components/zucchini/address_translator.h - chromium/src - Git at Google

 // Copyright 2017 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.

 #ifndef COMPONENTS_ZUCCHINI_ADDRESS_TRANSLATOR_H_
 #define COMPONENTS_ZUCCHINI_ADDRESS_TRANSLATOR_H_

 #include <stdint.h>

 #include <tuple>
 #include <vector>

 #include "base/macros.h"
 #include "components/zucchini/algorithm.h"
 #include "components/zucchini/image_utils.h"

 namespace zucchini {

 // There are several ways to reason about addresses in an image:
 // - Offset: Position relative to start of image.
 // - VA (Virtual Address): Virtual memory address of a loaded image. This is
 //   subject to relocation by the OS.
 // - RVA (Relative Virtual Address): VA relative to some base address. This is
 //   the preferred way to specify pointers in an image.
 //
 // Zucchini is primarily concerned with offsets and RVAs. Executable images like
 // PE and ELF are organized into sections. Each section specifies offset and RVA
 // ranges as:
 //   {Offset start, offset size, RVA start, RVA size}.
 // This constitutes a basic unit to translate between offsets and RVAs. Note:
 // |offset size| < |RVA size| is possible. For example, the .bss section can can
 // have zero-filled statically-allocated data that have no corresponding bytes
 // on image (to save space). This poses a problem for Zucchini, which stores
 // addresses as offsets: now we'd have "dangling RVAs" that don't map to
 // offsets! Some ways to handling this are:
 // 1. Ignore all dangling RVAs. This simplifies the algorithm, but also means
 //    some reference targets would escape detection and processing.
 // 2. Create distinct "fake offsets" to accommodate dangling RVAs. Image data
 //    must not be read on these fake offsets, which are only valid as target
 //    addresses for reference matching.
 // As for |RVA size| < |offset size|, the extra portion just gets ignored.
 //
 // Status: Zucchini implements (2) in a simple way: dangling RVAs are mapped to
 // fake offsets by adding a large value. This value can be chosen as an
 // exclusive upper bound of all offsets (i.e., image size). This allows them to
 // be easily detected and processed as a special-case.
 // TODO(huangs): Investigate option (1), now that the refactored code makes
 // experimentation easier.
 // TODO(huangs): Make AddressTranslator smarter: Allocate unused |offset_t|
 // ranges and create "fake" units to accommodate dangling RVAs. Then
 // AddressTranslator can be simplified.

 // Virtual Address relative to some base address (RVA). There's distinction
 // between "valid RVA" and "existent RVA":
 // - Valid RVA: An RVA that's reasonably small, i.e., below |kRvaBound|.
 // - Existent RVA: An RVA that has semantic meaning in an image, and may
 //   translate to an offset in an image or (if a dangling RVA) a fake offset.
 //   All existent RVAs are valid RVAs.
 using rva_t = uint32_t;
 // Divide by 2 to match |kOffsetBound|.
 constexpr rva_t kRvaBound = static_cast<rva_t>(-1) / 2;
 constexpr rva_t kInvalidRva = static_cast<rva_t>(-2);

 // A utility to translate between offsets and RVAs in an image.
 class AddressTranslator {
  public:
   // A basic unit for address translation, roughly maps to a section, but may
   // be processed (e.g., merged) as an optimization.
   struct Unit {
     offset_t offset_end() const { return offset_begin + offset_size; }
     rva_t rva_end() const { return rva_begin + rva_size; }
     bool IsEmpty() const {
       // |rva_size == 0| and |offset_size > 0| means Unit hasn't been trimmed
       // yet, and once it is then it's empty.
       // |rva_size > 0| and |offset_size == 0| means Unit has dangling RVA, but
       // is not empty.
       return rva_size == 0;
     }
     bool CoversOffset(offset_t offset) const {
       return RangeCovers(offset_begin, offset_size, offset);
     }
     bool CoversRva(rva_t rva) const {
       return RangeCovers(rva_begin, rva_size, rva);
     }
     bool CoversDanglingRva(rva_t rva) const {
       return CoversRva(rva) && rva - rva_begin >= offset_size;
     }
     // Assumes valid |offset| (*cannot* be fake offset).
     rva_t OffsetToRvaUnsafe(offset_t offset) const {
       return offset - offset_begin + rva_begin;
     }
     // Assumes valid |rva| (*can* be danging RVA).
     offset_t RvaToOffsetUnsafe(rva_t rva, offset_t fake_offset_begin) const {
       rva_t delta = rva - rva_begin;
       return delta < offset_size ? delta + offset_begin
                                  : fake_offset_begin + rva;
     }
     bool HasDanglingRva() const { return rva_size > offset_size; }
     friend bool operator==(const Unit& a, const Unit& b) {
       return std::tie(a.offset_begin, a.offset_size, a.rva_begin, a.rva_size) ==
              std::tie(b.offset_begin, b.offset_size, b.rva_begin, b.rva_size);
     }

