src/platform.h - platform/external/chromium_org/v8 - Git at Google

 // Copyright 2012 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 // This module contains the platform-specific code. This make the rest of the
 // code less dependent on operating system, compilers and runtime libraries.
 // This module does specifically not deal with differences between different
 // processor architecture.
 // The platform classes have the same definition for all platforms. The
 // implementation for a particular platform is put in platform_<os>.cc.
 // The build system then uses the implementation for the target platform.
 //
 // This design has been chosen because it is simple and fast. Alternatively,
 // the platform dependent classes could have been implemented using abstract
 // superclasses with virtual methods and having specializations for each
 // platform. This design was rejected because it was more complicated and
 // slower. It would require factory methods for selecting the right
 // implementation and the overhead of virtual methods for performance
 // sensitive like mutex locking/unlocking.

 #ifndef V8_PLATFORM_H_
 #define V8_PLATFORM_H_

 #include <stdarg.h>
 #include <string>
 #include <vector>

 #include "src/base/build_config.h"
 #include "src/platform/mutex.h"
 #include "src/platform/semaphore.h"

 #ifdef __sun
 # ifndef signbit
 namespace std {
 int signbit(double x);
 }
 # endif
 #endif

 #if V8_OS_QNX
 #include "src/qnx-math.h"
 #endif

 // Microsoft Visual C++ specific stuff.
 #if V8_LIBC_MSVCRT

 #include "src/base/win32-headers.h"
 #include "src/win32-math.h"

 int strncasecmp(const char* s1, const char* s2, int n);

 // Visual C++ 2013 and higher implement this function.
 #if (_MSC_VER < 1800)
 inline int lrint(double flt) {
   int intgr;
 #if V8_TARGET_ARCH_IA32 || V8_TARGET_ARCH_X87
   __asm {
     fld flt
     fistp intgr
   };
 #else
   intgr = static_cast<int>(flt + 0.5);
   if ((intgr & 1) != 0 && intgr - flt == 0.5) {
     // If the number is halfway between two integers, round to the even one.
     intgr--;
   }
 #endif
   return intgr;
 }
 #endif  // _MSC_VER < 1800

 #endif  // V8_LIBC_MSVCRT

 namespace v8 {
 namespace internal {

 // ----------------------------------------------------------------------------
 // Fast TLS support

 #ifndef V8_NO_FAST_TLS

 #if defined(_MSC_VER) && (V8_HOST_ARCH_IA32)

 #define V8_FAST_TLS_SUPPORTED 1

 INLINE(intptr_t InternalGetExistingThreadLocal(intptr_t index));

 inline intptr_t InternalGetExistingThreadLocal(intptr_t index) {
   const intptr_t kTibInlineTlsOffset = 0xE10;
   const intptr_t kTibExtraTlsOffset = 0xF94;
   const intptr_t kMaxInlineSlots = 64;
   const intptr_t kMaxSlots = kMaxInlineSlots + 1024;
   const intptr_t kPointerSize = sizeof(void*);
   ASSERT(0 <= index && index < kMaxSlots);
   if (index < kMaxInlineSlots) {
     return static_cast<intptr_t>(__readfsdword(kTibInlineTlsOffset +
                                                kPointerSize * index));
   }
   intptr_t extra = static_cast<intptr_t>(__readfsdword(kTibExtraTlsOffset));
   ASSERT(extra != 0);
   return *reinterpret_cast<intptr_t*>(extra +
                                       kPointerSize * (index - kMaxInlineSlots));
 }

 #elif defined(__APPLE__) && (V8_HOST_ARCH_IA32 || V8_HOST_ARCH_X64)

 #define V8_FAST_TLS_SUPPORTED 1

 extern intptr_t kMacTlsBaseOffset;

 INLINE(intptr_t InternalGetExistingThreadLocal(intptr_t index));

 inline intptr_t InternalGetExistingThreadLocal(intptr_t index) {
   intptr_t result;
 #if V8_HOST_ARCH_IA32
   asm("movl %%gs:(%1,%2,4), %0;"
       :"=r"(result)  // Output must be a writable register.
       :"r"(kMacTlsBaseOffset), "r"(index));
 #else
   asm("movq %%gs:(%1,%2,8), %0;"
       :"=r"(result)
       :"r"(kMacTlsBaseOffset), "r"(index));
 #endif
   return result;
 }

