    FILE_SHARE_READ | FILE_SHARE_WRITE | FILE_SHARE_DELETE,
                    NULL,
                    OPEN_EXISTING,
                    FILE_FLAG_SEQUENTIAL_SCAN,
                    NULL));

     if (!file.IsValid())
       return false;

     // Default to 1MB sequential reads.
     const DWORD actual_step_size = std::max(static_cast<DWORD>(step_size),
                                             static_cast<DWORD>(1024*1024));
     LPVOID buffer = ::VirtualAlloc(NULL,
                                    actual_step_size,
                                    MEM_COMMIT,
                                    PAGE_READWRITE);

     if (buffer == NULL)
       return false;

     DWORD len;
     size_t total_read = 0;
     while (::ReadFile(file.Get(), buffer, actual_step_size, &len, NULL) &&
            len > 0 &&
            (size_to_read ? total_read < size_to_read : true)) {
       total_read += static_cast<size_t>(len);
     }
     ::VirtualFree(buffer, 0, MEM_RELEASE);
   } else {
     // WinXP branch. Here, reading the DLL from disk doesn't do
     // what we want so instead we pull the pages into memory by loading
     // the DLL and touching pages at a stride. We use the system's page
     // size as the stride, ignoring the passed in step_size, to make sure
     // each page in the range is touched.
     HMODULE dll_module = ::LoadLibraryExW(
         file_path,
         NULL,
         LOAD_WITH_ALTERED_SEARCH_PATH | DONT_RESOLVE_DLL_REFERENCES);

     if (!dll_module)
       return false;

     base::win::PEImage pe_image(dll_module);
     CHECK(pe_image.VerifyMagic());

     // We don't want to read past the end of the module (which could trigger
     // an access violation), so make sure to check the image size.
     PIMAGE_NT_HEADERS nt_headers = pe_image.GetNTHeaders();
     size_t dll_module_length = std::min(
         size_to_read ? size_to_read : ~0,
         static_cast<size_t>(nt_headers->OptionalHeader.SizeOfImage));

     // Page in then release the module.
     TouchPagesInRange(dll_module, dll_module_length);
     FreeLibrary(dll_module);
   }

   return true;
 }

 bool ImagePreReader::PartialPreReadImage(const wchar_t* file_path,
                                          size_t percentage,
                                          size_t max_chunk_size) {
   base::ThreadRestrictions::AssertIOAllowed();

   if (percentage >= kOneHundredPercent) {
     // If we're reading the whole image, we don't need to parse headers and
     // navigate sections, the basic PreReadImage() can be used to just step
     // blindly through the entire file / address-space.
     return PreReadImage(file_path, 0, max_chunk_size);
   }

   if (base::win::GetVersion() > base::win::VERSION_XP) {
     // Vista+ branch. On these OSes, we warm up the Image by reading its
     // file off the disk.
     return PartialPreReadImageOnDisk(file_path, percentage, max_chunk_size);
   }

   // WinXP branch. For XP, reading the image from disk doesn't do what we want
   // so instead we pull the pages into memory by loading the DLL and touching
   // initialized pages at a stride.
   return PartialPreReadImageInMemory(file_path, percentage);
 }
	// 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 "chrome/app/image_pre_reader_win.h"

	#include <windows.h>
	#include <algorithm>
	#include <limits>
	#include <vector>

	#include "base/logging.h"
	#include "base/memory/scoped_ptr.h"
	#include "base/threading/thread_restrictions.h"
	#include "base/win/pe_image.h"
	#include "base/win/scoped_handle.h"
	#include "base/win/windows_version.h"

	namespace {

	// The minimum buffer size to allocate when reading the PE file headers.
	//
	// The PE file headers usually fit into a single 1KB page, and a PE file must
	// at least contain the initial page with the headers. That said, as long as
	// we expect at least sizeof(IMAGE_DOS_HEADER) bytes, we're ok.
	const size_t kMinHeaderBufferSize = 0x400;

	// A handy symbolic constant.
	const size_t kOneHundredPercent = 100;

	void StaticAssertions() {
	COMPILE_ASSERT(kMinHeaderBufferSize >= sizeof(IMAGE_DOS_HEADER),
	min_header_buffer_size_at_least_as_big_as_the_dos_header);
	}

	// This struct provides a deallocation functor for use with scoped_ptr<T>
	// allocated with ::VirtualAlloc().
	struct VirtualFreeDeleter {
	void operator() (void* ptr) {
	::VirtualFree(ptr, 0, MEM_RELEASE);
	}
	};

	// A wrapper for the Win32 ::SetFilePointer() function with some error checking.
	bool SetFilePointer(HANDLE file_handle, size_t position) {
	return position <= static_cast<size_t>(std::numeric_limits<LONG>::max()) &&
	::SetFilePointer(file_handle,
	static_cast<LONG>(position),
	NULL,
	FILE_BEGIN) != INVALID_SET_FILE_POINTER;
	}

