src/third_party/icu/source/common/cmemory.h - cobalt - Git at Google

 /*
 ******************************************************************************
 *
 *   Copyright (C) 1997-2015, International Business Machines
 *   Corporation and others.  All Rights Reserved.
 *
 ******************************************************************************
 *
 * File CMEMORY.H
 *
 *  Contains stdlib.h/string.h memory functions
 *
 * @author       Bertrand A. Damiba
 *
 * Modification History:
 *
 *   Date        Name        Description
 *   6/20/98     Bertrand    Created.
 *  05/03/99     stephen     Changed from functions to macros.
 *
 ******************************************************************************
 */

 #ifndef CMEMORY_H
 #define CMEMORY_H

 #include "unicode/utypes.h"

 #if !defined(STARBOARD)
 #include <stddef.h>
 #include <string.h>
 #endif
 #include "unicode/localpointer.h"

 #if U_DEBUG && defined(UPRV_MALLOC_COUNT)
 #include <stdio.h>
 #endif

 #if U_DEBUG

 /*
  * The C++ standard requires that the source pointer for memcpy() & memmove()
  * is valid, not NULL, and not at the end of an allocated memory block.
  * In debug mode, we read one byte from the source point to verify that it's
  * a valid, readable pointer.
  */

 U_CAPI void uprv_checkValidMemory(const void *p, size_t n);

 #define uprv_memcpy(dst, src, size) ( \
     uprv_checkValidMemory(src, 1), \
     U_STANDARD_CPP_NAMESPACE memcpy(dst, src, size))
 #define uprv_memmove(dst, src, size) ( \
     uprv_checkValidMemory(src, 1), \
     U_STANDARD_CPP_NAMESPACE memmove(dst, src, size))

 #else

 #define uprv_memcpy(dst, src, size) U_STANDARD_CPP_NAMESPACE memcpy(dst, src, size)
 #define uprv_memmove(dst, src, size) U_STANDARD_CPP_NAMESPACE memmove(dst, src, size)

 #endif  /* U_DEBUG */

 /**
  * \def UPRV_LENGTHOF
  * Convenience macro to determine the length of a fixed array at compile-time.
  * @param array A fixed length array
  * @return The length of the array, in elements
  * @internal
  */
 #define UPRV_LENGTHOF(array) (int32_t)(sizeof(array)/sizeof((array)[0]))
 #define uprv_memset(buffer, mark, size) U_STANDARD_CPP_NAMESPACE memset(buffer, mark, size)
 #define uprv_memcmp(buffer1, buffer2, size) U_STANDARD_CPP_NAMESPACE memcmp(buffer1, buffer2,size)

 U_CAPI void * U_EXPORT2
 uprv_malloc(size_t s) U_MALLOC_ATTR U_ALLOC_SIZE_ATTR(1);

 U_CAPI void * U_EXPORT2
 uprv_realloc(void *mem, size_t size) U_ALLOC_SIZE_ATTR(2);

 U_CAPI void U_EXPORT2
 uprv_free(void *mem);

 U_CAPI void * U_EXPORT2
 uprv_calloc(size_t num, size_t size) U_MALLOC_ATTR U_ALLOC_SIZE_ATTR2(1,2);

 /**
  * This should align the memory properly on any machine.
  * This is very useful for the safeClone functions.
  */
 typedef union {
     long    t1;
     double  t2;
     void   *t3;
 } UAlignedMemory;

 /**
  * Get the least significant bits of a pointer (a memory address).
  * For example, with a mask of 3, the macro gets the 2 least significant bits,
  * which will be 0 if the pointer is 32-bit (4-byte) aligned.
  *
  * ptrdiff_t is the most appropriate integer type to cast to.
  * size_t should work too, since on most (or all?) platforms it has the same
  * width as ptrdiff_t.
  */
 #define U_POINTER_MASK_LSB(ptr, mask) (((ptrdiff_t)(char *)(ptr)) & (mask))

 /**
  * Get the amount of bytes that a pointer is off by from
  * the previous UAlignedMemory-aligned pointer.
  */
 #define U_ALIGNMENT_OFFSET(ptr) U_POINTER_MASK_LSB(ptr, sizeof(UAlignedMemory) - 1)

 /**
  * Get the amount of bytes to add to a pointer
  * in order to get the next UAlignedMemory-aligned address.
  */
 #define U_ALIGNMENT_OFFSET_UP(ptr) (sizeof(UAlignedMemory) - U_ALIGNMENT_OFFSET(ptr))

 /**
   *  Heap clean up function, called from u_cleanup()
   *    Clears any user heap functions from u_setMemoryFunctions()
   *    Does NOT deallocate any remaining allocated memory.
   */
 U_CFUNC UBool
 cmemory_cleanup(void);

 /**
  * A function called by <TT>uhash_remove</TT>,
  * <TT>uhash_close</TT>, or <TT>uhash_put</TT> to delete
  * an existing key or value.
  * @param obj A key or value stored in a hashtable
  * @see uprv_deleteUObject
  */
 typedef void U_CALLCONV UObjectDeleter(void* obj);

 /**
  * Deleter for UObject instances.
  * Works for all subclasses of UObject because it has a virtual destructor.
  */
 U_CAPI void U_EXPORT2
 uprv_deleteUObject(void *obj);