 #endif

 #endif  // V8_NO_FAST_TLS


 class TimezoneCache;


 // ----------------------------------------------------------------------------
 // OS
 //
 // This class has static methods for the different platform specific
 // functions. Add methods here to cope with differences between the
 // supported platforms.

 class OS {
  public:
   // Returns the accumulated user time for thread. This routine
   // can be used for profiling. The implementation should
   // strive for high-precision timer resolution, preferable
   // micro-second resolution.
   static int GetUserTime(uint32_t* secs,  uint32_t* usecs);

   // Returns current time as the number of milliseconds since
   // 00:00:00 UTC, January 1, 1970.
   static double TimeCurrentMillis();

   static TimezoneCache* CreateTimezoneCache();
   static void DisposeTimezoneCache(TimezoneCache* cache);
   static void ClearTimezoneCache(TimezoneCache* cache);

   // Returns a string identifying the current time zone. The
   // timestamp is used for determining if DST is in effect.
   static const char* LocalTimezone(double time, TimezoneCache* cache);

   // Returns the local time offset in milliseconds east of UTC without
   // taking daylight savings time into account.
   static double LocalTimeOffset(TimezoneCache* cache);

   // Returns the daylight savings offset for the given time.
   static double DaylightSavingsOffset(double time, TimezoneCache* cache);

   // Returns last OS error.
   static int GetLastError();

   static FILE* FOpen(const char* path, const char* mode);
   static bool Remove(const char* path);

   // Opens a temporary file, the file is auto removed on close.
   static FILE* OpenTemporaryFile();

   // Log file open mode is platform-dependent due to line ends issues.
   static const char* const LogFileOpenMode;

   // Print output to console. This is mostly used for debugging output.
   // On platforms that has standard terminal output, the output
   // should go to stdout.
   static void Print(const char* format, ...);
   static void VPrint(const char* format, va_list args);

   // Print output to a file. This is mostly used for debugging output.
   static void FPrint(FILE* out, const char* format, ...);
   static void VFPrint(FILE* out, const char* format, va_list args);

   // Print error output to console. This is mostly used for error message
   // output. On platforms that has standard terminal output, the output
   // should go to stderr.
   static void PrintError(const char* format, ...);
   static void VPrintError(const char* format, va_list args);

   // Allocate/Free memory used by JS heap. Pages are readable/writable, but
   // they are not guaranteed to be executable unless 'executable' is true.
   // Returns the address of allocated memory, or NULL if failed.
   static void* Allocate(const size_t requested,
                         size_t* allocated,
                         bool is_executable);
   static void Free(void* address, const size_t size);

   // This is the granularity at which the ProtectCode(...) call can set page
   // permissions.
   static intptr_t CommitPageSize();

   // Mark code segments non-writable.
   static void ProtectCode(void* address, const size_t size);

   // Assign memory as a guard page so that access will cause an exception.
   static void Guard(void* address, const size_t size);

   // Generate a random address to be used for hinting mmap().
   static void* GetRandomMmapAddr();

   // Get the Alignment guaranteed by Allocate().
   static size_t AllocateAlignment();

   // Sleep for a number of milliseconds.
   static void Sleep(const int milliseconds);

   // Abort the current process.
   static void Abort();

   // Debug break.
   static void DebugBreak();

   // Walk the stack.
   static const int kStackWalkError = -1;
   static const int kStackWalkMaxNameLen = 256;
   static const int kStackWalkMaxTextLen = 256;
   struct StackFrame {
     void* address;
     char text[kStackWalkMaxTextLen];
   };

   class MemoryMappedFile {
    public:
     static MemoryMappedFile* open(const char* name);
     static MemoryMappedFile* create(const char* name, int size, void* initial);
     virtual ~MemoryMappedFile() { }
     virtual void* memory() = 0;
     virtual int size() = 0;
   };

