runtime/platform/utils.h - sdk.git - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef RUNTIME_PLATFORM_UTILS_H_
 #define RUNTIME_PLATFORM_UTILS_H_

 #include <limits>
 #include <memory>
 #include <type_traits>

 #include "platform/assert.h"
 #include "platform/globals.h"

 namespace dart {

 class Utils {
  public:
   template <typename T>
   static inline T Minimum(T x, T y) {
     return x < y ? x : y;
   }

   template <typename T>
   static constexpr inline T Maximum(T x, T y) {
     return x > y ? x : y;
   }

   // Calculates absolute value of a given signed integer.
   // `x` must not be equal to minimum value representable by `T`
   // as its absolute value is out of range.
   template <typename T>
   static inline T Abs(T x) {
     // Note: as a general rule, it is not OK to use STL in Dart VM.
     // However, std::numeric_limits<T>::min() and max() are harmless
     // and worthwhile exception from this rule.
     ASSERT(x != std::numeric_limits<T>::min());
     if (x < 0) return -x;
     return x;
   }

   // Calculates absolute value of a given signed integer with saturation.
   // If `x` equals to minimum value representable by `T`, then
   // absolute value is saturated to the maximum value representable by `T`.
   template <typename T>
   static inline T AbsWithSaturation(T x) {
     if (x < 0) {
       // Note: as a general rule, it is not OK to use STL in Dart VM.
       // However, std::numeric_limits<T>::min() and max() are harmless
       // and worthwhile exception from this rule.
       if (x == std::numeric_limits<T>::min()) {
         return std::numeric_limits<T>::max();
       }
       return -x;
     }
     return x;
   }

   template <typename T>
   static constexpr bool IsPowerOfTwo(T x) {
     return ((x & (x - 1)) == 0) && (x != 0);
   }

   template <typename T>
   static inline int ShiftForPowerOfTwo(T x) {
     ASSERT(IsPowerOfTwo(x));
     int num_shifts = 0;
     while (x > 1) {
       num_shifts++;
       x = x >> 1;
     }
     return num_shifts;
   }

   template <typename T>
   static constexpr bool IsAligned(T x, intptr_t n) {
     assert(IsPowerOfTwo(n));
     return (x & (n - 1)) == 0;
   }

   template <typename T>
   static constexpr bool IsAligned(T* x, intptr_t n) {
     return IsAligned(reinterpret_cast<uword>(x), n);
   }

   template <typename T>
   static inline T RoundDown(T x, intptr_t n) {
     ASSERT(IsPowerOfTwo(n));
     return (x & -n);
   }

   template <typename T>
   static inline T* RoundDown(T* x, intptr_t n) {
     return reinterpret_cast<T*>(RoundDown(reinterpret_cast<uword>(x), n));
   }

   template <typename T>
   static inline T RoundUp(T x, intptr_t n) {
     return RoundDown(x + n - 1, n);
   }

   template <typename T>
   static inline T* RoundUp(T* x, intptr_t n) {
     return reinterpret_cast<T*>(RoundUp(reinterpret_cast<uword>(x), n));
   }

   static uintptr_t RoundUpToPowerOfTwo(uintptr_t x);

   static int CountOneBits64(uint64_t x);
   static int CountOneBits32(uint32_t x);

   static int CountOneBitsWord(uword x) {
 #ifdef ARCH_IS_64_BIT
     return CountOneBits64(x);
 #else
     return CountOneBits32(x);
 #endif
   }

   // TODO(koda): Compare to flsll call/intrinsic.
   static constexpr size_t HighestBit(int64_t v) {
     uint64_t x = static_cast<uint64_t>((v > 0) ? v : -v);
     uint64_t t = 0;
     size_t r = 0;
     if ((t = x >> 32) != 0) {
       x = t;
       r += 32;
     }
     if ((t = x >> 16) != 0) {
       x = t;
       r += 16;
     }
     if ((t = x >> 8) != 0) {
       x = t;
       r += 8;
     }
     if ((t = x >> 4) != 0) {
       x = t;
       r += 4;
     }
     if ((t = x >> 2) != 0) {
       x = t;
       r += 2;
     }
     if (x > 1) r += 1;
     return r;
   }

   static constexpr size_t BitLength(int64_t value) {
     // Flip bits if negative (-1 becomes 0).
     value ^= value >> (8 * sizeof(value) - 1);
     return (value == 0) ? 0 : (Utils::HighestBit(value) + 1);
   }

   static int CountLeadingZeros64(uint64_t x);
   static int CountLeadingZeros32(uint32_t x);