	// A helper function to read the next \|bytes_to_read\| bytes from the file
	// given by \|file_handle\| into \|buffer\|.
	bool ReadNextBytes(HANDLE file_handle, void* buffer, size_t bytes_to_read) {
	DCHECK(file_handle != INVALID_HANDLE_VALUE);
	DCHECK(buffer != NULL);
	DCHECK(bytes_to_read > 0);

	DWORD bytes_read = 0;
	return bytes_to_read <= std::numeric_limits<DWORD>::max() &&
	::ReadFile(file_handle,
	buffer,
	static_cast<DWORD>(bytes_to_read),
	&bytes_read,
	NULL) &&
	bytes_read == bytes_to_read;
	}

	// A helper function to extend the \|current_buffer\| of bytes such that it
	// contains \|desired_length\| bytes read from the file given by \|file_handle\|.
	//
	// It is assumed that \|file_handle\| has been used to sequentially populate
	// \|current_buffer\| thus far and is already positioned at the appropriate
	// read location.
	bool ReadMissingBytes(HANDLE file_handle,
	std::vector<uint8>* current_buffer,
	size_t desired_length) {
	DCHECK(file_handle != INVALID_HANDLE_VALUE);
	DCHECK(current_buffer != NULL);

	size_t current_length = current_buffer->size();
	if (current_length >= desired_length)
	return true;

	size_t bytes_to_read = desired_length - current_length;
	current_buffer->resize(desired_length);
	return ReadNextBytes(file_handle,
	&(current_buffer->at(current_length)),
	bytes_to_read);
	}

	// Return a \|percentage\| of the number of initialized bytes in the given
	// \|section\|.
	//
	// This returns a percentage of the lesser of the size of the raw data in
	// the section and the virtual size of the section.
	//
	// Note that sections can have their tails implicitly initialized to zero
	// (i.e., their virtual size is larger than the raw size) and that raw data
	// is padded to the PE page size if the entire section is initialized (i.e.,
	// their raw data size will be larger than the virtual size).
	//
	// Any data after the initialized portion of the section will be soft-faulted
	// in (very quickly) as needed, so we don't need to include it in the returned
	// length.
	size_t GetPercentageOfSectionLength(const IMAGE_SECTION_HEADER* section,
	size_t percentage) {
	DCHECK(section != NULL);
	DCHECK_GT(percentage, 0u);
	DCHECK_LE(percentage, kOneHundredPercent);

	size_t initialized_length = std::min(section->SizeOfRawData,
	section->Misc.VirtualSize);

	if (initialized_length == 0)
	return 0;

	size_t length = (initialized_length * percentage) / kOneHundredPercent;

	return std::max<size_t>(length, 1);
	}

	// Helper function to read through a \|percentage\| of the given \|section\|
	// of the file denoted by \|file_handle\|. The \|temp_buffer\| is (re)used as
	// a transient storage area as the section is read in chunks of
	// \|temp_buffer_size\| bytes.
	bool ReadThroughSection(HANDLE file_handle,
	const IMAGE_SECTION_HEADER* section,
	size_t percentage,
	void* temp_buffer,
	size_t temp_buffer_size) {
	DCHECK(file_handle != INVALID_HANDLE_VALUE);
	DCHECK(section != NULL);
	DCHECK_LE(percentage, kOneHundredPercent);
	DCHECK(temp_buffer != NULL);
	DCHECK(temp_buffer_size > 0);

	size_t bytes_to_read = GetPercentageOfSectionLength(section, percentage);
	if (bytes_to_read == 0)
	return true;

	if (!SetFilePointer(file_handle, section->PointerToRawData))
	return false;

	// Read all chunks except the last one.
	while (bytes_to_read > temp_buffer_size) {
	if (!ReadNextBytes(file_handle, temp_buffer, temp_buffer_size))
	return false;
	bytes_to_read -= temp_buffer_size;
	}

	// Read the last (possibly partial) chunk and return.
	DCHECK(bytes_to_read > 0);
	DCHECK(bytes_to_read <= temp_buffer_size);
	return ReadNextBytes(file_handle, temp_buffer, bytes_to_read);
	}

	// A helper function to touch all pages in the range
	// [base_addr, base_addr + length).
	void TouchPagesInRange(void* base_addr, size_t length) {
	DCHECK(base_addr != NULL);
	DCHECK(length > 0);

	// Get the system info so we know the page size. Also, make sure we use a
	// non-zero value for the page size; GetSystemInfo() is hookable/patchable,
	// and you never know what shenanigans someone could get up to.
	SYSTEM_INFO system_info = {};
	GetSystemInfo(&system_info);
	if (system_info.dwPageSize == 0)
	system_info.dwPageSize = 4096;