 #ifdef __cplusplus

 U_NAMESPACE_BEGIN

 /**
  * "Smart pointer" class, deletes memory via uprv_free().
  * For most methods see the LocalPointerBase base class.
  * Adds operator[] for array item access.
  *
  * @see LocalPointerBase
  */
 template<typename T>
 class LocalMemory : public LocalPointerBase<T> {
 public:
     /**
      * Constructor takes ownership.
      * @param p simple pointer to an array of T items that is adopted
      */
     explicit LocalMemory(T *p=NULL) : LocalPointerBase<T>(p) {}
 #if U_HAVE_RVALUE_REFERENCES
     /**
      * Move constructor, leaves src with isNull().
      * @param src source smart pointer
      */
     LocalMemory(LocalMemory<T> &&src) U_NOEXCEPT : LocalPointerBase<T>(src.ptr) {
         src.ptr=NULL;
     }
 #endif
     /**
      * Destructor deletes the memory it owns.
      */
     ~LocalMemory() {
         uprv_free(LocalPointerBase<T>::ptr);
     }
 #if U_HAVE_RVALUE_REFERENCES
     /**
      * Move assignment operator, leaves src with isNull().
      * The behavior is undefined if *this and src are the same object.
      * @param src source smart pointer
      * @return *this
      */
     LocalMemory<T> &operator=(LocalMemory<T> &&src) U_NOEXCEPT {
         return moveFrom(src);
     }
 #endif
     /**
      * Move assignment, leaves src with isNull().
      * The behavior is undefined if *this and src are the same object.
      *
      * Can be called explicitly, does not need C++11 support.
      * @param src source smart pointer
      * @return *this
      */
     LocalMemory<T> &moveFrom(LocalMemory<T> &src) U_NOEXCEPT {
         delete[] LocalPointerBase<T>::ptr;
         LocalPointerBase<T>::ptr=src.ptr;
         src.ptr=NULL;
         return *this;
     }
     /**
      * Swap pointers.
      * @param other other smart pointer
      */
     void swap(LocalMemory<T> &other) U_NOEXCEPT {
         T *temp=LocalPointerBase<T>::ptr;
         LocalPointerBase<T>::ptr=other.ptr;
         other.ptr=temp;
     }
     /**
      * Non-member LocalMemory swap function.
      * @param p1 will get p2's pointer
      * @param p2 will get p1's pointer
      */
     friend inline void swap(LocalMemory<T> &p1, LocalMemory<T> &p2) U_NOEXCEPT {
         p1.swap(p2);
     }
     /**
      * Deletes the array it owns,
      * and adopts (takes ownership of) the one passed in.
      * @param p simple pointer to an array of T items that is adopted
      */
     void adoptInstead(T *p) {
         uprv_free(LocalPointerBase<T>::ptr);
         LocalPointerBase<T>::ptr=p;
     }
     /**
      * Deletes the array it owns, allocates a new one and reset its bytes to 0.
      * Returns the new array pointer.
      * If the allocation fails, then the current array is unchanged and
      * this method returns NULL.
      * @param newCapacity must be >0
      * @return the allocated array pointer, or NULL if the allocation failed
      */
     inline T *allocateInsteadAndReset(int32_t newCapacity=1);
     /**
      * Deletes the array it owns and allocates a new one, copying length T items.
      * Returns the new array pointer.
      * If the allocation fails, then the current array is unchanged and
      * this method returns NULL.
      * @param newCapacity must be >0
      * @param length number of T items to be copied from the old array to the new one;
      *               must be no more than the capacity of the old array,
      *               which the caller must track because the LocalMemory does not track it
      * @return the allocated array pointer, or NULL if the allocation failed
      */
     inline T *allocateInsteadAndCopy(int32_t newCapacity=1, int32_t length=0);
     /**
      * Array item access (writable).
      * No index bounds check.
      * @param i array index
      * @return reference to the array item
      */
     T &operator[](ptrdiff_t i) const { return LocalPointerBase<T>::ptr[i]; }
 };

 template<typename T>
 inline T *LocalMemory<T>::allocateInsteadAndReset(int32_t newCapacity) {
     if(newCapacity>0) {
         T *p=(T *)uprv_malloc(newCapacity*sizeof(T));
         if(p!=NULL) {
             uprv_memset(p, 0, newCapacity*sizeof(T));
             uprv_free(LocalPointerBase<T>::ptr);
             LocalPointerBase<T>::ptr=p;
         }
         return p;
     } else {
         return NULL;
     }
 }


 template<typename T>
 inline T *LocalMemory<T>::allocateInsteadAndCopy(int32_t newCapacity, int32_t length) {
     if(newCapacity>0) {
         T *p=(T *)uprv_malloc(newCapacity*sizeof(T));
         if(p!=NULL) {
             if(length>0) {
                 if(length>newCapacity) {
                     length=newCapacity;
                 }
                 uprv_memcpy(p, LocalPointerBase<T>::ptr, length*sizeof(T));
             }
             uprv_free(LocalPointerBase<T>::ptr);
             LocalPointerBase<T>::ptr=p;
         }
         return p;
     } else {
         return NULL;
     }
 }