   // Safe formatting print. Ensures that str is always null-terminated.
   // Returns the number of chars written, or -1 if output was truncated.
   static int SNPrintF(char* str, int length, const char* format, ...);
   static int VSNPrintF(char* str,
                        int length,
                        const char* format,
                        va_list args);

   static char* StrChr(char* str, int c);
   static void StrNCpy(char* dest, int length, const char* src, size_t n);

   // Support for the profiler.  Can do nothing, in which case ticks
   // occuring in shared libraries will not be properly accounted for.
   struct SharedLibraryAddress {
     SharedLibraryAddress(
         const std::string& library_path, uintptr_t start, uintptr_t end)
         : library_path(library_path), start(start), end(end) {}

     std::string library_path;
     uintptr_t start;
     uintptr_t end;
   };

   static std::vector<SharedLibraryAddress> GetSharedLibraryAddresses();

   // Support for the profiler.  Notifies the external profiling
   // process that a code moving garbage collection starts.  Can do
   // nothing, in which case the code objects must not move (e.g., by
   // using --never-compact) if accurate profiling is desired.
   static void SignalCodeMovingGC();

   // Returns the number of processors online.
   static int NumberOfProcessorsOnline();

   // The total amount of physical memory available on the current system.
   static uint64_t TotalPhysicalMemory();

   // Maximum size of the virtual memory.  0 means there is no artificial
   // limit.
   static intptr_t MaxVirtualMemory();

   // Returns the double constant NAN
   static double nan_value();

   // Support runtime detection of whether the hard float option of the
   // EABI is used.
   static bool ArmUsingHardFloat();

   // Returns the activation frame alignment constraint or zero if
   // the platform doesn't care. Guaranteed to be a power of two.
   static int ActivationFrameAlignment();

   static int GetCurrentProcessId();

  private:
   static const int msPerSecond = 1000;

   DISALLOW_IMPLICIT_CONSTRUCTORS(OS);
 };

 // Represents and controls an area of reserved memory.
 // Control of the reserved memory can be assigned to another VirtualMemory
 // object by assignment or copy-contructing. This removes the reserved memory
 // from the original object.
 class VirtualMemory {
  public:
   // Empty VirtualMemory object, controlling no reserved memory.
   VirtualMemory();

   // Reserves virtual memory with size.
   explicit VirtualMemory(size_t size);

   // Reserves virtual memory containing an area of the given size that
   // is aligned per alignment. This may not be at the position returned
   // by address().
   VirtualMemory(size_t size, size_t alignment);

   // Releases the reserved memory, if any, controlled by this VirtualMemory
   // object.
   ~VirtualMemory();

   // Returns whether the memory has been reserved.
   bool IsReserved();

   // Initialize or resets an embedded VirtualMemory object.
   void Reset();

   // Returns the start address of the reserved memory.
   // If the memory was reserved with an alignment, this address is not
   // necessarily aligned. The user might need to round it up to a multiple of
   // the alignment to get the start of the aligned block.
   void* address() {
     ASSERT(IsReserved());
     return address_;
   }

   // Returns the size of the reserved memory. The returned value is only
   // meaningful when IsReserved() returns true.
   // If the memory was reserved with an alignment, this size may be larger
   // than the requested size.
   size_t size() { return size_; }

   // Commits real memory. Returns whether the operation succeeded.
   bool Commit(void* address, size_t size, bool is_executable);

   // Uncommit real memory.  Returns whether the operation succeeded.
   bool Uncommit(void* address, size_t size);

   // Creates a single guard page at the given address.
   bool Guard(void* address);

   void Release() {
     ASSERT(IsReserved());
     // Notice: Order is important here. The VirtualMemory object might live
     // inside the allocated region.
     void* address = address_;
     size_t size = size_;
     Reset();
     bool result = ReleaseRegion(address, size);
     USE(result);
     ASSERT(result);
   }