   static int CountLeadingZerosWord(uword x) {
 #ifdef ARCH_IS_64_BIT
     return CountLeadingZeros64(x);
 #else
     return CountLeadingZeros32(x);
 #endif
   }

   static int CountTrailingZeros64(uint64_t x);
   static int CountTrailingZeros32(uint32_t x);

   static int CountTrailingZerosWord(uword x) {
 #ifdef ARCH_IS_64_BIT
     return CountTrailingZeros64(x);
 #else
     return CountTrailingZeros32(x);
 #endif
   }

   static uint64_t ReverseBits64(uint64_t x);
   static uint32_t ReverseBits32(uint32_t x);

   static uword ReverseBitsWord(uword x) {
 #ifdef ARCH_IS_64_BIT
     return ReverseBits64(x);
 #else
     return ReverseBits32(x);
 #endif
   }

   // Computes magic numbers to implement DIV or MOD operator.
   static void CalculateMagicAndShiftForDivRem(int64_t divisor,
                                               int64_t* magic,
                                               int64_t* shift);

   // Computes a hash value for the given series of bytes.
   static uint32_t StringHash(const void* data, int length);

   // Computes a hash value for the given word.
   static uint32_t WordHash(intptr_t key);

   // Check whether an N-bit two's-complement representation can hold value.
   template <typename T>
   static inline bool IsInt(intptr_t N, T value) {
     ASSERT(N >= 1);
     constexpr intptr_t value_size_in_bits = kBitsPerByte * sizeof(T);
     if constexpr (std::is_signed<T>::value) {
       if (N >= value_size_in_bits) return true;  // Trivially fits.
     } else {
       if (N > value_size_in_bits) return true;  // Trivially fits.
       if (N == value_size_in_bits) {
         return static_cast<typename std::make_signed<T>::type>(value) >= 0;
       }
     }
     const T limit = static_cast<T>(1) << (N - 1);
     return (-limit <= value) && (value < limit);
   }

   template <typename T>
   static inline bool IsUint(intptr_t N, T value) {
     ASSERT(N >= 1);
     constexpr intptr_t value_size_in_bits = kBitsPerByte * sizeof(T);
     if constexpr (std::is_signed<T>::value) {
       if (value < 0) return false;  // Not an unsigned value.
       if (N >= value_size_in_bits - 1) {
         return true;  // N can fit the magnitude bits.
       }
     } else {
       if (N >= value_size_in_bits) return true;  // Trivially fits.
     }
     const T limit = (static_cast<T>(1) << N) - 1;
     return value <= limit;
   }

   // Check whether the magnitude of value fits in N bits. This differs from
   // IsInt(N + 1, value) only in that this returns false for the minimum value
   // of a N+1 bit two's complement value.
   //
   // Primarily used for testing whether a two's complement value can be used in
   // a place where the sign is replaced with a marker that says whether the
   // magnitude is added or subtracted, e.g., the U bit (bit 23) in some ARM7
   // instructions.
   template <typename T>
   static inline bool MagnitudeIsUint(intptr_t N, T value) {
     ASSERT(N >= 1);
     if constexpr (std::is_signed<T>::value) {
       using Unsigned = typename std::make_unsigned<T>::type;
       if (value < 0) return IsUint<Unsigned>(N, -value);
     }
     return IsUint(N, value);
   }

   static inline int32_t Low16Bits(int32_t value) {
     return static_cast<int32_t>(value & 0xffff);
   }

   static inline int32_t High16Bits(int32_t value) {
     return static_cast<int32_t>(value >> 16);
   }

   static inline int32_t Low32Bits(int64_t value) {
     return static_cast<int32_t>(value);
   }

   static inline int32_t High32Bits(int64_t value) {
     return static_cast<int32_t>(value >> 32);
   }

   static inline int64_t LowHighTo64Bits(uint32_t low, int32_t high) {
     return (static_cast<uint64_t>(high) << 32) | (low & 0x0ffffffffLL);
   }

   static inline constexpr bool IsAlphaNumeric(uint32_t c) {
     return (c >= 'A' && c <= 'Z') || (c >= 'a' && c <= 'z') ||
            IsDecimalDigit(c);
   }

   static inline constexpr bool IsDecimalDigit(uint32_t c) {
     return ('0' <= c) && (c <= '9');
   }

   static bool IsHexDigit(char c) {
     return IsDecimalDigit(c) || (('A' <= c) && (c <= 'F')) ||
            (('a' <= c) && (c <= 'f'));
   }

   static int HexDigitToInt(char c) {
     ASSERT(IsHexDigit(c));
     if (IsDecimalDigit(c)) return c - '0';
     if (('A' <= c) && (c <= 'F')) return 10 + (c - 'A');
     return 10 + (c - 'a');
   }

   static char IntToHexDigit(int i) {
     ASSERT(0 <= i && i < 16);
     if (i < 10) return static_cast<char>('0' + i);
     return static_cast<char>('A' + (i - 10));
   }