     offset_t offset_begin;
     offset_t offset_size;
     rva_t rva_begin;
     rva_t rva_size;
   };

   // An adaptor for AddressTranslator::OffsetToRva() that caches the last Unit
   // found, to reduce the number of OffsetToUnit() calls for clustered queries.
   class OffsetToRvaCache {
    public:
     // Embeds |translator| for use. Now object lifetime is tied to |translator|
     // lifetime.
     explicit OffsetToRvaCache(const AddressTranslator& translator);

     rva_t Convert(offset_t offset) const;

    private:
     const AddressTranslator& translator_;
     mutable const AddressTranslator::Unit* cached_unit_ = nullptr;

     DISALLOW_COPY_AND_ASSIGN(OffsetToRvaCache);
   };

   // An adaptor for AddressTranslator::RvaToOffset() that caches the last Unit
   // found, to reduce the number of RvaToUnit() calls for clustered queries.
   class RvaToOffsetCache {
    public:
     // Embeds |translator| for use. Now object lifetime is tied to |translator|
     // lifetime.
     explicit RvaToOffsetCache(const AddressTranslator& translator);

     bool IsValid(rva_t rva) const;

     offset_t Convert(rva_t rva) const;

    private:
     const AddressTranslator& translator_;
     mutable const AddressTranslator::Unit* cached_unit_ = nullptr;

     DISALLOW_COPY_AND_ASSIGN(RvaToOffsetCache);
   };

   enum Status {
     kSuccess = 0,
     kErrorOverflow,
     kErrorBadOverlap,
     kErrorBadOverlapDanglingRva,
     kErrorFakeOffsetBeginTooLarge,
   };

   AddressTranslator();
   ~AddressTranslator();

   // Consumes |units| to populate data in this class. Performs consistency
   // checks and overlapping Units. Returns Status to indicate success.
   Status Initialize(std::vector<Unit>&& units);

   // Returns the (possibly dangling) RVA corresponding to |offset|, or
   // kInvalidRva if not found.
   rva_t OffsetToRva(offset_t offset) const;

   // Returns the (possibly fake) offset corresponding to |rva|, or
   // kInvalidOffset if not found (i.e., |rva| is non-existent).
   offset_t RvaToOffset(rva_t rva) const;

   // For testing.
   offset_t fake_offset_begin() const { return fake_offset_begin_; }

   const std::vector<Unit>& units_sorted_by_offset() const {
     return units_sorted_by_offset_;
   }

   const std::vector<Unit>& units_sorted_by_rva() const {
     return units_sorted_by_rva_;
   }

  private:
   // Helper to find the Unit that contains given |offset| or |rva|. Returns null
   // if not found.
   const Unit* OffsetToUnit(offset_t offset) const;
   const Unit* RvaToUnit(rva_t rva) const;

   // Storage of Units. All offset ranges are non-empty and disjoint. Likewise
   // for all RVA ranges.
   std::vector<Unit> units_sorted_by_offset_;
   std::vector<Unit> units_sorted_by_rva_;

   // Conversion factor to translate between dangling RVAs and fake offsets.
   offset_t fake_offset_begin_;

   DISALLOW_COPY_AND_ASSIGN(AddressTranslator);
 };

 }  // namespace zucchini

 #endif  // COMPONENTS_ZUCCHINI_ADDRESS_TRANSLATOR_H_
	// Copyright 2017 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.