   // Assign control of the reserved region to a different VirtualMemory object.
   // The old object is no longer functional (IsReserved() returns false).
   void TakeControl(VirtualMemory* from) {
     ASSERT(!IsReserved());
     address_ = from->address_;
     size_ = from->size_;
     from->Reset();
   }

   static void* ReserveRegion(size_t size);

   static bool CommitRegion(void* base, size_t size, bool is_executable);

   static bool UncommitRegion(void* base, size_t size);

   // Must be called with a base pointer that has been returned by ReserveRegion
   // and the same size it was reserved with.
   static bool ReleaseRegion(void* base, size_t size);

   // Returns true if OS performs lazy commits, i.e. the memory allocation call
   // defers actual physical memory allocation till the first memory access.
   // Otherwise returns false.
   static bool HasLazyCommits();

  private:
   void* address_;  // Start address of the virtual memory.
   size_t size_;  // Size of the virtual memory.
 };


 // ----------------------------------------------------------------------------
 // Thread
 //
 // Thread objects are used for creating and running threads. When the start()
 // method is called the new thread starts running the run() method in the new
 // thread. The Thread object should not be deallocated before the thread has
 // terminated.

 class Thread {
  public:
   // Opaque data type for thread-local storage keys.
   typedef int32_t LocalStorageKey;

   class Options {
    public:
     Options() : name_("v8:<unknown>"), stack_size_(0) {}
     Options(const char* name, int stack_size = 0)
         : name_(name), stack_size_(stack_size) {}

     const char* name() const { return name_; }
     int stack_size() const { return stack_size_; }

    private:
     const char* name_;
     int stack_size_;
   };

   // Create new thread.
   explicit Thread(const Options& options);
   virtual ~Thread();

   // Start new thread by calling the Run() method on the new thread.
   void Start();

   // Start new thread and wait until Run() method is called on the new thread.
   void StartSynchronously() {
     start_semaphore_ = new Semaphore(0);
     Start();
     start_semaphore_->Wait();
     delete start_semaphore_;
     start_semaphore_ = NULL;
   }

   // Wait until thread terminates.
   void Join();

   inline const char* name() const {
     return name_;
   }

   // Abstract method for run handler.
   virtual void Run() = 0;

   // Thread-local storage.
   static LocalStorageKey CreateThreadLocalKey();
   static void DeleteThreadLocalKey(LocalStorageKey key);
   static void* GetThreadLocal(LocalStorageKey key);
   static int GetThreadLocalInt(LocalStorageKey key) {
     return static_cast<int>(reinterpret_cast<intptr_t>(GetThreadLocal(key)));
   }
   static void SetThreadLocal(LocalStorageKey key, void* value);
   static void SetThreadLocalInt(LocalStorageKey key, int value) {
     SetThreadLocal(key, reinterpret_cast<void*>(static_cast<intptr_t>(value)));
   }
   static bool HasThreadLocal(LocalStorageKey key) {
     return GetThreadLocal(key) != NULL;
   }

 #ifdef V8_FAST_TLS_SUPPORTED
   static inline void* GetExistingThreadLocal(LocalStorageKey key) {
     void* result = reinterpret_cast<void*>(
         InternalGetExistingThreadLocal(static_cast<intptr_t>(key)));
     ASSERT(result == GetThreadLocal(key));
     return result;
   }
 #else
   static inline void* GetExistingThreadLocal(LocalStorageKey key) {
     return GetThreadLocal(key);
   }
 #endif

   // A hint to the scheduler to let another thread run.
   static void YieldCPU();


   // The thread name length is limited to 16 based on Linux's implementation of
   // prctl().
   static const int kMaxThreadNameLength = 16;

   class PlatformData;
   PlatformData* data() { return data_; }

   void NotifyStartedAndRun() {
     if (start_semaphore_) start_semaphore_->Signal();
     Run();
   }

  private:
   void set_name(const char* name);

   PlatformData* data_;

   char name_[kMaxThreadNameLength];
   int stack_size_;
   Semaphore* start_semaphore_;

   DISALLOW_COPY_AND_ASSIGN(Thread);
 };