   // Perform a range check, checking if
   //    offset + count <= length
   // without the risk of integer overflow.
   static inline bool RangeCheck(intptr_t offset,
                                 intptr_t count,
                                 intptr_t length) {
     return offset >= 0 && count >= 0 && length >= 0 &&
            count <= (length - offset);
   }

   static inline bool WillAddOverflow(int64_t a, int64_t b) {
     return ((b > 0) && (a > (kMaxInt64 - b))) ||
            ((b < 0) && (a < (kMinInt64 - b)));
   }

   static inline bool WillSubOverflow(int64_t a, int64_t b) {
     return ((b > 0) && (a < (kMinInt64 + b))) ||
            ((b < 0) && (a > (kMaxInt64 + b)));
   }

   // Adds two int64_t values with wrapping around
   // (two's complement arithmetic).
   template <typename T = int64_t>
   static inline T AddWithWrapAround(T a, T b) {
     // Avoid undefined behavior by doing arithmetic in the unsigned type.
     using Unsigned = typename std::make_unsigned<T>::type;
     return static_cast<T>(static_cast<Unsigned>(a) + static_cast<Unsigned>(b));
   }

   // Subtracts two int64_t values with wrapping around
   // (two's complement arithmetic).
   template <typename T = int64_t>
   static inline T SubWithWrapAround(T a, T b) {
     // Avoid undefined behavior by doing arithmetic in the unsigned type.
     using Unsigned = typename std::make_unsigned<T>::type;
     return static_cast<T>(static_cast<Unsigned>(a) - static_cast<Unsigned>(b));
   }

   // Multiplies two int64_t values with wrapping around
   // (two's complement arithmetic).
   template <typename T = int64_t>
   static inline T MulWithWrapAround(T a, T b) {
     // Avoid undefined behavior by doing arithmetic in the unsigned type.
     using Unsigned = typename std::make_unsigned<T>::type;
     return static_cast<T>(static_cast<Unsigned>(a) * static_cast<Unsigned>(b));
   }

   template <typename T = int64_t>
   static inline T NegWithWrapAround(T a) {
     // Avoid undefined behavior by doing arithmetic in the unsigned type.
     using Unsigned = typename std::make_unsigned<T>::type;
     return static_cast<T>(-static_cast<Unsigned>(a));
   }

   // Shifts int64_t value left. Supports any non-negative number of bits and
   // silently discards shifted out bits.
   static inline int64_t ShiftLeftWithTruncation(int64_t a, int64_t b) {
     ASSERT(b >= 0);
     if (b >= kBitsPerInt64) {
       return 0;
     }
     // Avoid undefined behavior by doing arithmetic in the unsigned type.
     return static_cast<int64_t>(static_cast<uint64_t>(a) << b);
   }

   template <typename T>
   static inline T RotateLeft(T value, uint8_t rotate) {
     const uint8_t width = sizeof(T) * kBitsPerByte;
     ASSERT(0 <= rotate);
     ASSERT(rotate <= width);
     using Unsigned = typename std::make_unsigned<T>::type;
     return (static_cast<Unsigned>(value) << rotate) |
            (static_cast<T>(value) >> ((width - rotate) & (width - 1)));
   }
   template <typename T>
   static inline T RotateRight(T value, uint8_t rotate) {
     const uint8_t width = sizeof(T) * kBitsPerByte;
     ASSERT(0 <= rotate);
     ASSERT(rotate <= width);
     using Unsigned = typename std::make_unsigned<T>::type;
     return (static_cast<T>(value) >> rotate) |
            (static_cast<Unsigned>(value) << ((width - rotate) & (width - 1)));
   }

   // Utility functions for converting values from host endianness to
   // big or little endian values.
   static uint16_t HostToBigEndian16(uint16_t host_value);
   static uint32_t HostToBigEndian32(uint32_t host_value);
   static uint64_t HostToBigEndian64(uint64_t host_value);
   static uint16_t HostToLittleEndian16(uint16_t host_value);
   static uint32_t HostToLittleEndian32(uint32_t host_value);
   static uint64_t HostToLittleEndian64(uint64_t host_value);