	// We don't want to read outside the byte range (which could trigger an
	// access violation), so let's figure out the exact locations of the first
	// and final bytes we want to read.
	volatile uint8* touch_ptr = reinterpret_cast<uint8*>(base_addr);
	volatile uint8* final_touch_ptr = touch_ptr + length - 1;

	// Read the memory in the range [touch_ptr, final_touch_ptr] with a stride
	// of the system page size, to ensure that it's been paged in.
	uint8 dummy;
	while (touch_ptr < final_touch_ptr) {
	dummy = *touch_ptr;
	touch_ptr += system_info.dwPageSize;
	}
	dummy = *final_touch_ptr;
	}

	} // namespace

	bool ImagePreReader::PartialPreReadImageOnDisk(const wchar_t* file_path,
	size_t percentage,
	size_t max_chunk_size) {
	// TODO(rogerm): change this to have the number of bytes pre-read per
	// section be driven by a static table within the PE file (defaulting to
	// full read if it's not there?) that's initialized by the optimization
	// toolchain.
	DCHECK(file_path != NULL);

	if (percentage == 0)
	return true;

	if (percentage > kOneHundredPercent)
	percentage = kOneHundredPercent;

	// Validate/setup max_chunk_size, imposing a 1MB minimum on the chunk size.
	const size_t kMinChunkSize = 1024 * 1024;
	max_chunk_size = std::max(max_chunk_size, kMinChunkSize);

	// Open the file.
	base::win::ScopedHandle file(
	CreateFile(file_path,
	GENERIC_READ,
	FILE_SHARE_READ \| FILE_SHARE_WRITE \| FILE_SHARE_DELETE,
	NULL,
	OPEN_EXISTING,
	FILE_FLAG_SEQUENTIAL_SCAN,
	NULL));

	if (!file.IsValid())
	return false;

	// Allocate a resizable buffer for the headers. We initially reserve as much
	// space as we typically see as the header size for chrome.dll and other
	// PE images.
	std::vector<uint8> headers;
	headers.reserve(kMinHeaderBufferSize);

	// Read, hopefully, all of the headers.
	if (!ReadMissingBytes(file.Get(), &headers, kMinHeaderBufferSize))
	return false;

	// The DOS header starts at offset 0 and allows us to get the offset of the
	// NT headers. Let's ensure we've read enough to capture the NT headers.
	size_t nt_headers_start =
	reinterpret_cast<IMAGE_DOS_HEADER*>(&headers[0])->e_lfanew;
	size_t nt_headers_end = nt_headers_start + sizeof(IMAGE_NT_HEADERS);
	if (!ReadMissingBytes(file.Get(), &headers, nt_headers_end))
	return false;

	// Now that we've got the NT headers we can get the total header size,
	// including all of the section headers. Let's ensure we've read enough
	// to capture all of the header data.
	size_t size_of_headers = reinterpret_cast<IMAGE_NT_HEADERS*>(
	&headers[nt_headers_start])->OptionalHeader.SizeOfHeaders;
	if (!ReadMissingBytes(file.Get(), &headers, size_of_headers))
	return false;

	// Now we have all of the headers. This is enough to let us use the PEImage
	// wrapper to query the structure of the image.
	base::win::PEImage pe_image(reinterpret_cast<HMODULE>(&headers[0]));
	CHECK(pe_image.VerifyMagic());

	// Allocate a buffer to hold the pre-read bytes.
	scoped_ptr<uint8, VirtualFreeDeleter> buffer(
	static_cast<uint8*>(
	::VirtualAlloc(NULL, max_chunk_size, MEM_COMMIT, PAGE_READWRITE)));
	if (buffer.get() == NULL)
	return false;

	// Iterate over each section, reading in a percentage of each.
	const IMAGE_SECTION_HEADER* section = NULL;
	for (UINT i = 0; (section = pe_image.GetSectionHeader(i)) != NULL; ++i) {
	CHECK_LE(reinterpret_cast<const uint8*>(section + 1),
	&headers[0] + headers.size());
	if (!ReadThroughSection(file.Get(), section, percentage, buffer.get(),
	max_chunk_size)) {
	return false;
	}
	}

	// We're done.
	return true;
	}

	bool ImagePreReader::PartialPreReadImageInMemory(const wchar_t* file_path,
	size_t percentage) {
	// TODO(rogerm): change this to have the number of bytes pre-read per
	// section be driven by a static table within the PE file (defaulting to
	// full read if it's not there?) that's initialized by the optimization
	// toolchain.
	DCHECK(file_path != NULL);

	if (percentage == 0)
	return true;

	if (percentage > kOneHundredPercent)
	percentage = kOneHundredPercent;