 } }  // namespace v8::internal

 #endif  // V8_PLATFORM_H_
	// Copyright 2012 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	// This module contains the platform-specific code. This make the rest of the
	// code less dependent on operating system, compilers and runtime libraries.
	// This module does specifically not deal with differences between different
	// processor architecture.
	// The platform classes have the same definition for all platforms. The
	// implementation for a particular platform is put in platform_<os>.cc.
	// The build system then uses the implementation for the target platform.
	//
	// This design has been chosen because it is simple and fast. Alternatively,
	// the platform dependent classes could have been implemented using abstract
	// superclasses with virtual methods and having specializations for each
	// platform. This design was rejected because it was more complicated and
	// slower. It would require factory methods for selecting the right
	// implementation and the overhead of virtual methods for performance
	// sensitive like mutex locking/unlocking.

	#ifndef V8_PLATFORM_H_
	#define V8_PLATFORM_H_

	#include <stdarg.h>
	#include <string>
	#include <vector>

	#include "src/base/build_config.h"
	#include "src/platform/mutex.h"
	#include "src/platform/semaphore.h"

	#ifdef __sun
	# ifndef signbit
	namespace std {
	int signbit(double x);
	}
	# endif
	#endif

	#if V8_OS_QNX
	#include "src/qnx-math.h"
	#endif

	// Microsoft Visual C++ specific stuff.
	#if V8_LIBC_MSVCRT

	#include "src/base/win32-headers.h"
	#include "src/win32-math.h"

	int strncasecmp(const char* s1, const char* s2, int n);

	// Visual C++ 2013 and higher implement this function.
	#if (_MSC_VER < 1800)
	inline int lrint(double flt) {
	int intgr;
	#if V8_TARGET_ARCH_IA32 \|\| V8_TARGET_ARCH_X87
	__asm {
	fld flt
	fistp intgr
	};
	#else
	intgr = static_cast<int>(flt + 0.5);
	if ((intgr & 1) != 0 && intgr - flt == 0.5) {
	// If the number is halfway between two integers, round to the even one.
	intgr--;
	}
	#endif
	return intgr;
	}
	#endif // _MSC_VER < 1800

	#endif // V8_LIBC_MSVCRT

	namespace v8 {
	namespace internal {

	// ----------------------------------------------------------------------------
	// Fast TLS support

	#ifndef V8_NO_FAST_TLS

	#if defined(_MSC_VER) && (V8_HOST_ARCH_IA32)

	#define V8_FAST_TLS_SUPPORTED 1

	INLINE(intptr_t InternalGetExistingThreadLocal(intptr_t index));

	inline intptr_t InternalGetExistingThreadLocal(intptr_t index) {
	const intptr_t kTibInlineTlsOffset = 0xE10;
	const intptr_t kTibExtraTlsOffset = 0xF94;
	const intptr_t kMaxInlineSlots = 64;
	const intptr_t kMaxSlots = kMaxInlineSlots + 1024;
	const intptr_t kPointerSize = sizeof(void*);
	ASSERT(0 <= index && index < kMaxSlots);
	if (index < kMaxInlineSlots) {
	return static_cast<intptr_t>(__readfsdword(kTibInlineTlsOffset +
	kPointerSize * index));
	}
	intptr_t extra = static_cast<intptr_t>(__readfsdword(kTibExtraTlsOffset));
	ASSERT(extra != 0);
	return reinterpret_cast<intptr_t>(extra +
	kPointerSize * (index - kMaxInlineSlots));
	}

	#elif defined(__APPLE__) && (V8_HOST_ARCH_IA32 \|\| V8_HOST_ARCH_X64)

	#define V8_FAST_TLS_SUPPORTED 1

	extern intptr_t kMacTlsBaseOffset;

	INLINE(intptr_t InternalGetExistingThreadLocal(intptr_t index));

	inline intptr_t InternalGetExistingThreadLocal(intptr_t index) {
	intptr_t result;
	#if V8_HOST_ARCH_IA32
	asm("movl %%gs:(%1,%2,4), %0;"
	:"=r"(result) // Output must be a writable register.
	:"r"(kMacTlsBaseOffset), "r"(index));
	#else
	asm("movq %%gs:(%1,%2,8), %0;"
	:"=r"(result)
	:"r"(kMacTlsBaseOffset), "r"(index));
	#endif
	return result;
	}

