base/memory/protected_memory.h - cobalt - 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.

 // Protected memory is memory holding security-sensitive data intended to be
 // left read-only for the majority of its lifetime to avoid being overwritten
 // by attackers. ProtectedMemory is a simple wrapper around platform-specific
 // APIs to set memory read-write and read-only when required. Protected memory
 // should be set read-write for the minimum amount of time required.

 // Normally mutable variables are held in read-write memory and constant data
 // is held in read-only memory to ensure it is not accidentally overwritten.
 // In some cases we want to hold mutable variables in read-only memory, except
 // when they are being written to, to ensure that they are not tampered with.
 //
 // ProtectedMemory is a container class intended to hold a single variable in
 // read-only memory, except when explicitly set read-write. The variable can be
 // set read-write by creating a scoped AutoWritableMemory object by calling
 // AutoWritableMemory::Create(), the memory stays writable until the returned
 // object goes out of scope and is destructed. The wrapped variable can be
 // accessed using operator* and operator->.
 //
 // Instances of ProtectedMemory must be declared in the PROTECTED_MEMORY_SECTION
 // and as global variables. Because protected memory variables are globals, the
 // the same rules apply disallowing non-trivial constructors and destructors.
 // Global definitions are required to avoid the linker placing statics in
 // inlinable functions into a comdat section and setting the protected memory
 // section read-write when they are merged.
 //
 // EXAMPLE:
 //
 //  struct Items { void* item1; };
 //  static PROTECTED_MEMORY_SECTION base::ProtectedMemory<Items> items;
 //  void InitializeItems() {
 //    // Explicitly set items read-write before writing to it.
 //    auto writer = base::AutoWritableMemory::Create(items);
 //    items->item1 = /* ... */;
 //    assert(items->item1 != nullptr);
 //    // items is set back to read-only on the destruction of writer
 //  }
 //
 //  using FnPtr = void (*)(void);
 //  PROTECTED_MEMORY_SECTION base::ProtectedMemory<FnPtr> fnPtr;
 //  FnPtr ResolveFnPtr(void) {
 //    // The Initializer nested class is a helper class for creating a static
 //    // initializer for a ProtectedMemory variable. It implicitly sets the
 //    // variable read-write during initialization.
 //    static base::ProtectedMemory<FnPtr>::Initializer I(&fnPtr,
 //      reinterpret_cast<FnPtr>(dlsym(/* ... */)));
 //    return *fnPtr;
 //  }

 #ifndef BASE_MEMORY_PROTECTED_MEMORY_H_
 #define BASE_MEMORY_PROTECTED_MEMORY_H_

 #include "base/lazy_instance.h"
 #include "base/logging.h"
 #include "base/macros.h"
 #include "base/memory/protected_memory_buildflags.h"
 #include "base/synchronization/lock.h"
 #include "build/build_config.h"

 #define PROTECTED_MEMORY_ENABLED 1

 // Linking with lld is required to workaround crbug.com/792777.
 // TODO(vtsyrklevich): Remove once support for gold on Android/CrOs is dropped
 #if defined(OS_LINUX) && BUILDFLAG(USE_LLD)
 // Define the section read-only
 __asm__(".section protected_memory, \"a\"\n\t");
 #define PROTECTED_MEMORY_SECTION __attribute__((section("protected_memory")))

 // Explicitly mark these variables hidden so the symbols are local to the
 // currently built component. Otherwise they are created with global (external)
 // linkage and component builds would break because a single pair of these
 // symbols would override the rest.
 __attribute__((visibility("hidden"))) extern char __start_protected_memory;
 __attribute__((visibility("hidden"))) extern char __stop_protected_memory;

 #elif defined(OS_MACOSX) && !defined(OS_IOS)
 // The segment the section is in is defined read-only with a linker flag in
 // build/config/mac/BUILD.gn
 #define PROTECTED_MEMORY_SECTION \
   __attribute__((section("PROTECTED_MEMORY, protected_memory")))
 extern char __start_protected_memory __asm(
     "section$start$PROTECTED_MEMORY$protected_memory");
 extern char __stop_protected_memory __asm(
     "section$end$PROTECTED_MEMORY$protected_memory");

 #elif defined(OS_WIN)
 // Define a read-write prot section. The $a, $mem, and $z 'sub-sections' are
 // merged alphabetically so $a and $z are used to define the start and end of
 // the protected memory section, and $mem holds protected variables.
 // (Note: Sections in Portable Executables are equivalent to segments in other
 // executable formats, so this section is mapped into its own pages.)
 #pragma section("prot$a", read, write)
 #pragma section("prot$mem", read, write)
 #pragma section("prot$z", read, write)