	#ifndef COMPONENTS_ZUCCHINI_ADDRESS_TRANSLATOR_H_
	#define COMPONENTS_ZUCCHINI_ADDRESS_TRANSLATOR_H_

	#include <stdint.h>

	#include <tuple>
	#include <vector>

	#include "base/macros.h"
	#include "components/zucchini/algorithm.h"
	#include "components/zucchini/image_utils.h"

	namespace zucchini {

	// There are several ways to reason about addresses in an image:
	// - Offset: Position relative to start of image.
	// - VA (Virtual Address): Virtual memory address of a loaded image. This is
	// subject to relocation by the OS.
	// - RVA (Relative Virtual Address): VA relative to some base address. This is
	// the preferred way to specify pointers in an image.
	//
	// Zucchini is primarily concerned with offsets and RVAs. Executable images like
	// PE and ELF are organized into sections. Each section specifies offset and RVA
	// ranges as:
	// {Offset start, offset size, RVA start, RVA size}.
	// This constitutes a basic unit to translate between offsets and RVAs. Note:
	// \|offset size\| < \|RVA size\| is possible. For example, the .bss section can can
	// have zero-filled statically-allocated data that have no corresponding bytes
	// on image (to save space). This poses a problem for Zucchini, which stores
	// addresses as offsets: now we'd have "dangling RVAs" that don't map to
	// offsets! Some ways to handling this are:
	// 1. Ignore all dangling RVAs. This simplifies the algorithm, but also means
	// some reference targets would escape detection and processing.
	// 2. Create distinct "fake offsets" to accommodate dangling RVAs. Image data
	// must not be read on these fake offsets, which are only valid as target
	// addresses for reference matching.
	// As for \|RVA size\| < \|offset size\|, the extra portion just gets ignored.
	//
	// Status: Zucchini implements (2) in a simple way: dangling RVAs are mapped to
	// fake offsets by adding a large value. This value can be chosen as an
	// exclusive upper bound of all offsets (i.e., image size). This allows them to
	// be easily detected and processed as a special-case.
	// TODO(huangs): Investigate option (1), now that the refactored code makes
	// experimentation easier.
	// TODO(huangs): Make AddressTranslator smarter: Allocate unused \|offset_t\|
	// ranges and create "fake" units to accommodate dangling RVAs. Then
	// AddressTranslator can be simplified.

	// Virtual Address relative to some base address (RVA). There's distinction
	// between "valid RVA" and "existent RVA":
	// - Valid RVA: An RVA that's reasonably small, i.e., below \|kRvaBound\|.
	// - Existent RVA: An RVA that has semantic meaning in an image, and may
	// translate to an offset in an image or (if a dangling RVA) a fake offset.
	// All existent RVAs are valid RVAs.
	using rva_t = uint32_t;
	// Divide by 2 to match \|kOffsetBound\|.
	constexpr rva_t kRvaBound = static_cast<rva_t>(-1) / 2;
	constexpr rva_t kInvalidRva = static_cast<rva_t>(-2);

	// A utility to translate between offsets and RVAs in an image.
	class AddressTranslator {
	public:
	// A basic unit for address translation, roughly maps to a section, but may
	// be processed (e.g., merged) as an optimization.
	struct Unit {
	offset_t offset_end() const { return offset_begin + offset_size; }
	rva_t rva_end() const { return rva_begin + rva_size; }
	bool IsEmpty() const {
	// \|rva_size == 0\| and \|offset_size > 0\| means Unit hasn't been trimmed
	// yet, and once it is then it's empty.
	// \|rva_size > 0\| and \|offset_size == 0\| means Unit has dangling RVA, but
	// is not empty.
	return rva_size == 0;
	}
	bool CoversOffset(offset_t offset) const {
	return RangeCovers(offset_begin, offset_size, offset);
	}
	bool CoversRva(rva_t rva) const {
	return RangeCovers(rva_begin, rva_size, rva);
	}
	bool CoversDanglingRva(rva_t rva) const {
	return CoversRva(rva) && rva - rva_begin >= offset_size;
	}
	// Assumes valid \|offset\| (cannot be fake offset).
	rva_t OffsetToRvaUnsafe(offset_t offset) const {
	return offset - offset_begin + rva_begin;
	}
	// Assumes valid \|rva\| (can be danging RVA).
	offset_t RvaToOffsetUnsafe(rva_t rva, offset_t fake_offset_begin) const {
	rva_t delta = rva - rva_begin;
	return delta < offset_size ? delta + offset_begin
	: fake_offset_begin + rva;
	}
	bool HasDanglingRva() const { return rva_size > offset_size; }
	friend bool operator==(const Unit& a, const Unit& b) {
	return std::tie(a.offset_begin, a.offset_size, a.rva_begin, a.rva_size) ==
	std::tie(b.offset_begin, b.offset_size, b.rva_begin, b.rva_size);
	}