	#endif

	#endif // V8_NO_FAST_TLS


	class TimezoneCache;


	// ----------------------------------------------------------------------------
	// OS
	//
	// This class has static methods for the different platform specific
	// functions. Add methods here to cope with differences between the
	// supported platforms.

	class OS {
	public:
	// Returns the accumulated user time for thread. This routine
	// can be used for profiling. The implementation should
	// strive for high-precision timer resolution, preferable
	// micro-second resolution.
	static int GetUserTime(uint32_t* secs, uint32_t* usecs);

	// Returns current time as the number of milliseconds since
	// 00:00:00 UTC, January 1, 1970.
	static double TimeCurrentMillis();

	static TimezoneCache* CreateTimezoneCache();
	static void DisposeTimezoneCache(TimezoneCache* cache);
	static void ClearTimezoneCache(TimezoneCache* cache);

	// Returns a string identifying the current time zone. The
	// timestamp is used for determining if DST is in effect.
	static const char* LocalTimezone(double time, TimezoneCache* cache);

	// Returns the local time offset in milliseconds east of UTC without
	// taking daylight savings time into account.
	static double LocalTimeOffset(TimezoneCache* cache);

	// Returns the daylight savings offset for the given time.
	static double DaylightSavingsOffset(double time, TimezoneCache* cache);

	// Returns last OS error.
	static int GetLastError();

	static FILE* FOpen(const char* path, const char* mode);
	static bool Remove(const char* path);

	// Opens a temporary file, the file is auto removed on close.
	static FILE* OpenTemporaryFile();

	// Log file open mode is platform-dependent due to line ends issues.
	static const char* const LogFileOpenMode;

	// Print output to console. This is mostly used for debugging output.
	// On platforms that has standard terminal output, the output
	// should go to stdout.
	static void Print(const char* format, ...);
	static void VPrint(const char* format, va_list args);

	// Print output to a file. This is mostly used for debugging output.
	static void FPrint(FILE* out, const char* format, ...);
	static void VFPrint(FILE* out, const char* format, va_list args);

	// Print error output to console. This is mostly used for error message
	// output. On platforms that has standard terminal output, the output
	// should go to stderr.
	static void PrintError(const char* format, ...);
	static void VPrintError(const char* format, va_list args);

	// Allocate/Free memory used by JS heap. Pages are readable/writable, but
	// they are not guaranteed to be executable unless 'executable' is true.
	// Returns the address of allocated memory, or NULL if failed.
	static void* Allocate(const size_t requested,
	size_t* allocated,
	bool is_executable);
	static void Free(void* address, const size_t size);

	// This is the granularity at which the ProtectCode(...) call can set page
	// permissions.
	static intptr_t CommitPageSize();

	// Mark code segments non-writable.
	static void ProtectCode(void* address, const size_t size);

	// Assign memory as a guard page so that access will cause an exception.
	static void Guard(void* address, const size_t size);

	// Generate a random address to be used for hinting mmap().
	static void* GetRandomMmapAddr();

	// Get the Alignment guaranteed by Allocate().
	static size_t AllocateAlignment();

	// Sleep for a number of milliseconds.
	static void Sleep(const int milliseconds);

	// Abort the current process.
	static void Abort();

	// Debug break.
	static void DebugBreak();

	// Walk the stack.
	static const int kStackWalkError = -1;
	static const int kStackWalkMaxNameLen = 256;
	static const int kStackWalkMaxTextLen = 256;
	struct StackFrame {
	void* address;
	char text[kStackWalkMaxTextLen];
	};

	class MemoryMappedFile {
	public:
	static MemoryMappedFile* open(const char* name);
	static MemoryMappedFile* create(const char* name, int size, void* initial);
	virtual ~MemoryMappedFile() { }
	virtual void* memory() = 0;
	virtual int size() = 0;
	};

