src/third_party/mozjs/js/public/TemplateLib.h - cobalt - Git at Google

 /* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 -*-
  * vim: set ts=8 sts=4 et sw=4 tw=99:
  * This Source Code Form is subject to the terms of the Mozilla Public
  * License, v. 2.0. If a copy of the MPL was not distributed with this
  * file, You can obtain one at http://mozilla.org/MPL/2.0/. */

 #ifndef js_TemplateLib_h
 #define js_TemplateLib_h

 #include "jstypes.h"

 /*
  * Library of reusable template meta-functions (that is, functions on types and
  * compile-time values). Meta-functions are placed inside the 'tl' namespace to
  * avoid conflict with non-meta functions that logically have the same name
  * (e.g., js::tl::Min vs. js::Min).
  */

 namespace js {
 namespace tl {

 /* Compute min/max/clamp. */
 template <size_t i, size_t j> struct Min {
     static const size_t result = i < j ? i : j;
 };
 template <size_t i, size_t j> struct Max {
     static const size_t result = i > j ? i : j;
 };
 template <size_t i, size_t min, size_t max> struct Clamp {
     static const size_t result = i < min ? min : (i > max ? max : i);
 };

 /* Compute x^y. */
 template <size_t x, size_t y> struct Pow {
     static const size_t result = x * Pow<x, y - 1>::result;
 };
 template <size_t x> struct Pow<x,0> {
     static const size_t result = 1;
 };

 /* Compute floor(log2(i)). */
 template <size_t i> struct FloorLog2 {
     static const size_t result = 1 + FloorLog2<i / 2>::result;
 };
 template <> struct FloorLog2<0> { /* Error */ };
 template <> struct FloorLog2<1> { static const size_t result = 0; };

 /* Compute ceiling(log2(i)). */
 template <size_t i> struct CeilingLog2 {
     static const size_t result = FloorLog2<2 * i - 1>::result;
 };

 /* Round up to the nearest power of 2. */
 template <size_t i> struct RoundUpPow2 {
     static const size_t result = size_t(1) << CeilingLog2<i>::result;
 };
 template <> struct RoundUpPow2<0> {
     static const size_t result = 1;
 };

 /* Compute the number of bits in the given unsigned type. */
 template <class T> struct BitSize {
     static const size_t result = sizeof(T) * JS_BITS_PER_BYTE;
 };

 /*
  * Produce an N-bit mask, where N <= BitSize<size_t>::result.  Handle the
  * language-undefined edge case when N = BitSize<size_t>::result.
  */
 template <size_t N> struct NBitMask {
     // Assert the precondition.  On success this evaluates to 0.  Otherwise it
     // triggers divide-by-zero at compile time: a guaranteed compile error in
     // C++11, and usually one in C++98.  Add this value to |result| to assure
     // its computation.
     static const size_t checkPrecondition = 0 / size_t(N < BitSize<size_t>::result);
     static const size_t result = (size_t(1) << N) - 1 + checkPrecondition;
 };
 template <> struct NBitMask<BitSize<size_t>::result> {
     static const size_t result = size_t(-1);
 };

 /*
  * For the unsigned integral type size_t, compute a mask M for N such that
  * for all X, !(X & M) implies X * N will not overflow (w.r.t size_t)
  */
 template <size_t N> struct MulOverflowMask {
     static const size_t result =
         ~NBitMask<BitSize<size_t>::result - CeilingLog2<N>::result>::result;
 };
 template <> struct MulOverflowMask<0> { /* Error */ };
 template <> struct MulOverflowMask<1> { static const size_t result = 0; };

 /*
  * Generate a mask for T such that if (X & sUnsafeRangeSizeMask), an X-sized
  * array of T's is big enough to cause a ptrdiff_t overflow when subtracting
  * a pointer to the end of the array from the beginning.
  */
 template <class T> struct UnsafeRangeSizeMask {
     /*
      * The '2' factor means the top bit is clear, sizeof(T) converts from
      * units of elements to bytes.
      */
     static const size_t result = MulOverflowMask<2 * sizeof(T)>::result;
 };

 template <bool cond, typename T, T v1, T v2> struct If        { static const T result = v1; };
 template <typename T, T v1, T v2> struct If<false, T, v1, v2> { static const T result = v2; };

 /*
  * Traits class for identifying types that are implicitly barriered.
  */
 template <class T> struct IsRelocatableHeapType { static const bool result = true; };