 /**
  * Simple array/buffer management class using uprv_malloc() and uprv_free().
  * Provides an internal array with fixed capacity. Can alias another array
  * or allocate one.
  *
  * The array address is properly aligned for type T. It might not be properly
  * aligned for types larger than T (or larger than the largest subtype of T).
  *
  * Unlike LocalMemory and LocalArray, this class never adopts
  * (takes ownership of) another array.
  */
 template<typename T, int32_t stackCapacity>
 class MaybeStackArray {
 public:
     /**
      * Default constructor initializes with internal T[stackCapacity] buffer.
      */
     MaybeStackArray() : ptr(stackArray), capacity(stackCapacity), needToRelease(FALSE) {}
     /**
      * Destructor deletes the array (if owned).
      */
     ~MaybeStackArray() { releaseArray(); }
     /**
      * Returns the array capacity (number of T items).
      * @return array capacity
      */
     int32_t getCapacity() const { return capacity; }
     /**
      * Access without ownership change.
      * @return the array pointer
      */
     T *getAlias() const { return ptr; }
     /**
      * Returns the array limit. Simple convenience method.
      * @return getAlias()+getCapacity()
      */
     T *getArrayLimit() const { return getAlias()+capacity; }
     // No "operator T *() const" because that can make
     // expressions like mbs[index] ambiguous for some compilers.
     /**
      * Array item access (const).
      * No index bounds check.
      * @param i array index
      * @return reference to the array item
      */
     const T &operator[](ptrdiff_t i) const { return ptr[i]; }
     /**
      * Array item access (writable).
      * No index bounds check.
      * @param i array index
      * @return reference to the array item
      */
     T &operator[](ptrdiff_t i) { return ptr[i]; }
     /**
      * Deletes the array (if owned) and aliases another one, no transfer of ownership.
      * If the arguments are illegal, then the current array is unchanged.
      * @param otherArray must not be NULL
      * @param otherCapacity must be >0
      */
     void aliasInstead(T *otherArray, int32_t otherCapacity) {
         if(otherArray!=NULL && otherCapacity>0) {
             releaseArray();
             ptr=otherArray;
             capacity=otherCapacity;
             needToRelease=FALSE;
         }
     }
     /**
      * Deletes the array (if owned) and allocates a new one, copying length T items.
      * Returns the new array pointer.
      * If the allocation fails, then the current array is unchanged and
      * this method returns NULL.
      * @param newCapacity can be less than or greater than the current capacity;
      *                    must be >0
      * @param length number of T items to be copied from the old array to the new one
      * @return the allocated array pointer, or NULL if the allocation failed
      */
     inline T *resize(int32_t newCapacity, int32_t length=0);
     /**
      * Gives up ownership of the array if owned, or else clones it,
      * copying length T items; resets itself to the internal stack array.
      * Returns NULL if the allocation failed.
      * @param length number of T items to copy when cloning,
      *        and capacity of the clone when cloning
      * @param resultCapacity will be set to the returned array's capacity (output-only)
      * @return the array pointer;
      *         caller becomes responsible for deleting the array
      */
     inline T *orphanOrClone(int32_t length, int32_t &resultCapacity);
 private:
     T *ptr;
     int32_t capacity;
     UBool needToRelease;
     T stackArray[stackCapacity];
     void releaseArray() {
         if(needToRelease) {
             uprv_free(ptr);
         }
     }
     /* No comparison operators with other MaybeStackArray's. */
     bool operator==(const MaybeStackArray & /*other*/) {return FALSE;}
     bool operator!=(const MaybeStackArray & /*other*/) {return TRUE;}
     /* No ownership transfer: No copy constructor, no assignment operator. */
     MaybeStackArray(const MaybeStackArray & /*other*/) {}
     void operator=(const MaybeStackArray & /*other*/) {}

     // No heap allocation. Use only on the stack.
     //   (Declaring these functions private triggers a cascade of problems:
     //      MSVC insists on exporting an instantiation of MaybeStackArray, which
     //      requires that all functions be defined.
     //      An empty implementation of new() is rejected, it must return a value.
     //      Returning NULL is rejected by gcc for operator new.
     //      The expedient thing is just not to override operator new.
     //      While relatively pointless, heap allocated instances will function.
     // static void * U_EXPORT2 operator new(size_t size);
     // static void * U_EXPORT2 operator new[](size_t size);
 #if U_HAVE_PLACEMENT_NEW
     // static void * U_EXPORT2 operator new(size_t, void *ptr);
 #endif
 };

 template<typename T, int32_t stackCapacity>
 inline T *MaybeStackArray<T, stackCapacity>::resize(int32_t newCapacity, int32_t length) {
     if(newCapacity>0) {
 #if U_DEBUG && defined(UPRV_MALLOC_COUNT)
       ::fprintf(::stderr,"MaybeStacArray (resize) alloc %d * %lu\n", newCapacity,sizeof(T));
 #endif
         T *p=(T *)uprv_malloc(newCapacity*sizeof(T));
         if(p!=NULL) {
             if(length>0) {
                 if(length>capacity) {
                     length=capacity;
                 }
                 if(length>newCapacity) {
                     length=newCapacity;
                 }
                 uprv_memcpy(p, ptr, length*sizeof(T));
             }
             releaseArray();
             ptr=p;
             capacity=newCapacity;
             needToRelease=TRUE;
         }
         return p;
     } else {
         return NULL;
     }
 }

 template<typename T, int32_t stackCapacity>
 inline T *MaybeStackArray<T, stackCapacity>::orphanOrClone(int32_t length, int32_t &resultCapacity) {
     T *p;
     if(needToRelease) {
         p=ptr;
     } else if(length<=0) {
         return NULL;
     } else {
         if(length>capacity) {
             length=capacity;
         }
         p=(T *)uprv_malloc(length*sizeof(T));
 #if U_DEBUG && defined(UPRV_MALLOC_COUNT)
       ::fprintf(::stderr,"MaybeStacArray (orphan) alloc %d * %lu\n", length,sizeof(T));
 #endif
         if(p==NULL) {
             return NULL;
         }
         uprv_memcpy(p, ptr, length*sizeof(T));
     }
     resultCapacity=length;
     ptr=stackArray;
     capacity=stackCapacity;
     needToRelease=FALSE;
     return p;
 }