	// Safe formatting print. Ensures that str is always null-terminated.
	// Returns the number of chars written, or -1 if output was truncated.
	static int SNPrintF(char* str, int length, const char* format, ...);
	static int VSNPrintF(char* str,
	int length,
	const char* format,
	va_list args);

	static char* StrChr(char* str, int c);
	static void StrNCpy(char* dest, int length, const char* src, size_t n);

	// Support for the profiler. Can do nothing, in which case ticks
	// occuring in shared libraries will not be properly accounted for.
	struct SharedLibraryAddress {
	SharedLibraryAddress(
	const std::string& library_path, uintptr_t start, uintptr_t end)
	: library_path(library_path), start(start), end(end) {}

	std::string library_path;
	uintptr_t start;
	uintptr_t end;
	};

	static std::vector<SharedLibraryAddress> GetSharedLibraryAddresses();

	// Support for the profiler. Notifies the external profiling
	// process that a code moving garbage collection starts. Can do
	// nothing, in which case the code objects must not move (e.g., by
	// using --never-compact) if accurate profiling is desired.
	static void SignalCodeMovingGC();

	// Returns the number of processors online.
	static int NumberOfProcessorsOnline();

	// The total amount of physical memory available on the current system.
	static uint64_t TotalPhysicalMemory();

	// Maximum size of the virtual memory. 0 means there is no artificial
	// limit.
	static intptr_t MaxVirtualMemory();

	// Returns the double constant NAN
	static double nan_value();

	// Support runtime detection of whether the hard float option of the
	// EABI is used.
	static bool ArmUsingHardFloat();

	// Returns the activation frame alignment constraint or zero if
	// the platform doesn't care. Guaranteed to be a power of two.
	static int ActivationFrameAlignment();

	static int GetCurrentProcessId();

	private:
	static const int msPerSecond = 1000;

	DISALLOW_IMPLICIT_CONSTRUCTORS(OS);
	};

	// Represents and controls an area of reserved memory.
	// Control of the reserved memory can be assigned to another VirtualMemory
	// object by assignment or copy-contructing. This removes the reserved memory
	// from the original object.
	class VirtualMemory {
	public:
	// Empty VirtualMemory object, controlling no reserved memory.
	VirtualMemory();

	// Reserves virtual memory with size.
	explicit VirtualMemory(size_t size);

	// Reserves virtual memory containing an area of the given size that
	// is aligned per alignment. This may not be at the position returned
	// by address().
	VirtualMemory(size_t size, size_t alignment);

	// Releases the reserved memory, if any, controlled by this VirtualMemory
	// object.
	~VirtualMemory();

	// Returns whether the memory has been reserved.
	bool IsReserved();

	// Initialize or resets an embedded VirtualMemory object.
	void Reset();

	// Returns the start address of the reserved memory.
	// If the memory was reserved with an alignment, this address is not
	// necessarily aligned. The user might need to round it up to a multiple of
	// the alignment to get the start of the aligned block.
	void* address() {
	ASSERT(IsReserved());
	return address_;
	}

	// Returns the size of the reserved memory. The returned value is only
	// meaningful when IsReserved() returns true.
	// If the memory was reserved with an alignment, this size may be larger
	// than the requested size.
	size_t size() { return size_; }

	// Commits real memory. Returns whether the operation succeeded.
	bool Commit(void* address, size_t size, bool is_executable);

	// Uncommit real memory. Returns whether the operation succeeded.
	bool Uncommit(void* address, size_t size);

	// Creates a single guard page at the given address.
	bool Guard(void* address);

	void Release() {
	ASSERT(IsReserved());
	// Notice: Order is important here. The VirtualMemory object might live
	// inside the allocated region.
	void* address = address_;
	size_t size = size_;
	Reset();
	bool result = ReleaseRegion(address, size);
	USE(result);
	ASSERT(result);
	}