   // Going between Host <-> LE/BE is the same operation for all practical
   // purposes.
   static inline uint32_t BigEndianToHost32(uint32_t be_value) {
     return HostToBigEndian32(be_value);
   }
   static inline uint64_t LittleEndianToHost64(uint64_t le_value) {
     return HostToLittleEndian64(le_value);
   }

   static bool DoublesBitEqual(const double a, const double b) {
     return bit_cast<int64_t, double>(a) == bit_cast<int64_t, double>(b);
   }

   // A double-to-integer conversion that avoids undefined behavior.
   // Out of range values and NaNs are converted to minimum value
   // for type T.
   template <typename T>
   static T SafeDoubleToInt(double v) {
     const double min = static_cast<double>(std::numeric_limits<T>::min());
     const double max = static_cast<double>(std::numeric_limits<T>::max());
     return (min <= v && v <= max) ? static_cast<T>(v)
                                   : std::numeric_limits<T>::min();
   }

   // dart2js represents integers as double precision floats, which can
   // represent anything in the range -2^53 ... 2^53.
   static bool IsJavascriptInt(int64_t value) {
     return ((-0x20000000000000LL <= value) && (value <= 0x20000000000000LL));
   }

   // The lowest n bits are 1, the others are 0.
   template <typename T = uword>
   static constexpr T NBitMask(size_t n) {
     using Unsigned = typename std::make_unsigned<T>::type;
     constexpr size_t kBitsPerT = sizeof(T) * kBitsPerByte;
     assert(n <= sizeof(T) * kBitsPerT);
     return static_cast<T>(n == kBitsPerT ? std::numeric_limits<Unsigned>::max()
                                          : (static_cast<Unsigned>(1) << n) - 1);
   }

   template <typename T = uword>
   static constexpr T Bit(size_t n) {
     ASSERT(n < sizeof(T) * kBitsPerByte);
     T bit = 1;
     return bit << n;
   }

   template <typename T>
   static constexpr bool TestBit(T mask, size_t position) {
     ASSERT(position < sizeof(T) * kBitsPerByte);
     return ((mask >> position) & 1) != 0;
   }

   static char* StrError(int err, char* buffer, size_t bufsize);

   // Not all platforms support strndup.
   static char* StrNDup(const char* s, intptr_t n);
   static char* StrDup(const char* s);
   static intptr_t StrNLen(const char* s, intptr_t n);

   static int Close(int fildes);
   static size_t Read(int filedes, void* buf, size_t nbyte);
   static int Unlink(const char* path);

   // Print formatted output info a buffer.
   //
   // Does not write more than size characters (including the trailing '\0').
   //
   // Returns the number of characters (excluding the trailing '\0')
   // that would been written if the buffer had been big enough.  If
   // the return value is greater or equal than the given size then the
   // output has been truncated.  The return value is never negative.
   //
   // The buffer will always be terminated by a '\0', unless the buffer
   // is of size 0.  The buffer might be NULL if the size is 0.
   //
   // This specification conforms to C99 standard which is implemented
   // by glibc 2.1+ with one exception: the C99 standard allows a
   // negative return value.  We will terminate the vm rather than let
   // that occur.
   static int SNPrint(char* str, size_t size, const char* format, ...)
       PRINTF_ATTRIBUTE(3, 4);
   static int VSNPrint(char* str, size_t size, const char* format, va_list args);

   // Allocate a string and print formatted output into a malloc'd buffer.
   static char* SCreate(const char* format, ...) PRINTF_ATTRIBUTE(1, 2);
   static char* VSCreate(const char* format, va_list args);

   typedef std::unique_ptr<char, decltype(std::free)*> CStringUniquePtr;

   // Returns str in a unique_ptr with free used as its deleter.
   static CStringUniquePtr CreateCStringUniquePtr(char* str);
 };

 }  // namespace dart

 #if defined(DART_HOST_OS_ANDROID)
 #include "platform/utils_android.h"
 #elif defined(DART_HOST_OS_FUCHSIA)
 #include "platform/utils_fuchsia.h"
 #elif defined(DART_HOST_OS_LINUX)
 #include "platform/utils_linux.h"
 #elif defined(DART_HOST_OS_MACOS)
 #include "platform/utils_macos.h"
 #elif defined(DART_HOST_OS_WINDOWS)
 #include "platform/utils_win.h"
 #else
 #error Unknown target os.
 #endif