 /**
  * Variant of MaybeStackArray that allocates a header struct and an array
  * in one contiguous memory block, using uprv_malloc() and uprv_free().
  * Provides internal memory with fixed array capacity. Can alias another memory
  * block or allocate one.
  * The stackCapacity is the number of T items in the internal memory,
  * not counting the H header.
  * Unlike LocalMemory and LocalArray, this class never adopts
  * (takes ownership of) another memory block.
  */
 template<typename H, typename T, int32_t stackCapacity>
 class MaybeStackHeaderAndArray {
 public:
     /**
      * Default constructor initializes with internal H+T[stackCapacity] buffer.
      */
     MaybeStackHeaderAndArray() : ptr(&stackHeader), capacity(stackCapacity), needToRelease(FALSE) {}
     /**
      * Destructor deletes the memory (if owned).
      */
     ~MaybeStackHeaderAndArray() { releaseMemory(); }
     /**
      * Returns the array capacity (number of T items).
      * @return array capacity
      */
     int32_t getCapacity() const { return capacity; }
     /**
      * Access without ownership change.
      * @return the header pointer
      */
     H *getAlias() const { return ptr; }
     /**
      * Returns the array start.
      * @return array start, same address as getAlias()+1
      */
     T *getArrayStart() const { return reinterpret_cast<T *>(getAlias()+1); }
     /**
      * Returns the array limit.
      * @return array limit
      */
     T *getArrayLimit() const { return getArrayStart()+capacity; }
     /**
      * Access without ownership change. Same as getAlias().
      * A class instance can be used directly in expressions that take a T *.
      * @return the header pointer
      */
     operator H *() const { return ptr; }
     /**
      * Array item access (writable).
      * No index bounds check.
      * @param i array index
      * @return reference to the array item
      */
     T &operator[](ptrdiff_t i) { return getArrayStart()[i]; }
     /**
      * Deletes the memory block (if owned) and aliases another one, no transfer of ownership.
      * If the arguments are illegal, then the current memory is unchanged.
      * @param otherArray must not be NULL
      * @param otherCapacity must be >0
      */
     void aliasInstead(H *otherMemory, int32_t otherCapacity) {
         if(otherMemory!=NULL && otherCapacity>0) {
             releaseMemory();
             ptr=otherMemory;
             capacity=otherCapacity;
             needToRelease=FALSE;
         }
     }
     /**
      * Deletes the memory block (if owned) and allocates a new one,
      * copying the header and length T array items.
      * Returns the new header pointer.
      * If the allocation fails, then the current memory is unchanged and
      * this method returns NULL.
      * @param newCapacity can be less than or greater than the current capacity;
      *                    must be >0
      * @param length number of T items to be copied from the old array to the new one
      * @return the allocated pointer, or NULL if the allocation failed
      */
     inline H *resize(int32_t newCapacity, int32_t length=0);
     /**
      * Gives up ownership of the memory if owned, or else clones it,
      * copying the header and length T array items; resets itself to the internal memory.
      * Returns NULL if the allocation failed.
      * @param length number of T items to copy when cloning,
      *        and array capacity of the clone when cloning
      * @param resultCapacity will be set to the returned array's capacity (output-only)
      * @return the header pointer;
      *         caller becomes responsible for deleting the array
      */
     inline H *orphanOrClone(int32_t length, int32_t &resultCapacity);
 private:
     H *ptr;
     int32_t capacity;
     UBool needToRelease;
     // stackHeader must precede stackArray immediately.
     H stackHeader;
     T stackArray[stackCapacity];
     void releaseMemory() {
         if(needToRelease) {
             uprv_free(ptr);
         }
     }
     /* No comparison operators with other MaybeStackHeaderAndArray's. */
     bool operator==(const MaybeStackHeaderAndArray & /*other*/) {return FALSE;}
     bool operator!=(const MaybeStackHeaderAndArray & /*other*/) {return TRUE;}
     /* No ownership transfer: No copy constructor, no assignment operator. */
     MaybeStackHeaderAndArray(const MaybeStackHeaderAndArray & /*other*/) {}
     void operator=(const MaybeStackHeaderAndArray & /*other*/) {}

     // No heap allocation. Use only on the stack.
     //   (Declaring these functions private triggers a cascade of problems;
     //    see the MaybeStackArray class for details.)
     // static void * U_EXPORT2 operator new(size_t size);
     // static void * U_EXPORT2 operator new[](size_t size);
 #if U_HAVE_PLACEMENT_NEW
     // static void * U_EXPORT2 operator new(size_t, void *ptr);
 #endif
 };

 template<typename H, typename T, int32_t stackCapacity>
 inline H *MaybeStackHeaderAndArray<H, T, stackCapacity>::resize(int32_t newCapacity,
                                                                 int32_t length) {
     if(newCapacity>=0) {
 #if U_DEBUG && defined(UPRV_MALLOC_COUNT)
       ::fprintf(::stderr,"MaybeStackHeaderAndArray alloc %d + %d * %ul\n", sizeof(H),newCapacity,sizeof(T));
 #endif
         H *p=(H *)uprv_malloc(sizeof(H)+newCapacity*sizeof(T));
         if(p!=NULL) {
             if(length<0) {
                 length=0;
             } else if(length>0) {
                 if(length>capacity) {
                     length=capacity;
                 }
                 if(length>newCapacity) {
                     length=newCapacity;
                 }
             }
             uprv_memcpy(p, ptr, sizeof(H)+length*sizeof(T));
             releaseMemory();
             ptr=p;
             capacity=newCapacity;
             needToRelease=TRUE;
         }
         return p;
     } else {
         return NULL;
     }
 }

 template<typename H, typename T, int32_t stackCapacity>
 inline H *MaybeStackHeaderAndArray<H, T, stackCapacity>::orphanOrClone(int32_t length,
                                                                        int32_t &resultCapacity) {
     H *p;
     if(needToRelease) {
         p=ptr;
     } else {
         if(length<0) {
             length=0;
         } else if(length>capacity) {
             length=capacity;
         }
 #if U_DEBUG && defined(UPRV_MALLOC_COUNT)
       ::fprintf(::stderr,"MaybeStackHeaderAndArray (orphan) alloc %ul + %d * %lu\n", sizeof(H),length,sizeof(T));
 #endif
         p=(H *)uprv_malloc(sizeof(H)+length*sizeof(T));
         if(p==NULL) {
             return NULL;
         }
         uprv_memcpy(p, ptr, sizeof(H)+length*sizeof(T));
     }
     resultCapacity=length;
     ptr=&stackHeader;
     capacity=stackCapacity;
     needToRelease=FALSE;
     return p;
 }