 // We want the protected memory section to be read-only, not read-write so we
 // instruct the linker to set the section read-only at link time. We do this
 // at link time instead of compile time, because defining the prot section
 // read-only would cause mis-compiles due to optimizations assuming that the
 // section contents are constant.
 #pragma comment(linker, "/SECTION:prot,R")

 __declspec(allocate("prot$a")) __declspec(selectany)
 char __start_protected_memory;
 __declspec(allocate("prot$z")) __declspec(selectany)
 char __stop_protected_memory;

 #define PROTECTED_MEMORY_SECTION __declspec(allocate("prot$mem"))

 #else
 #undef PROTECTED_MEMORY_ENABLED
 #define PROTECTED_MEMORY_ENABLED 0
 #define PROTECTED_MEMORY_SECTION
 #endif

 namespace base {

 template <typename T>
 class ProtectedMemory {
  public:
   ProtectedMemory() = default;

   // Expose direct access to the encapsulated variable
   T& operator*() { return data; }
   const T& operator*() const { return data; }
   T* operator->() { return &data; }
   const T* operator->() const { return &data; }

   // Helper class for creating simple ProtectedMemory static initializers.
   class Initializer {
    public:
     // Defined out-of-line below to break circular definition dependency between
     // ProtectedMemory and AutoWritableMemory.
     Initializer(ProtectedMemory<T>* PM, const T& Init);

     DISALLOW_IMPLICIT_CONSTRUCTORS(Initializer);
   };

  private:
   T data;

   DISALLOW_COPY_AND_ASSIGN(ProtectedMemory);
 };

 // DCHECK that the byte at |ptr| is read-only.
 BASE_EXPORT void AssertMemoryIsReadOnly(const void* ptr);

 // Abstract out platform-specific methods to get the beginning and end of the
 // PROTECTED_MEMORY_SECTION. ProtectedMemoryEnd returns a pointer to the byte
 // past the end of the PROTECTED_MEMORY_SECTION.
 #if PROTECTED_MEMORY_ENABLED
 constexpr void* ProtectedMemoryStart = &__start_protected_memory;
 constexpr void* ProtectedMemoryEnd = &__stop_protected_memory;
 #endif

 #if defined(COMPONENT_BUILD)
 namespace internal {

 // For component builds we want to define a separate global writers variable
 // (explained below) in every DSO that includes this header. To do that we use
 // this template to define a global without duplicate symbol errors.
 template <typename T>
 struct DsoSpecific {
   static T value;
 };
 template <typename T>
 T DsoSpecific<T>::value = 0;

 }  // namespace internal
 #endif  // defined(COMPONENT_BUILD)

 // A class that sets a given ProtectedMemory variable writable while the
 // AutoWritableMemory is in scope. This class implements the logic for setting
 // the protected memory region read-only/read-write in a thread-safe manner.
 class AutoWritableMemory {
  private:
   // 'writers' is a global holding the number of ProtectedMemory instances set
   // writable, used to avoid races setting protected memory readable/writable.
   // When this reaches zero the protected memory region is set read only.
   // Access is controlled by writers_lock.
 #if defined(COMPONENT_BUILD)
   // For component builds writers is a reference to an int defined separately in
   // every DSO.
   static constexpr int& writers = internal::DsoSpecific<int>::value;
 #else
   // Otherwise, we declare writers in the protected memory section to avoid the
   // scenario where an attacker could overwrite it with a large value and invoke
   // code that constructs and destructs an AutoWritableMemory. After such a call
   // protected memory would still be set writable because writers > 0.
   static int writers;
 #endif  // defined(COMPONENT_BUILD)

   // Synchronizes access to the writers variable and the simultaneous actions
   // that need to happen alongside writers changes, e.g. setting the protected
   // memory region readable when writers is decremented to 0.
   static BASE_EXPORT base::LazyInstance<Lock>::Leaky writers_lock;

   // Abstract out platform-specific memory APIs. |end| points to the byte past
   // the end of the region of memory having its memory protections changed.
   BASE_EXPORT bool SetMemoryReadWrite(void* start, void* end);
   BASE_EXPORT bool SetMemoryReadOnly(void* start, void* end);

   // If this is the first writer (e.g. writers == 0) set the writers variable
   // read-write. Next, increment writers and set the requested memory writable.
   AutoWritableMemory(void* ptr, void* ptr_end) {
 #if PROTECTED_MEMORY_ENABLED
     DCHECK(ptr >= ProtectedMemoryStart && ptr_end <= ProtectedMemoryEnd);