 #endif  // RUNTIME_PLATFORM_UTILS_H_
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef RUNTIME_PLATFORM_UTILS_H_
	#define RUNTIME_PLATFORM_UTILS_H_

	#include <limits>
	#include <memory>
	#include <type_traits>

	#include "platform/assert.h"
	#include "platform/globals.h"

	namespace dart {

	class Utils {
	public:
	template <typename T>
	static inline T Minimum(T x, T y) {
	return x < y ? x : y;
	}

	template <typename T>
	static constexpr inline T Maximum(T x, T y) {
	return x > y ? x : y;
	}

	// Calculates absolute value of a given signed integer.
	// `x` must not be equal to minimum value representable by `T`
	// as its absolute value is out of range.
	template <typename T>
	static inline T Abs(T x) {
	// Note: as a general rule, it is not OK to use STL in Dart VM.
	// However, std::numeric_limits<T>::min() and max() are harmless
	// and worthwhile exception from this rule.
	ASSERT(x != std::numeric_limits<T>::min());
	if (x < 0) return -x;
	return x;
	}

	// Calculates absolute value of a given signed integer with saturation.
	// If `x` equals to minimum value representable by `T`, then
	// absolute value is saturated to the maximum value representable by `T`.
	template <typename T>
	static inline T AbsWithSaturation(T x) {
	if (x < 0) {
	// Note: as a general rule, it is not OK to use STL in Dart VM.
	// However, std::numeric_limits<T>::min() and max() are harmless
	// and worthwhile exception from this rule.
	if (x == std::numeric_limits<T>::min()) {
	return std::numeric_limits<T>::max();
	}
	return -x;
	}
	return x;
	}

	template <typename T>
	static constexpr bool IsPowerOfTwo(T x) {
	return ((x & (x - 1)) == 0) && (x != 0);
	}

	template <typename T>
	static inline int ShiftForPowerOfTwo(T x) {
	ASSERT(IsPowerOfTwo(x));
	int num_shifts = 0;
	while (x > 1) {
	num_shifts++;
	x = x >> 1;
	}
	return num_shifts;
	}

	template <typename T>
	static constexpr bool IsAligned(T x, intptr_t n) {
	assert(IsPowerOfTwo(n));
	return (x & (n - 1)) == 0;
	}

	template <typename T>
	static constexpr bool IsAligned(T* x, intptr_t n) {
	return IsAligned(reinterpret_cast<uword>(x), n);
	}

	template <typename T>
	static inline T RoundDown(T x, intptr_t n) {
	ASSERT(IsPowerOfTwo(n));
	return (x & -n);
	}

	template <typename T>
	static inline T* RoundDown(T* x, intptr_t n) {
	return reinterpret_cast<T*>(RoundDown(reinterpret_cast<uword>(x), n));
	}

	template <typename T>
	static inline T RoundUp(T x, intptr_t n) {
	return RoundDown(x + n - 1, n);
	}

	template <typename T>
	static inline T* RoundUp(T* x, intptr_t n) {
	return reinterpret_cast<T*>(RoundUp(reinterpret_cast<uword>(x), n));
	}

	static uintptr_t RoundUpToPowerOfTwo(uintptr_t x);

	static int CountOneBits64(uint64_t x);
	static int CountOneBits32(uint32_t x);

	static int CountOneBitsWord(uword x) {
	#ifdef ARCH_IS_64_BIT
	return CountOneBits64(x);
	#else
	return CountOneBits32(x);
	#endif
	}

	// TODO(koda): Compare to flsll call/intrinsic.
	static constexpr size_t HighestBit(int64_t v) {
	uint64_t x = static_cast<uint64_t>((v > 0) ? v : -v);
	uint64_t t = 0;
	size_t r = 0;
	if ((t = x >> 32) != 0) {
	x = t;
	r += 32;
	}
	if ((t = x >> 16) != 0) {
	x = t;
	r += 16;
	}
	if ((t = x >> 8) != 0) {
	x = t;
	r += 8;
	}
	if ((t = x >> 4) != 0) {
	x = t;
	r += 4;
	}
	if ((t = x >> 2) != 0) {
	x = t;
	r += 2;
	}
	if (x > 1) r += 1;
	return r;
	}

	static constexpr size_t BitLength(int64_t value) {
	// Flip bits if negative (-1 becomes 0).
	value ^= value >> (8 * sizeof(value) - 1);
	return (value == 0) ? 0 : (Utils::HighestBit(value) + 1);
	}

	static int CountLeadingZeros64(uint64_t x);
	static int CountLeadingZeros32(uint32_t x);