 U_NAMESPACE_END

 #endif  /* __cplusplus */
 #endif  /* CMEMORY_H */
	/*
	******************************************************************************
	*
	* Copyright (C) 1997-2015, International Business Machines
	* Corporation and others. All Rights Reserved.
	*
	******************************************************************************
	*
	* File CMEMORY.H
	*
	* Contains stdlib.h/string.h memory functions
	*
	* @author Bertrand A. Damiba
	*
	* Modification History:
	*
	* Date Name Description
	* 6/20/98 Bertrand Created.
	* 05/03/99 stephen Changed from functions to macros.
	*
	******************************************************************************
	*/

	#ifndef CMEMORY_H
	#define CMEMORY_H

	#include "unicode/utypes.h"

	#if !defined(STARBOARD)
	#include <stddef.h>
	#include <string.h>
	#endif
	#include "unicode/localpointer.h"

	#if U_DEBUG && defined(UPRV_MALLOC_COUNT)
	#include <stdio.h>
	#endif

	#if U_DEBUG

	/*
	* The C++ standard requires that the source pointer for memcpy() & memmove()
	* is valid, not NULL, and not at the end of an allocated memory block.
	* In debug mode, we read one byte from the source point to verify that it's
	* a valid, readable pointer.
	*/

	U_CAPI void uprv_checkValidMemory(const void *p, size_t n);

	#define uprv_memcpy(dst, src, size) ( \
	uprv_checkValidMemory(src, 1), \
	U_STANDARD_CPP_NAMESPACE memcpy(dst, src, size))
	#define uprv_memmove(dst, src, size) ( \
	uprv_checkValidMemory(src, 1), \
	U_STANDARD_CPP_NAMESPACE memmove(dst, src, size))

	#else

	#define uprv_memcpy(dst, src, size) U_STANDARD_CPP_NAMESPACE memcpy(dst, src, size)
	#define uprv_memmove(dst, src, size) U_STANDARD_CPP_NAMESPACE memmove(dst, src, size)

	#endif /* U_DEBUG */

	/**
	* \def UPRV_LENGTHOF
	* Convenience macro to determine the length of a fixed array at compile-time.
	* @param array A fixed length array
	* @return The length of the array, in elements
	* @internal
	*/
	#define UPRV_LENGTHOF(array) (int32_t)(sizeof(array)/sizeof((array)[0]))
	#define uprv_memset(buffer, mark, size) U_STANDARD_CPP_NAMESPACE memset(buffer, mark, size)
	#define uprv_memcmp(buffer1, buffer2, size) U_STANDARD_CPP_NAMESPACE memcmp(buffer1, buffer2,size)

	U_CAPI void * U_EXPORT2
	uprv_malloc(size_t s) U_MALLOC_ATTR U_ALLOC_SIZE_ATTR(1);

	U_CAPI void * U_EXPORT2
	uprv_realloc(void *mem, size_t size) U_ALLOC_SIZE_ATTR(2);

	U_CAPI void U_EXPORT2
	uprv_free(void *mem);

	U_CAPI void * U_EXPORT2
	uprv_calloc(size_t num, size_t size) U_MALLOC_ATTR U_ALLOC_SIZE_ATTR2(1,2);

	/**
	* This should align the memory properly on any machine.
	* This is very useful for the safeClone functions.
	*/
	typedef union {
	long t1;
	double t2;
	void *t3;
	} UAlignedMemory;

	/**
	* Get the least significant bits of a pointer (a memory address).
	* For example, with a mask of 3, the macro gets the 2 least significant bits,
	* which will be 0 if the pointer is 32-bit (4-byte) aligned.
	*
	* ptrdiff_t is the most appropriate integer type to cast to.
	* size_t should work too, since on most (or all?) platforms it has the same
	* width as ptrdiff_t.
	*/
	#define U_POINTER_MASK_LSB(ptr, mask) (((ptrdiff_t)(char *)(ptr)) & (mask))

	/**
	* Get the amount of bytes that a pointer is off by from
	* the previous UAlignedMemory-aligned pointer.
	*/
	#define U_ALIGNMENT_OFFSET(ptr) U_POINTER_MASK_LSB(ptr, sizeof(UAlignedMemory) - 1)

	/**
	* Get the amount of bytes to add to a pointer
	* in order to get the next UAlignedMemory-aligned address.
	*/
	#define U_ALIGNMENT_OFFSET_UP(ptr) (sizeof(UAlignedMemory) - U_ALIGNMENT_OFFSET(ptr))

	/**
	* Heap clean up function, called from u_cleanup()
	* Clears any user heap functions from u_setMemoryFunctions()
	* Does NOT deallocate any remaining allocated memory.
	*/
	U_CFUNC UBool
	cmemory_cleanup(void);

	/**
	* A function called by <TT>uhash_remove</TT>,
	* <TT>uhash_close</TT>, or <TT>uhash_put</TT> to delete
	* an existing key or value.
	* @param obj A key or value stored in a hashtable
	* @see uprv_deleteUObject
	*/
	typedef void U_CALLCONV UObjectDeleter(void* obj);

	/**
	* Deleter for UObject instances.
	* Works for all subclasses of UObject because it has a virtual destructor.
	*/
	U_CAPI void U_EXPORT2
	uprv_deleteUObject(void *obj);