	// Assign control of the reserved region to a different VirtualMemory object.
	// The old object is no longer functional (IsReserved() returns false).
	void TakeControl(VirtualMemory* from) {
	ASSERT(!IsReserved());
	address_ = from->address_;
	size_ = from->size_;
	from->Reset();
	}

	static void* ReserveRegion(size_t size);

	static bool CommitRegion(void* base, size_t size, bool is_executable);

	static bool UncommitRegion(void* base, size_t size);

	// Must be called with a base pointer that has been returned by ReserveRegion
	// and the same size it was reserved with.
	static bool ReleaseRegion(void* base, size_t size);

	// Returns true if OS performs lazy commits, i.e. the memory allocation call
	// defers actual physical memory allocation till the first memory access.
	// Otherwise returns false.
	static bool HasLazyCommits();

	private:
	void* address_; // Start address of the virtual memory.
	size_t size_; // Size of the virtual memory.
	};


	// ----------------------------------------------------------------------------
	// Thread
	//
	// Thread objects are used for creating and running threads. When the start()
	// method is called the new thread starts running the run() method in the new
	// thread. The Thread object should not be deallocated before the thread has
	// terminated.

	class Thread {
	public:
	// Opaque data type for thread-local storage keys.
	typedef int32_t LocalStorageKey;

	class Options {
	public:
	Options() : name_("v8:<unknown>"), stack_size_(0) {}
	Options(const char* name, int stack_size = 0)
	: name_(name), stack_size_(stack_size) {}

	const char* name() const { return name_; }
	int stack_size() const { return stack_size_; }

	private:
	const char* name_;
	int stack_size_;
	};

	// Create new thread.
	explicit Thread(const Options& options);
	virtual ~Thread();

	// Start new thread by calling the Run() method on the new thread.
	void Start();

	// Start new thread and wait until Run() method is called on the new thread.
	void StartSynchronously() {
	start_semaphore_ = new Semaphore(0);
	Start();
	start_semaphore_->Wait();
	delete start_semaphore_;
	start_semaphore_ = NULL;
	}

	// Wait until thread terminates.
	void Join();

	inline const char* name() const {
	return name_;
	}

	// Abstract method for run handler.
	virtual void Run() = 0;

	// Thread-local storage.
	static LocalStorageKey CreateThreadLocalKey();
	static void DeleteThreadLocalKey(LocalStorageKey key);
	static void* GetThreadLocal(LocalStorageKey key);
	static int GetThreadLocalInt(LocalStorageKey key) {
	return static_cast<int>(reinterpret_cast<intptr_t>(GetThreadLocal(key)));
	}
	static void SetThreadLocal(LocalStorageKey key, void* value);
	static void SetThreadLocalInt(LocalStorageKey key, int value) {
	SetThreadLocal(key, reinterpret_cast<void*>(static_cast<intptr_t>(value)));
	}
	static bool HasThreadLocal(LocalStorageKey key) {
	return GetThreadLocal(key) != NULL;
	}

	#ifdef V8_FAST_TLS_SUPPORTED
	static inline void* GetExistingThreadLocal(LocalStorageKey key) {
	void* result = reinterpret_cast<void*>(
	InternalGetExistingThreadLocal(static_cast<intptr_t>(key)));
	ASSERT(result == GetThreadLocal(key));
	return result;
	}
	#else
	static inline void* GetExistingThreadLocal(LocalStorageKey key) {
	return GetThreadLocal(key);
	}
	#endif

	// A hint to the scheduler to let another thread run.
	static void YieldCPU();


	// The thread name length is limited to 16 based on Linux's implementation of
	// prctl().
	static const int kMaxThreadNameLength = 16;

	class PlatformData;
	PlatformData* data() { return data_; }

	void NotifyStartedAndRun() {
	if (start_semaphore_) start_semaphore_->Signal();
	Run();
	}

	private:
	void set_name(const char* name);

	PlatformData* data_;

	char name_[kMaxThreadNameLength];
	int stack_size_;
	Semaphore* start_semaphore_;

	DISALLOW_COPY_AND_ASSIGN(Thread);
	};

	} } // namespace v8::internal

	#endif // V8_PLATFORM_H_