     {
       base::AutoLock auto_lock(writers_lock.Get());
       if (writers == 0) {
         AssertMemoryIsReadOnly(ptr);
 #if !defined(COMPONENT_BUILD)
         AssertMemoryIsReadOnly(&writers);
         CHECK(SetMemoryReadWrite(&writers, &writers + 1));
 #endif  // !defined(COMPONENT_BUILD)
       }

       writers++;
     }

     CHECK(SetMemoryReadWrite(ptr, ptr_end));
 #endif  // PROTECTED_MEMORY_ENABLED
   }

  public:
   // Wrap the private constructor to create an easy-to-use interface to
   // construct AutoWritableMemory objects.
   template <typename T>
   static AutoWritableMemory Create(ProtectedMemory<T>& PM) {
     T* ptr = &*PM;
     return AutoWritableMemory(ptr, ptr + 1);
   }

   // Move constructor just increments writers
   AutoWritableMemory(AutoWritableMemory&& original) {
 #if PROTECTED_MEMORY_ENABLED
     base::AutoLock auto_lock(writers_lock.Get());
     CHECK_GT(writers, 0);
     writers++;
 #endif  // PROTECTED_MEMORY_ENABLED
   }

   // On destruction decrement writers, and if no other writers exist, set the
   // entire protected memory region read-only.
   ~AutoWritableMemory() {
 #if PROTECTED_MEMORY_ENABLED
     base::AutoLock auto_lock(writers_lock.Get());
     CHECK_GT(writers, 0);
     writers--;

     if (writers == 0) {
       CHECK(SetMemoryReadOnly(ProtectedMemoryStart, ProtectedMemoryEnd));
 #if !defined(COMPONENT_BUILD)
       AssertMemoryIsReadOnly(&writers);
 #endif  // !defined(COMPONENT_BUILD)
     }
 #endif  // PROTECTED_MEMORY_ENABLED
   }

   DISALLOW_IMPLICIT_CONSTRUCTORS(AutoWritableMemory);
 };

 template <typename T>
 ProtectedMemory<T>::Initializer::Initializer(ProtectedMemory<T>* PM,
                                              const T& Init) {
   AutoWritableMemory writer = AutoWritableMemory::Create(*PM);
   **PM = Init;
 }

 }  // namespace base

 #endif  // BASE_MEMORY_PROTECTED_MEMORY_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.

	// Protected memory is memory holding security-sensitive data intended to be
	// left read-only for the majority of its lifetime to avoid being overwritten
	// by attackers. ProtectedMemory is a simple wrapper around platform-specific
	// APIs to set memory read-write and read-only when required. Protected memory
	// should be set read-write for the minimum amount of time required.

	// Normally mutable variables are held in read-write memory and constant data
	// is held in read-only memory to ensure it is not accidentally overwritten.
	// In some cases we want to hold mutable variables in read-only memory, except
	// when they are being written to, to ensure that they are not tampered with.
	//
	// ProtectedMemory is a container class intended to hold a single variable in
	// read-only memory, except when explicitly set read-write. The variable can be
	// set read-write by creating a scoped AutoWritableMemory object by calling
	// AutoWritableMemory::Create(), the memory stays writable until the returned
	// object goes out of scope and is destructed. The wrapped variable can be
	// accessed using operator* and operator->.
	//
	// Instances of ProtectedMemory must be declared in the PROTECTED_MEMORY_SECTION
	// and as global variables. Because protected memory variables are globals, the
	// the same rules apply disallowing non-trivial constructors and destructors.
	// Global definitions are required to avoid the linker placing statics in
	// inlinable functions into a comdat section and setting the protected memory
	// section read-write when they are merged.
	//
	// EXAMPLE:
	//
	// struct Items { void* item1; };
	// static PROTECTED_MEMORY_SECTION base::ProtectedMemory<Items> items;
	// void InitializeItems() {
	// // Explicitly set items read-write before writing to it.
	// auto writer = base::AutoWritableMemory::Create(items);
	// items->item1 = /* ... */;
	// assert(items->item1 != nullptr);
	// // items is set back to read-only on the destruction of writer
	// }
	//
	// using FnPtr = void (*)(void);
	// PROTECTED_MEMORY_SECTION base::ProtectedMemory<FnPtr> fnPtr;
	// FnPtr ResolveFnPtr(void) {
	// // The Initializer nested class is a helper class for creating a static
	// // initializer for a ProtectedMemory variable. It implicitly sets the
	// // variable read-write during initialization.
	// static base::ProtectedMemory<FnPtr>::Initializer I(&fnPtr,
	// reinterpret_cast<FnPtr>(dlsym(/* ... */)));
	// return *fnPtr;
	// }