	#ifdef __cplusplus

	U_NAMESPACE_BEGIN

	/**
	* "Smart pointer" class, deletes memory via uprv_free().
	* For most methods see the LocalPointerBase base class.
	* Adds operator[] for array item access.
	*
	* @see LocalPointerBase
	*/
	template<typename T>
	class LocalMemory : public LocalPointerBase<T> {
	public:
	/**
	* Constructor takes ownership.
	* @param p simple pointer to an array of T items that is adopted
	*/
	explicit LocalMemory(T *p=NULL) : LocalPointerBase<T>(p) {}
	#if U_HAVE_RVALUE_REFERENCES
	/**
	* Move constructor, leaves src with isNull().
	* @param src source smart pointer
	*/
	LocalMemory(LocalMemory<T> &&src) U_NOEXCEPT : LocalPointerBase<T>(src.ptr) {
	src.ptr=NULL;
	}
	#endif
	/**
	* Destructor deletes the memory it owns.
	*/
	~LocalMemory() {
	uprv_free(LocalPointerBase<T>::ptr);
	}
	#if U_HAVE_RVALUE_REFERENCES
	/**
	* Move assignment operator, leaves src with isNull().
	* The behavior is undefined if *this and src are the same object.
	* @param src source smart pointer
	* @return *this
	*/
	LocalMemory<T> &operator=(LocalMemory<T> &&src) U_NOEXCEPT {
	return moveFrom(src);
	}
	#endif
	/**
	* Move assignment, leaves src with isNull().
	* The behavior is undefined if *this and src are the same object.
	*
	* Can be called explicitly, does not need C++11 support.
	* @param src source smart pointer
	* @return *this
	*/
	LocalMemory<T> &moveFrom(LocalMemory<T> &src) U_NOEXCEPT {
	delete[] LocalPointerBase<T>::ptr;
	LocalPointerBase<T>::ptr=src.ptr;
	src.ptr=NULL;
	return *this;
	}
	/**
	* Swap pointers.
	* @param other other smart pointer
	*/
	void swap(LocalMemory<T> &other) U_NOEXCEPT {
	T *temp=LocalPointerBase<T>::ptr;
	LocalPointerBase<T>::ptr=other.ptr;
	other.ptr=temp;
	}
	/**
	* Non-member LocalMemory swap function.
	* @param p1 will get p2's pointer
	* @param p2 will get p1's pointer
	*/
	friend inline void swap(LocalMemory<T> &p1, LocalMemory<T> &p2) U_NOEXCEPT {
	p1.swap(p2);
	}
	/**
	* Deletes the array it owns,
	* and adopts (takes ownership of) the one passed in.
	* @param p simple pointer to an array of T items that is adopted
	*/
	void adoptInstead(T *p) {
	uprv_free(LocalPointerBase<T>::ptr);
	LocalPointerBase<T>::ptr=p;
	}
	/**
	* Deletes the array it owns, allocates a new one and reset its bytes to 0.
	* Returns the new array pointer.
	* If the allocation fails, then the current array is unchanged and
	* this method returns NULL.
	* @param newCapacity must be >0
	* @return the allocated array pointer, or NULL if the allocation failed
	*/
	inline T *allocateInsteadAndReset(int32_t newCapacity=1);
	/**
	* Deletes the array it owns and allocates a new one, copying length T items.
	* Returns the new array pointer.
	* If the allocation fails, then the current array is unchanged and
	* this method returns NULL.
	* @param newCapacity must be >0
	* @param length number of T items to be copied from the old array to the new one;
	* must be no more than the capacity of the old array,
	* which the caller must track because the LocalMemory does not track it
	* @return the allocated array pointer, or NULL if the allocation failed
	*/
	inline T *allocateInsteadAndCopy(int32_t newCapacity=1, int32_t length=0);
	/**
	* Array item access (writable).
	* No index bounds check.
	* @param i array index
	* @return reference to the array item
	*/
	T &operator[](ptrdiff_t i) const { return LocalPointerBase<T>::ptr[i]; }
	};

	template<typename T>
	inline T *LocalMemory<T>::allocateInsteadAndReset(int32_t newCapacity) {
	if(newCapacity>0) {
	T p=(T )uprv_malloc(newCapacity*sizeof(T));
	if(p!=NULL) {
	uprv_memset(p, 0, newCapacity*sizeof(T));
	uprv_free(LocalPointerBase<T>::ptr);
	LocalPointerBase<T>::ptr=p;
	}
	return p;
	} else {
	return NULL;
	}
	}


	template<typename T>
	inline T *LocalMemory<T>::allocateInsteadAndCopy(int32_t newCapacity, int32_t length) {
	if(newCapacity>0) {
	T p=(T )uprv_malloc(newCapacity*sizeof(T));
	if(p!=NULL) {
	if(length>0) {
	if(length>newCapacity) {
	length=newCapacity;
	}
	uprv_memcpy(p, LocalPointerBase<T>::ptr, length*sizeof(T));
	}
	uprv_free(LocalPointerBase<T>::ptr);
	LocalPointerBase<T>::ptr=p;
	}
	return p;
	} else {
	return NULL;
	}
	}