	static int CountLeadingZerosWord(uword x) {
	#ifdef ARCH_IS_64_BIT
	return CountLeadingZeros64(x);
	#else
	return CountLeadingZeros32(x);
	#endif
	}

	static int CountTrailingZeros64(uint64_t x);
	static int CountTrailingZeros32(uint32_t x);

	static int CountTrailingZerosWord(uword x) {
	#ifdef ARCH_IS_64_BIT
	return CountTrailingZeros64(x);
	#else
	return CountTrailingZeros32(x);
	#endif
	}

	static uint64_t ReverseBits64(uint64_t x);
	static uint32_t ReverseBits32(uint32_t x);

	static uword ReverseBitsWord(uword x) {
	#ifdef ARCH_IS_64_BIT
	return ReverseBits64(x);
	#else
	return ReverseBits32(x);
	#endif
	}

	// Computes magic numbers to implement DIV or MOD operator.
	static void CalculateMagicAndShiftForDivRem(int64_t divisor,
	int64_t* magic,
	int64_t* shift);

	// Computes a hash value for the given series of bytes.
	static uint32_t StringHash(const void* data, int length);

	// Computes a hash value for the given word.
	static uint32_t WordHash(intptr_t key);

	// Check whether an N-bit two's-complement representation can hold value.
	template <typename T>
	static inline bool IsInt(intptr_t N, T value) {
	ASSERT(N >= 1);
	constexpr intptr_t value_size_in_bits = kBitsPerByte * sizeof(T);
	if constexpr (std::is_signed<T>::value) {
	if (N >= value_size_in_bits) return true; // Trivially fits.
	} else {
	if (N > value_size_in_bits) return true; // Trivially fits.
	if (N == value_size_in_bits) {
	return static_cast<typename std::make_signed<T>::type>(value) >= 0;
	}
	}
	const T limit = static_cast<T>(1) << (N - 1);
	return (-limit <= value) && (value < limit);
	}

	template <typename T>
	static inline bool IsUint(intptr_t N, T value) {
	ASSERT(N >= 1);
	constexpr intptr_t value_size_in_bits = kBitsPerByte * sizeof(T);
	if constexpr (std::is_signed<T>::value) {
	if (value < 0) return false; // Not an unsigned value.
	if (N >= value_size_in_bits - 1) {
	return true; // N can fit the magnitude bits.
	}
	} else {
	if (N >= value_size_in_bits) return true; // Trivially fits.
	}
	const T limit = (static_cast<T>(1) << N) - 1;
	return value <= limit;
	}

	// Check whether the magnitude of value fits in N bits. This differs from
	// IsInt(N + 1, value) only in that this returns false for the minimum value
	// of a N+1 bit two's complement value.
	//
	// Primarily used for testing whether a two's complement value can be used in
	// a place where the sign is replaced with a marker that says whether the
	// magnitude is added or subtracted, e.g., the U bit (bit 23) in some ARM7
	// instructions.
	template <typename T>
	static inline bool MagnitudeIsUint(intptr_t N, T value) {
	ASSERT(N >= 1);
	if constexpr (std::is_signed<T>::value) {
	using Unsigned = typename std::make_unsigned<T>::type;
	if (value < 0) return IsUint<Unsigned>(N, -value);
	}
	return IsUint(N, value);
	}

	static inline int32_t Low16Bits(int32_t value) {
	return static_cast<int32_t>(value & 0xffff);
	}

	static inline int32_t High16Bits(int32_t value) {
	return static_cast<int32_t>(value >> 16);
	}

	static inline int32_t Low32Bits(int64_t value) {
	return static_cast<int32_t>(value);
	}

	static inline int32_t High32Bits(int64_t value) {
	return static_cast<int32_t>(value >> 32);
	}

	static inline int64_t LowHighTo64Bits(uint32_t low, int32_t high) {
	return (static_cast<uint64_t>(high) << 32) \| (low & 0x0ffffffffLL);
	}

	static inline constexpr bool IsAlphaNumeric(uint32_t c) {
	return (c >= 'A' && c <= 'Z') \|\| (c >= 'a' && c <= 'z') \|\|
	IsDecimalDigit(c);
	}

	static inline constexpr bool IsDecimalDigit(uint32_t c) {
	return ('0' <= c) && (c <= '9');
	}

	static bool IsHexDigit(char c) {
	return IsDecimalDigit(c) \|\| (('A' <= c) && (c <= 'F')) \|\|
	(('a' <= c) && (c <= 'f'));
	}

	static int HexDigitToInt(char c) {
	ASSERT(IsHexDigit(c));
	if (IsDecimalDigit(c)) return c - '0';
	if (('A' <= c) && (c <= 'F')) return 10 + (c - 'A');
	return 10 + (c - 'a');
	}

	static char IntToHexDigit(int i) {
	ASSERT(0 <= i && i < 16);
	if (i < 10) return static_cast<char>('0' + i);
	return static_cast<char>('A' + (i - 10));
	}