	#ifndef BASE_MEMORY_PROTECTED_MEMORY_H_
	#define BASE_MEMORY_PROTECTED_MEMORY_H_

	#include "base/lazy_instance.h"
	#include "base/logging.h"
	#include "base/macros.h"
	#include "base/memory/protected_memory_buildflags.h"
	#include "base/synchronization/lock.h"
	#include "build/build_config.h"

	#define PROTECTED_MEMORY_ENABLED 1

	// Linking with lld is required to workaround crbug.com/792777.
	// TODO(vtsyrklevich): Remove once support for gold on Android/CrOs is dropped
	#if defined(OS_LINUX) && BUILDFLAG(USE_LLD)
	// Define the section read-only
	__asm__(".section protected_memory, \"a\"\n\t");
	#define PROTECTED_MEMORY_SECTION __attribute__((section("protected_memory")))

	// Explicitly mark these variables hidden so the symbols are local to the
	// currently built component. Otherwise they are created with global (external)
	// linkage and component builds would break because a single pair of these
	// symbols would override the rest.
	__attribute__((visibility("hidden"))) extern char __start_protected_memory;
	__attribute__((visibility("hidden"))) extern char __stop_protected_memory;

	#elif defined(OS_MACOSX) && !defined(OS_IOS)
	// The segment the section is in is defined read-only with a linker flag in
	// build/config/mac/BUILD.gn
	#define PROTECTED_MEMORY_SECTION \
	__attribute__((section("PROTECTED_MEMORY, protected_memory")))
	extern char __start_protected_memory __asm(
	"section$start$PROTECTED_MEMORY$protected_memory");
	extern char __stop_protected_memory __asm(
	"section$end$PROTECTED_MEMORY$protected_memory");

	#elif defined(OS_WIN)
	// Define a read-write prot section. The $a, $mem, and $z 'sub-sections' are
	// merged alphabetically so $a and $z are used to define the start and end of
	// the protected memory section, and $mem holds protected variables.
	// (Note: Sections in Portable Executables are equivalent to segments in other
	// executable formats, so this section is mapped into its own pages.)
	#pragma section("prot$a", read, write)
	#pragma section("prot$mem", read, write)
	#pragma section("prot$z", read, write)

	// We want the protected memory section to be read-only, not read-write so we
	// instruct the linker to set the section read-only at link time. We do this
	// at link time instead of compile time, because defining the prot section
	// read-only would cause mis-compiles due to optimizations assuming that the
	// section contents are constant.
	#pragma comment(linker, "/SECTION:prot,R")

	__declspec(allocate("prot$a")) __declspec(selectany)
	char __start_protected_memory;
	__declspec(allocate("prot$z")) __declspec(selectany)
	char __stop_protected_memory;

	#define PROTECTED_MEMORY_SECTION __declspec(allocate("prot$mem"))

	#else
	#undef PROTECTED_MEMORY_ENABLED
	#define PROTECTED_MEMORY_ENABLED 0
	#define PROTECTED_MEMORY_SECTION
	#endif

	namespace base {

	template <typename T>
	class ProtectedMemory {
	public:
	ProtectedMemory() = default;

	// Expose direct access to the encapsulated variable
	T& operator*() { return data; }
	const T& operator*() const { return data; }
	T* operator->() { return &data; }
	const T* operator->() const { return &data; }

	// Helper class for creating simple ProtectedMemory static initializers.
	class Initializer {
	public:
	// Defined out-of-line below to break circular definition dependency between
	// ProtectedMemory and AutoWritableMemory.
	Initializer(ProtectedMemory<T>* PM, const T& Init);

	DISALLOW_IMPLICIT_CONSTRUCTORS(Initializer);
	};

	private:
	T data;

	DISALLOW_COPY_AND_ASSIGN(ProtectedMemory);
	};

	// DCHECK that the byte at \|ptr\| is read-only.
	BASE_EXPORT void AssertMemoryIsReadOnly(const void* ptr);

	// Abstract out platform-specific methods to get the beginning and end of the
	// PROTECTED_MEMORY_SECTION. ProtectedMemoryEnd returns a pointer to the byte
	// past the end of the PROTECTED_MEMORY_SECTION.
	#if PROTECTED_MEMORY_ENABLED
	constexpr void* ProtectedMemoryStart = &__start_protected_memory;
	constexpr void* ProtectedMemoryEnd = &__stop_protected_memory;
	#endif