	/**
	* Simple array/buffer management class using uprv_malloc() and uprv_free().
	* Provides an internal array with fixed capacity. Can alias another array
	* or allocate one.
	*
	* The array address is properly aligned for type T. It might not be properly
	* aligned for types larger than T (or larger than the largest subtype of T).
	*
	* Unlike LocalMemory and LocalArray, this class never adopts
	* (takes ownership of) another array.
	*/
	template<typename T, int32_t stackCapacity>
	class MaybeStackArray {
	public:
	/**
	* Default constructor initializes with internal T[stackCapacity] buffer.
	*/
	MaybeStackArray() : ptr(stackArray), capacity(stackCapacity), needToRelease(FALSE) {}
	/**
	* Destructor deletes the array (if owned).
	*/
	~MaybeStackArray() { releaseArray(); }
	/**
	* Returns the array capacity (number of T items).
	* @return array capacity
	*/
	int32_t getCapacity() const { return capacity; }
	/**
	* Access without ownership change.
	* @return the array pointer
	*/
	T *getAlias() const { return ptr; }
	/**
	* Returns the array limit. Simple convenience method.
	* @return getAlias()+getCapacity()
	*/
	T *getArrayLimit() const { return getAlias()+capacity; }
	// No "operator T *() const" because that can make
	// expressions like mbs[index] ambiguous for some compilers.
	/**
	* Array item access (const).
	* No index bounds check.
	* @param i array index
	* @return reference to the array item
	*/
	const T &operator[](ptrdiff_t i) const { return ptr[i]; }
	/**
	* Array item access (writable).
	* No index bounds check.
	* @param i array index
	* @return reference to the array item
	*/
	T &operator[](ptrdiff_t i) { return ptr[i]; }
	/**
	* Deletes the array (if owned) and aliases another one, no transfer of ownership.
	* If the arguments are illegal, then the current array is unchanged.
	* @param otherArray must not be NULL
	* @param otherCapacity must be >0
	*/
	void aliasInstead(T *otherArray, int32_t otherCapacity) {
	if(otherArray!=NULL && otherCapacity>0) {
	releaseArray();
	ptr=otherArray;
	capacity=otherCapacity;
	needToRelease=FALSE;
	}
	}
	/**
	* Deletes the array (if owned) and allocates a new one, copying length T items.
	* Returns the new array pointer.
	* If the allocation fails, then the current array is unchanged and
	* this method returns NULL.
	* @param newCapacity can be less than or greater than the current capacity;
	* must be >0
	* @param length number of T items to be copied from the old array to the new one
	* @return the allocated array pointer, or NULL if the allocation failed
	*/
	inline T *resize(int32_t newCapacity, int32_t length=0);
	/**
	* Gives up ownership of the array if owned, or else clones it,
	* copying length T items; resets itself to the internal stack array.
	* Returns NULL if the allocation failed.
	* @param length number of T items to copy when cloning,
	* and capacity of the clone when cloning
	* @param resultCapacity will be set to the returned array's capacity (output-only)
	* @return the array pointer;
	* caller becomes responsible for deleting the array
	*/
	inline T *orphanOrClone(int32_t length, int32_t &resultCapacity);
	private:
	T *ptr;
	int32_t capacity;
	UBool needToRelease;
	T stackArray[stackCapacity];
	void releaseArray() {
	if(needToRelease) {
	uprv_free(ptr);
	}
	}
	/* No comparison operators with other MaybeStackArray's. */
	bool operator==(const MaybeStackArray & /other/) {return FALSE;}
	bool operator!=(const MaybeStackArray & /other/) {return TRUE;}
	/* No ownership transfer: No copy constructor, no assignment operator. */
	MaybeStackArray(const MaybeStackArray & /other/) {}
	void operator=(const MaybeStackArray & /other/) {}

	// No heap allocation. Use only on the stack.
	// (Declaring these functions private triggers a cascade of problems:
	// MSVC insists on exporting an instantiation of MaybeStackArray, which
	// requires that all functions be defined.
	// An empty implementation of new() is rejected, it must return a value.
	// Returning NULL is rejected by gcc for operator new.
	// The expedient thing is just not to override operator new.
	// While relatively pointless, heap allocated instances will function.
	// static void * U_EXPORT2 operator new(size_t size);
	// static void * U_EXPORT2 operator new[](size_t size);
	#if U_HAVE_PLACEMENT_NEW
	// static void * U_EXPORT2 operator new(size_t, void *ptr);
	#endif
	};

	template<typename T, int32_t stackCapacity>
	inline T *MaybeStackArray<T, stackCapacity>::resize(int32_t newCapacity, int32_t length) {
	if(newCapacity>0) {
	#if U_DEBUG && defined(UPRV_MALLOC_COUNT)
	::fprintf(::stderr,"MaybeStacArray (resize) alloc %d * %lu\n", newCapacity,sizeof(T));
	#endif
	T p=(T )uprv_malloc(newCapacity*sizeof(T));
	if(p!=NULL) {
	if(length>0) {
	if(length>capacity) {
	length=capacity;
	}
	if(length>newCapacity) {
	length=newCapacity;
	}
	uprv_memcpy(p, ptr, length*sizeof(T));
	}
	releaseArray();
	ptr=p;
	capacity=newCapacity;
	needToRelease=TRUE;
	}
	return p;
	} else {
	return NULL;
	}
	}

	template<typename T, int32_t stackCapacity>
	inline T *MaybeStackArray<T, stackCapacity>::orphanOrClone(int32_t length, int32_t &resultCapacity) {
	T *p;
	if(needToRelease) {
	p=ptr;
	} else if(length<=0) {
	return NULL;
	} else {
	if(length>capacity) {
	length=capacity;
	}
	p=(T )uprv_malloc(lengthsizeof(T));
	#if U_DEBUG && defined(UPRV_MALLOC_COUNT)
	::fprintf(::stderr,"MaybeStacArray (orphan) alloc %d * %lu\n", length,sizeof(T));
	#endif
	if(p==NULL) {
	return NULL;
	}
	uprv_memcpy(p, ptr, length*sizeof(T));
	}
	resultCapacity=length;
	ptr=stackArray;
	capacity=stackCapacity;
	needToRelease=FALSE;
	return p;
	}