 } /* namespace tl */
 } /* namespace js */

 #endif  /* js_TemplateLib_h */
	/* -- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 4 --
	* vim: set ts=8 sts=4 et sw=4 tw=99:
	* This Source Code Form is subject to the terms of the Mozilla Public
	* License, v. 2.0. If a copy of the MPL was not distributed with this
	* file, You can obtain one at http://mozilla.org/MPL/2.0/. */

	#ifndef js_TemplateLib_h
	#define js_TemplateLib_h

	#include "jstypes.h"

	/*
	* Library of reusable template meta-functions (that is, functions on types and
	* compile-time values). Meta-functions are placed inside the 'tl' namespace to
	* avoid conflict with non-meta functions that logically have the same name
	* (e.g., js::tl::Min vs. js::Min).
	*/

	namespace js {
	namespace tl {

	/* Compute min/max/clamp. */
	template <size_t i, size_t j> struct Min {
	static const size_t result = i < j ? i : j;
	};
	template <size_t i, size_t j> struct Max {
	static const size_t result = i > j ? i : j;
	};
	template <size_t i, size_t min, size_t max> struct Clamp {
	static const size_t result = i < min ? min : (i > max ? max : i);
	};

	/* Compute x^y. */
	template <size_t x, size_t y> struct Pow {
	static const size_t result = x * Pow<x, y - 1>::result;
	};
	template <size_t x> struct Pow<x,0> {
	static const size_t result = 1;
	};

	/* Compute floor(log2(i)). */
	template <size_t i> struct FloorLog2 {
	static const size_t result = 1 + FloorLog2<i / 2>::result;
	};
	template <> struct FloorLog2<0> { /* Error */ };
	template <> struct FloorLog2<1> { static const size_t result = 0; };

	/* Compute ceiling(log2(i)). */
	template <size_t i> struct CeilingLog2 {
	static const size_t result = FloorLog2<2 * i - 1>::result;
	};

	/* Round up to the nearest power of 2. */
	template <size_t i> struct RoundUpPow2 {
	static const size_t result = size_t(1) << CeilingLog2<i>::result;
	};
	template <> struct RoundUpPow2<0> {
	static const size_t result = 1;
	};

	/* Compute the number of bits in the given unsigned type. */
	template <class T> struct BitSize {
	static const size_t result = sizeof(T) * JS_BITS_PER_BYTE;
	};

	/*
	* Produce an N-bit mask, where N <= BitSize<size_t>::result. Handle the
	* language-undefined edge case when N = BitSize<size_t>::result.
	*/
	template <size_t N> struct NBitMask {
	// Assert the precondition. On success this evaluates to 0. Otherwise it
	// triggers divide-by-zero at compile time: a guaranteed compile error in
	// C++11, and usually one in C++98. Add this value to \|result\| to assure
	// its computation.
	static const size_t checkPrecondition = 0 / size_t(N < BitSize<size_t>::result);
	static const size_t result = (size_t(1) << N) - 1 + checkPrecondition;
	};
	template <> struct NBitMask<BitSize<size_t>::result> {
	static const size_t result = size_t(-1);
	};

	/*
	* For the unsigned integral type size_t, compute a mask M for N such that
	* for all X, !(X & M) implies X * N will not overflow (w.r.t size_t)
	*/
	template <size_t N> struct MulOverflowMask {
	static const size_t result =
	~NBitMask<BitSize<size_t>::result - CeilingLog2<N>::result>::result;
	};
	template <> struct MulOverflowMask<0> { /* Error */ };
	template <> struct MulOverflowMask<1> { static const size_t result = 0; };

	/*
	* Generate a mask for T such that if (X & sUnsafeRangeSizeMask), an X-sized
	* array of T's is big enough to cause a ptrdiff_t overflow when subtracting
	* a pointer to the end of the array from the beginning.
	*/
	template <class T> struct UnsafeRangeSizeMask {
	/*
	* The '2' factor means the top bit is clear, sizeof(T) converts from
	* units of elements to bytes.
	*/
	static const size_t result = MulOverflowMask<2 * sizeof(T)>::result;
	};

	template <bool cond, typename T, T v1, T v2> struct If { static const T result = v1; };
	template <typename T, T v1, T v2> struct If<false, T, v1, v2> { static const T result = v2; };

	/*
	* Traits class for identifying types that are implicitly barriered.
	*/
	template <class T> struct IsRelocatableHeapType { static const bool result = true; };

	} /* namespace tl */
	} /* namespace js */

	#endif /* js_TemplateLib_h */