	// Perform a range check, checking if
	// offset + count <= length
	// without the risk of integer overflow.
	static inline bool RangeCheck(intptr_t offset,
	intptr_t count,
	intptr_t length) {
	return offset >= 0 && count >= 0 && length >= 0 &&
	count <= (length - offset);
	}

	static inline bool WillAddOverflow(int64_t a, int64_t b) {
	return ((b > 0) && (a > (kMaxInt64 - b))) \|\|
	((b < 0) && (a < (kMinInt64 - b)));
	}

	static inline bool WillSubOverflow(int64_t a, int64_t b) {
	return ((b > 0) && (a < (kMinInt64 + b))) \|\|
	((b < 0) && (a > (kMaxInt64 + b)));
	}

	// Adds two int64_t values with wrapping around
	// (two's complement arithmetic).
	template <typename T = int64_t>
	static inline T AddWithWrapAround(T a, T b) {
	// Avoid undefined behavior by doing arithmetic in the unsigned type.
	using Unsigned = typename std::make_unsigned<T>::type;
	return static_cast<T>(static_cast<Unsigned>(a) + static_cast<Unsigned>(b));
	}

	// Subtracts two int64_t values with wrapping around
	// (two's complement arithmetic).
	template <typename T = int64_t>
	static inline T SubWithWrapAround(T a, T b) {
	// Avoid undefined behavior by doing arithmetic in the unsigned type.
	using Unsigned = typename std::make_unsigned<T>::type;
	return static_cast<T>(static_cast<Unsigned>(a) - static_cast<Unsigned>(b));
	}

	// Multiplies two int64_t values with wrapping around
	// (two's complement arithmetic).
	template <typename T = int64_t>
	static inline T MulWithWrapAround(T a, T b) {
	// Avoid undefined behavior by doing arithmetic in the unsigned type.
	using Unsigned = typename std::make_unsigned<T>::type;
	return static_cast<T>(static_cast<Unsigned>(a) * static_cast<Unsigned>(b));
	}

	template <typename T = int64_t>
	static inline T NegWithWrapAround(T a) {
	// Avoid undefined behavior by doing arithmetic in the unsigned type.
	using Unsigned = typename std::make_unsigned<T>::type;
	return static_cast<T>(-static_cast<Unsigned>(a));
	}

	// Shifts int64_t value left. Supports any non-negative number of bits and
	// silently discards shifted out bits.
	static inline int64_t ShiftLeftWithTruncation(int64_t a, int64_t b) {
	ASSERT(b >= 0);
	if (b >= kBitsPerInt64) {
	return 0;
	}
	// Avoid undefined behavior by doing arithmetic in the unsigned type.
	return static_cast<int64_t>(static_cast<uint64_t>(a) << b);
	}

	template <typename T>
	static inline T RotateLeft(T value, uint8_t rotate) {
	const uint8_t width = sizeof(T) * kBitsPerByte;
	ASSERT(0 <= rotate);
	ASSERT(rotate <= width);
	using Unsigned = typename std::make_unsigned<T>::type;
	return (static_cast<Unsigned>(value) << rotate) \|
	(static_cast<T>(value) >> ((width - rotate) & (width - 1)));
	}
	template <typename T>
	static inline T RotateRight(T value, uint8_t rotate) {
	const uint8_t width = sizeof(T) * kBitsPerByte;
	ASSERT(0 <= rotate);
	ASSERT(rotate <= width);
	using Unsigned = typename std::make_unsigned<T>::type;
	return (static_cast<T>(value) >> rotate) \|
	(static_cast<Unsigned>(value) << ((width - rotate) & (width - 1)));
	}

	// Utility functions for converting values from host endianness to
	// big or little endian values.
	static uint16_t HostToBigEndian16(uint16_t host_value);
	static uint32_t HostToBigEndian32(uint32_t host_value);
	static uint64_t HostToBigEndian64(uint64_t host_value);
	static uint16_t HostToLittleEndian16(uint16_t host_value);
	static uint32_t HostToLittleEndian32(uint32_t host_value);
	static uint64_t HostToLittleEndian64(uint64_t host_value);