	/**
	* Variant of MaybeStackArray that allocates a header struct and an array
	* in one contiguous memory block, using uprv_malloc() and uprv_free().
	* Provides internal memory with fixed array capacity. Can alias another memory
	* block or allocate one.
	* The stackCapacity is the number of T items in the internal memory,
	* not counting the H header.
	* Unlike LocalMemory and LocalArray, this class never adopts
	* (takes ownership of) another memory block.
	*/
	template<typename H, typename T, int32_t stackCapacity>
	class MaybeStackHeaderAndArray {
	public:
	/**
	* Default constructor initializes with internal H+T[stackCapacity] buffer.
	*/
	MaybeStackHeaderAndArray() : ptr(&stackHeader), capacity(stackCapacity), needToRelease(FALSE) {}
	/**
	* Destructor deletes the memory (if owned).
	*/
	~MaybeStackHeaderAndArray() { releaseMemory(); }
	/**
	* Returns the array capacity (number of T items).
	* @return array capacity
	*/
	int32_t getCapacity() const { return capacity; }
	/**
	* Access without ownership change.
	* @return the header pointer
	*/
	H *getAlias() const { return ptr; }
	/**
	* Returns the array start.
	* @return array start, same address as getAlias()+1
	*/
	T getArrayStart() const { return reinterpret_cast<T >(getAlias()+1); }
	/**
	* Returns the array limit.
	* @return array limit
	*/
	T *getArrayLimit() const { return getArrayStart()+capacity; }
	/**
	* Access without ownership change. Same as getAlias().
	* A class instance can be used directly in expressions that take a T *.
	* @return the header pointer
	*/
	operator H *() const { return ptr; }
	/**
	* Array item access (writable).
	* No index bounds check.
	* @param i array index
	* @return reference to the array item
	*/
	T &operator[](ptrdiff_t i) { return getArrayStart()[i]; }
	/**
	* Deletes the memory block (if owned) and aliases another one, no transfer of ownership.
	* If the arguments are illegal, then the current memory is unchanged.
	* @param otherArray must not be NULL
	* @param otherCapacity must be >0
	*/
	void aliasInstead(H *otherMemory, int32_t otherCapacity) {
	if(otherMemory!=NULL && otherCapacity>0) {
	releaseMemory();
	ptr=otherMemory;
	capacity=otherCapacity;
	needToRelease=FALSE;
	}
	}
	/**
	* Deletes the memory block (if owned) and allocates a new one,
	* copying the header and length T array items.
	* Returns the new header pointer.
	* If the allocation fails, then the current memory is unchanged and
	* this method returns NULL.
	* @param newCapacity can be less than or greater than the current capacity;
	* must be >0
	* @param length number of T items to be copied from the old array to the new one
	* @return the allocated pointer, or NULL if the allocation failed
	*/
	inline H *resize(int32_t newCapacity, int32_t length=0);
	/**
	* Gives up ownership of the memory if owned, or else clones it,
	* copying the header and length T array items; resets itself to the internal memory.
	* Returns NULL if the allocation failed.
	* @param length number of T items to copy when cloning,
	* and array capacity of the clone when cloning
	* @param resultCapacity will be set to the returned array's capacity (output-only)
	* @return the header pointer;
	* caller becomes responsible for deleting the array
	*/
	inline H *orphanOrClone(int32_t length, int32_t &resultCapacity);
	private:
	H *ptr;
	int32_t capacity;
	UBool needToRelease;
	// stackHeader must precede stackArray immediately.
	H stackHeader;
	T stackArray[stackCapacity];
	void releaseMemory() {
	if(needToRelease) {
	uprv_free(ptr);
	}
	}
	/* No comparison operators with other MaybeStackHeaderAndArray's. */
	bool operator==(const MaybeStackHeaderAndArray & /other/) {return FALSE;}
	bool operator!=(const MaybeStackHeaderAndArray & /other/) {return TRUE;}
	/* No ownership transfer: No copy constructor, no assignment operator. */
	MaybeStackHeaderAndArray(const MaybeStackHeaderAndArray & /other/) {}
	void operator=(const MaybeStackHeaderAndArray & /other/) {}

	// No heap allocation. Use only on the stack.
	// (Declaring these functions private triggers a cascade of problems;
	// see the MaybeStackArray class for details.)
	// static void * U_EXPORT2 operator new(size_t size);
	// static void * U_EXPORT2 operator new[](size_t size);
	#if U_HAVE_PLACEMENT_NEW
	// static void * U_EXPORT2 operator new(size_t, void *ptr);
	#endif
	};

	template<typename H, typename T, int32_t stackCapacity>
	inline H *MaybeStackHeaderAndArray<H, T, stackCapacity>::resize(int32_t newCapacity,
	int32_t length) {
	if(newCapacity>=0) {
	#if U_DEBUG && defined(UPRV_MALLOC_COUNT)
	::fprintf(::stderr,"MaybeStackHeaderAndArray alloc %d + %d * %ul\n", sizeof(H),newCapacity,sizeof(T));
	#endif
	H p=(H )uprv_malloc(sizeof(H)+newCapacity*sizeof(T));
	if(p!=NULL) {
	if(length<0) {
	length=0;
	} else if(length>0) {
	if(length>capacity) {
	length=capacity;
	}
	if(length>newCapacity) {
	length=newCapacity;
	}
	}
	uprv_memcpy(p, ptr, sizeof(H)+length*sizeof(T));
	releaseMemory();
	ptr=p;
	capacity=newCapacity;
	needToRelease=TRUE;
	}
	return p;
	} else {
	return NULL;
	}
	}

	template<typename H, typename T, int32_t stackCapacity>
	inline H *MaybeStackHeaderAndArray<H, T, stackCapacity>::orphanOrClone(int32_t length,
	int32_t &resultCapacity) {
	H *p;
	if(needToRelease) {
	p=ptr;
	} else {
	if(length<0) {
	length=0;
	} else if(length>capacity) {
	length=capacity;
	}
	#if U_DEBUG && defined(UPRV_MALLOC_COUNT)
	::fprintf(::stderr,"MaybeStackHeaderAndArray (orphan) alloc %ul + %d * %lu\n", sizeof(H),length,sizeof(T));
	#endif
	p=(H )uprv_malloc(sizeof(H)+lengthsizeof(T));
	if(p==NULL) {
	return NULL;
	}
	uprv_memcpy(p, ptr, sizeof(H)+length*sizeof(T));
	}
	resultCapacity=length;
	ptr=&stackHeader;
	capacity=stackCapacity;
	needToRelease=FALSE;
	return p;
	}

	U_NAMESPACE_END

	#endif /* __cplusplus */
	#endif /* CMEMORY_H */