	HMODULE dll_module = ::LoadLibraryExW(
	file_path,
	NULL,
	LOAD_WITH_ALTERED_SEARCH_PATH \| DONT_RESOLVE_DLL_REFERENCES);

	if (!dll_module)
	return false;

	base::win::PEImage pe_image(dll_module);
	CHECK(pe_image.VerifyMagic());

	// Iterate over each section, stepping through a percentage of each to page
	// it in off the disk.
	const IMAGE_SECTION_HEADER* section = NULL;
	for (UINT i = 0; (section = pe_image.GetSectionHeader(i)) != NULL; ++i) {
	// Get the extent we want to touch.
	size_t length = GetPercentageOfSectionLength(section, percentage);
	if (length == 0)
	continue;
	uint8* start =
	static_cast<uint8*>(pe_image.RVAToAddr(section->VirtualAddress));

	// Verify that the extent we're going to touch falls inside the section
	// we expect it to (and by implication, inside the pe_image).
	CHECK_EQ(section,
	pe_image.GetImageSectionFromAddr(start));
	CHECK_EQ(section,
	pe_image.GetImageSectionFromAddr(start + length - 1));

	// Page in the section range.
	TouchPagesInRange(start, length);
	}

	FreeLibrary(dll_module);

	return true;
	}

	bool ImagePreReader::PreReadImage(const wchar_t* file_path,
	size_t size_to_read,
	size_t step_size) {
	base::ThreadRestrictions::AssertIOAllowed();
	if (base::win::GetVersion() > base::win::VERSION_XP) {
	// Vista+ branch. On these OSes, the forced reads through the DLL actually
	// slows warm starts. The solution is to sequentially read file contents
	// with an optional cap on total amount to read.
	base::win::ScopedHandle file(
	CreateFile(file_path,
	GENERIC_READ,
	FILE_SHARE_READ \| FILE_SHARE_WRITE \| FILE_SHARE_DELETE,
	NULL,
	OPEN_EXISTING,
	FILE_FLAG_SEQUENTIAL_SCAN,
	NULL));

	if (!file.IsValid())
	return false;

	// Default to 1MB sequential reads.
	const DWORD actual_step_size = std::max(static_cast<DWORD>(step_size),
	static_cast<DWORD>(1024*1024));
	LPVOID buffer = ::VirtualAlloc(NULL,
	actual_step_size,
	MEM_COMMIT,
	PAGE_READWRITE);

	if (buffer == NULL)
	return false;

	DWORD len;
	size_t total_read = 0;
	while (::ReadFile(file.Get(), buffer, actual_step_size, &len, NULL) &&
	len > 0 &&
	(size_to_read ? total_read < size_to_read : true)) {
	total_read += static_cast<size_t>(len);
	}
	::VirtualFree(buffer, 0, MEM_RELEASE);
	} else {
	// WinXP branch. Here, reading the DLL from disk doesn't do
	// what we want so instead we pull the pages into memory by loading
	// the DLL and touching pages at a stride. We use the system's page
	// size as the stride, ignoring the passed in step_size, to make sure
	// each page in the range is touched.
	HMODULE dll_module = ::LoadLibraryExW(
	file_path,
	NULL,
	LOAD_WITH_ALTERED_SEARCH_PATH \| DONT_RESOLVE_DLL_REFERENCES);

	if (!dll_module)
	return false;

	base::win::PEImage pe_image(dll_module);
	CHECK(pe_image.VerifyMagic());

	// We don't want to read past the end of the module (which could trigger
	// an access violation), so make sure to check the image size.
	PIMAGE_NT_HEADERS nt_headers = pe_image.GetNTHeaders();
	size_t dll_module_length = std::min(
	size_to_read ? size_to_read : ~0,
	static_cast<size_t>(nt_headers->OptionalHeader.SizeOfImage));

	// Page in then release the module.
	TouchPagesInRange(dll_module, dll_module_length);
	FreeLibrary(dll_module);
	}

	return true;
	}

	bool ImagePreReader::PartialPreReadImage(const wchar_t* file_path,
	size_t percentage,
	size_t max_chunk_size) {
	base::ThreadRestrictions::AssertIOAllowed();

	if (percentage >= kOneHundredPercent) {
	// If we're reading the whole image, we don't need to parse headers and
	// navigate sections, the basic PreReadImage() can be used to just step
	// blindly through the entire file / address-space.
	return PreReadImage(file_path, 0, max_chunk_size);
	}

	if (base::win::GetVersion() > base::win::VERSION_XP) {
	// Vista+ branch. On these OSes, we warm up the Image by reading its
	// file off the disk.
	return PartialPreReadImageOnDisk(file_path, percentage, max_chunk_size);
	}

	// WinXP branch. For XP, reading the image from disk doesn't do what we want
	// so instead we pull the pages into memory by loading the DLL and touching
	// initialized pages at a stride.
	return PartialPreReadImageInMemory(file_path, percentage);
	}