	// Going between Host <-> LE/BE is the same operation for all practical
	// purposes.
	static inline uint32_t BigEndianToHost32(uint32_t be_value) {
	return HostToBigEndian32(be_value);
	}
	static inline uint64_t LittleEndianToHost64(uint64_t le_value) {
	return HostToLittleEndian64(le_value);
	}

	static bool DoublesBitEqual(const double a, const double b) {
	return bit_cast<int64_t, double>(a) == bit_cast<int64_t, double>(b);
	}

	// A double-to-integer conversion that avoids undefined behavior.
	// Out of range values and NaNs are converted to minimum value
	// for type T.
	template <typename T>
	static T SafeDoubleToInt(double v) {
	const double min = static_cast<double>(std::numeric_limits<T>::min());
	const double max = static_cast<double>(std::numeric_limits<T>::max());
	return (min <= v && v <= max) ? static_cast<T>(v)
	: std::numeric_limits<T>::min();
	}

	// dart2js represents integers as double precision floats, which can
	// represent anything in the range -2^53 ... 2^53.
	static bool IsJavascriptInt(int64_t value) {
	return ((-0x20000000000000LL <= value) && (value <= 0x20000000000000LL));
	}

	// The lowest n bits are 1, the others are 0.
	template <typename T = uword>
	static constexpr T NBitMask(size_t n) {
	using Unsigned = typename std::make_unsigned<T>::type;
	constexpr size_t kBitsPerT = sizeof(T) * kBitsPerByte;
	assert(n <= sizeof(T) * kBitsPerT);
	return static_cast<T>(n == kBitsPerT ? std::numeric_limits<Unsigned>::max()
	: (static_cast<Unsigned>(1) << n) - 1);
	}

	template <typename T = uword>
	static constexpr T Bit(size_t n) {
	ASSERT(n < sizeof(T) * kBitsPerByte);
	T bit = 1;
	return bit << n;
	}

	template <typename T>
	static constexpr bool TestBit(T mask, size_t position) {
	ASSERT(position < sizeof(T) * kBitsPerByte);
	return ((mask >> position) & 1) != 0;
	}

	static char* StrError(int err, char* buffer, size_t bufsize);

	// Not all platforms support strndup.
	static char* StrNDup(const char* s, intptr_t n);
	static char* StrDup(const char* s);
	static intptr_t StrNLen(const char* s, intptr_t n);

	static int Close(int fildes);
	static size_t Read(int filedes, void* buf, size_t nbyte);
	static int Unlink(const char* path);

	// Print formatted output info a buffer.
	//
	// Does not write more than size characters (including the trailing '\0').
	//
	// Returns the number of characters (excluding the trailing '\0')
	// that would been written if the buffer had been big enough. If
	// the return value is greater or equal than the given size then the
	// output has been truncated. The return value is never negative.
	//
	// The buffer will always be terminated by a '\0', unless the buffer
	// is of size 0. The buffer might be NULL if the size is 0.
	//
	// This specification conforms to C99 standard which is implemented
	// by glibc 2.1+ with one exception: the C99 standard allows a
	// negative return value. We will terminate the vm rather than let
	// that occur.
	static int SNPrint(char* str, size_t size, const char* format, ...)
	PRINTF_ATTRIBUTE(3, 4);
	static int VSNPrint(char* str, size_t size, const char* format, va_list args);

	// Allocate a string and print formatted output into a malloc'd buffer.
	static char* SCreate(const char* format, ...) PRINTF_ATTRIBUTE(1, 2);
	static char* VSCreate(const char* format, va_list args);

	typedef std::unique_ptr<char, decltype(std::free)*> CStringUniquePtr;

	// Returns str in a unique_ptr with free used as its deleter.
	static CStringUniquePtr CreateCStringUniquePtr(char* str);
	};

	} // namespace dart

	#if defined(DART_HOST_OS_ANDROID)
	#include "platform/utils_android.h"
	#elif defined(DART_HOST_OS_FUCHSIA)
	#include "platform/utils_fuchsia.h"
	#elif defined(DART_HOST_OS_LINUX)
	#include "platform/utils_linux.h"
	#elif defined(DART_HOST_OS_MACOS)
	#include "platform/utils_macos.h"
	#elif defined(DART_HOST_OS_WINDOWS)
	#include "platform/utils_win.h"
	#else
	#error Unknown target os.
	#endif

	#endif // RUNTIME_PLATFORM_UTILS_H_