	offset_t offset_begin;
	offset_t offset_size;
	rva_t rva_begin;
	rva_t rva_size;
	};

	// An adaptor for AddressTranslator::OffsetToRva() that caches the last Unit
	// found, to reduce the number of OffsetToUnit() calls for clustered queries.
	class OffsetToRvaCache {
	public:
	// Embeds \|translator\| for use. Now object lifetime is tied to \|translator\|
	// lifetime.
	explicit OffsetToRvaCache(const AddressTranslator& translator);

	rva_t Convert(offset_t offset) const;

	private:
	const AddressTranslator& translator_;
	mutable const AddressTranslator::Unit* cached_unit_ = nullptr;

	DISALLOW_COPY_AND_ASSIGN(OffsetToRvaCache);
	};

	// An adaptor for AddressTranslator::RvaToOffset() that caches the last Unit
	// found, to reduce the number of RvaToUnit() calls for clustered queries.
	class RvaToOffsetCache {
	public:
	// Embeds \|translator\| for use. Now object lifetime is tied to \|translator\|
	// lifetime.
	explicit RvaToOffsetCache(const AddressTranslator& translator);

	bool IsValid(rva_t rva) const;

	offset_t Convert(rva_t rva) const;

	private:
	const AddressTranslator& translator_;
	mutable const AddressTranslator::Unit* cached_unit_ = nullptr;

	DISALLOW_COPY_AND_ASSIGN(RvaToOffsetCache);
	};

	enum Status {
	kSuccess = 0,
	kErrorOverflow,
	kErrorBadOverlap,
	kErrorBadOverlapDanglingRva,
	kErrorFakeOffsetBeginTooLarge,
	};

	AddressTranslator();
	~AddressTranslator();

	// Consumes \|units\| to populate data in this class. Performs consistency
	// checks and overlapping Units. Returns Status to indicate success.
	Status Initialize(std::vector<Unit>&& units);

	// Returns the (possibly dangling) RVA corresponding to \|offset\|, or
	// kInvalidRva if not found.
	rva_t OffsetToRva(offset_t offset) const;

	// Returns the (possibly fake) offset corresponding to \|rva\|, or
	// kInvalidOffset if not found (i.e., \|rva\| is non-existent).
	offset_t RvaToOffset(rva_t rva) const;

	// For testing.
	offset_t fake_offset_begin() const { return fake_offset_begin_; }

	const std::vector<Unit>& units_sorted_by_offset() const {
	return units_sorted_by_offset_;
	}

	const std::vector<Unit>& units_sorted_by_rva() const {
	return units_sorted_by_rva_;
	}

	private:
	// Helper to find the Unit that contains given \|offset\| or \|rva\|. Returns null
	// if not found.
	const Unit* OffsetToUnit(offset_t offset) const;
	const Unit* RvaToUnit(rva_t rva) const;

	// Storage of Units. All offset ranges are non-empty and disjoint. Likewise
	// for all RVA ranges.
	std::vector<Unit> units_sorted_by_offset_;
	std::vector<Unit> units_sorted_by_rva_;

	// Conversion factor to translate between dangling RVAs and fake offsets.
	offset_t fake_offset_begin_;

	DISALLOW_COPY_AND_ASSIGN(AddressTranslator);
	};

	} // namespace zucchini

	#endif // COMPONENTS_ZUCCHINI_ADDRESS_TRANSLATOR_H_