	#if defined(COMPONENT_BUILD)
	namespace internal {

	// For component builds we want to define a separate global writers variable
	// (explained below) in every DSO that includes this header. To do that we use
	// this template to define a global without duplicate symbol errors.
	template <typename T>
	struct DsoSpecific {
	static T value;
	};
	template <typename T>
	T DsoSpecific<T>::value = 0;

	} // namespace internal
	#endif // defined(COMPONENT_BUILD)

	// A class that sets a given ProtectedMemory variable writable while the
	// AutoWritableMemory is in scope. This class implements the logic for setting
	// the protected memory region read-only/read-write in a thread-safe manner.
	class AutoWritableMemory {
	private:
	// 'writers' is a global holding the number of ProtectedMemory instances set
	// writable, used to avoid races setting protected memory readable/writable.
	// When this reaches zero the protected memory region is set read only.
	// Access is controlled by writers_lock.
	#if defined(COMPONENT_BUILD)
	// For component builds writers is a reference to an int defined separately in
	// every DSO.
	static constexpr int& writers = internal::DsoSpecific<int>::value;
	#else
	// Otherwise, we declare writers in the protected memory section to avoid the
	// scenario where an attacker could overwrite it with a large value and invoke
	// code that constructs and destructs an AutoWritableMemory. After such a call
	// protected memory would still be set writable because writers > 0.
	static int writers;
	#endif // defined(COMPONENT_BUILD)

	// Synchronizes access to the writers variable and the simultaneous actions
	// that need to happen alongside writers changes, e.g. setting the protected
	// memory region readable when writers is decremented to 0.
	static BASE_EXPORT base::LazyInstance<Lock>::Leaky writers_lock;

	// Abstract out platform-specific memory APIs. \|end\| points to the byte past
	// the end of the region of memory having its memory protections changed.
	BASE_EXPORT bool SetMemoryReadWrite(void* start, void* end);
	BASE_EXPORT bool SetMemoryReadOnly(void* start, void* end);

	// If this is the first writer (e.g. writers == 0) set the writers variable
	// read-write. Next, increment writers and set the requested memory writable.
	AutoWritableMemory(void* ptr, void* ptr_end) {
	#if PROTECTED_MEMORY_ENABLED
	DCHECK(ptr >= ProtectedMemoryStart && ptr_end <= ProtectedMemoryEnd);

	{
	base::AutoLock auto_lock(writers_lock.Get());
	if (writers == 0) {
	AssertMemoryIsReadOnly(ptr);
	#if !defined(COMPONENT_BUILD)
	AssertMemoryIsReadOnly(&writers);
	CHECK(SetMemoryReadWrite(&writers, &writers + 1));
	#endif // !defined(COMPONENT_BUILD)
	}

	writers++;
	}

	CHECK(SetMemoryReadWrite(ptr, ptr_end));
	#endif // PROTECTED_MEMORY_ENABLED
	}

	public:
	// Wrap the private constructor to create an easy-to-use interface to
	// construct AutoWritableMemory objects.
	template <typename T>
	static AutoWritableMemory Create(ProtectedMemory<T>& PM) {
	T* ptr = &*PM;
	return AutoWritableMemory(ptr, ptr + 1);
	}

	// Move constructor just increments writers
	AutoWritableMemory(AutoWritableMemory&& original) {
	#if PROTECTED_MEMORY_ENABLED
	base::AutoLock auto_lock(writers_lock.Get());
	CHECK_GT(writers, 0);
	writers++;
	#endif // PROTECTED_MEMORY_ENABLED
	}

	// On destruction decrement writers, and if no other writers exist, set the
	// entire protected memory region read-only.
	~AutoWritableMemory() {
	#if PROTECTED_MEMORY_ENABLED
	base::AutoLock auto_lock(writers_lock.Get());
	CHECK_GT(writers, 0);
	writers--;

	if (writers == 0) {
	CHECK(SetMemoryReadOnly(ProtectedMemoryStart, ProtectedMemoryEnd));
	#if !defined(COMPONENT_BUILD)
	AssertMemoryIsReadOnly(&writers);
	#endif // !defined(COMPONENT_BUILD)
	}
	#endif // PROTECTED_MEMORY_ENABLED
	}

	DISALLOW_IMPLICIT_CONSTRUCTORS(AutoWritableMemory);
	};

	template <typename T>
	ProtectedMemory<T>::Initializer::Initializer(ProtectedMemory<T>* PM,
	const T& Init) {
	AutoWritableMemory writer = AutoWritableMemory::Create(*PM);
	**PM = Init;
	}

	} // namespace base

	#endif // BASE_MEMORY_PROTECTED_MEMORY_H_