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  • doc/theses/mubeen_zulfiqar_MMath/allocator.tex

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    112112
    113 \section{Added Features}
    114 
    115 
    116 \subsection{Methods}
    117 Why did we need it?
    118 The added benefits.
    119 
     113\section{Added Features and Methods}
     114To improve the UHeapLmmm allocator (FIX ME: cite uHeapLmmm) interface and make it more user friendly, we added a few more routines to the C allocator. Also, we built a CFA (FIX ME: cite cforall) interface on top of C interface to increase the usability of the allocator.
     115
     116\subsection{C Interface}
     117We added a few more features and routines to the allocator's C interface that can make the allocator more usable to the programmers. THese features will programmer more control on the dynamic memory allocation.
     118
     119\subsubsection void * aalloc( size_t dim, size_t elemSize )
     120aalloc is an extension of malloc. It allows programmer to allocate a dynamic array of objects without calculating the total size of array explicitly. The only alternate of this routine in the other allocators is calloc but calloc also fills the dynamic memory with 0 which makes it slower for a programmer who only wants to dynamically allocate an array of objects without filling it with 0.
     121\paragraph{Usage}
     122aalloc takes two parameters.
     123\begin{itemize}
     124\item
     125dim: number of objects in the array
     126\item
     127elemSize: size of the object in the array.
     128\end{itemize}
     129It returns address of dynamic object allocatoed on heap that can contain dim number of objects of the size elemSize. On failure, it returns NULL pointer.
     130
     131\subsubsection void * resize( void * oaddr, size_t size )
     132resize is an extension of relloc. It allows programmer to reuse a cuurently allocated dynamic object with a new size requirement. Its alternate in the other allocators is realloc but relloc also copy the data in old object to the new object which makes it slower for the programmer who only wants to reuse an old dynamic object for a new size requirement but does not want to preserve the data in the old object to the new object.
     133\paragraph{Usage}
     134resize takes two parameters.
     135\begin{itemize}
     136\item
     137oaddr: the address of the old object that needs to be resized.
     138\item
     139size: the new size requirement of the to which the old object needs to be resized.
     140\end{itemize}
     141It returns an object that is of the size given but it does not preserve the data in the old object. On failure, it returns NULL pointer.
     142
     143\subsubsection void * resize( void * oaddr, size_t nalign, size_t size )
     144This resize is an extension of the above resize (FIX ME: cite above resize). In addition to resizing the size of of an old object, it can also realign the old object to a new alignment requirement.
     145\paragraph{Usage}
     146This resize takes three parameters. It takes an additional parameter of nalign as compared to the above resize (FIX ME: cite above resize).
     147\begin{itemize}
     148\item
     149oaddr: the address of the old object that needs to be resized.
     150\item
     151nalign: the new alignment to which the old object needs to be realigned.
     152\item
     153size: the new size requirement of the to which the old object needs to be resized.
     154\end{itemize}
     155It returns an object with the size and alignment given in the parameters. On failure, it returns a NULL pointer.
     156
     157\subsubsection void * amemalign( size_t alignment, size_t dim, size_t elemSize )
     158amemalign is a hybrid of memalign and aalloc. It allows programmer to allocate an aligned dynamic array of objects without calculating the total size of the array explicitly. It frees the programmer from calculating the total size of the array.
     159\paragraph{Usage}
     160amemalign takes three parameters.
     161\begin{itemize}
     162\item
     163alignment: the alignment to which the dynamic array needs to be aligned.
     164\item
     165dim: number of objects in the array
     166\item
     167elemSize: size of the object in the array.
     168\end{itemize}
     169It returns a dynamic array of objects that has the capacity to contain dim number of objects of the size of elemSize. The returned dynamic array is aligned to the given alignment. On failure, it returns NULL pointer.
     170
     171\subsubsection void * cmemalign( size_t alignment, size_t dim, size_t elemSize )
     172cmemalign is a hybrid of amemalign and calloc. It allows programmer to allocate an aligned dynamic array of objects that is 0 filled. The current way to do this in other allocators is to allocate an aligned object with memalign and then fill it with 0 explicitly. This routine provides both features of aligning and 0 filling, implicitly.
     173\paragraph{Usage}
     174cmemalign takes three parameters.
     175\begin{itemize}
     176\item
     177alignment: the alignment to which the dynamic array needs to be aligned.
     178\item
     179dim: number of objects in the array
     180\item
     181elemSize: size of the object in the array.
     182\end{itemize}
     183It returns a dynamic array of objects that has the capacity to contain dim number of objects of the size of elemSize. The returned dynamic array is aligned to the given alignment and is 0 filled. On failure, it returns NULL pointer.
     184
     185\subsubsection size_t malloc_alignment( void * addr )
     186malloc_alignment returns the alignment of a currently allocated dynamic object. It allows the programmer in memory management and personal bookkeeping. It helps the programmer in verofying the alignment of a dynamic object especially in a scenerio similar to prudcer-consumer where a producer allocates a dynamic object and the consumer needs to assure that the dynamic object was allocated with the required alignment.
     187\paragraph{Usage}
     188malloc_alignment takes one parameters.
     189\begin{itemize}
     190\item
     191addr: the address of the currently allocated dynamic object.
     192\end{itemize}
     193malloc_alignment returns the alignment of the given dynamic object. On failure, it return the value of default alignment of the uHeapLmmm allocator.
     194
     195\subsubsection bool malloc_zero_fill( void * addr )
     196malloc_zero_fill returns whether a currently allocated dynamic object was initially zero filled at the time of allocation. It allows the programmer in memory management and personal bookkeeping. It helps the programmer in verifying the zero filled property of a dynamic object especially in a scenerio similar to prudcer-consumer where a producer allocates a dynamic object and the consumer needs to assure that the dynamic object was zero filled at the time of allocation.
     197\paragraph{Usage}
     198malloc_zero_fill takes one parameters.
     199\begin{itemize}
     200\item
     201addr: the address of the currently allocated dynamic object.
     202\end{itemize}
     203malloc_zero_fill returns true if the dynamic object was initially zero filled and return false otherwise. On failure, it returns false.
     204
     205\subsubsection size_t malloc_size( void * addr )
     206malloc_size returns the allocation size of a currently allocated dynamic object. It allows the programmer in memory management and personal bookkeeping. It helps the programmer in verofying the alignment of a dynamic object especially in a scenerio similar to prudcer-consumer where a producer allocates a dynamic object and the consumer needs to assure that the dynamic object was allocated with the required size. Its current alternate in the other allocators is malloc_usable_size. But, malloc_size is different from malloc_usable_size as malloc_usabe_size returns the total data capacity of dynamic object including the extra space at the end of the dynamic object. On the other hand, malloc_size returns the size that was given to the allocator at the allocation of the dynamic object. This size is updated when an object is realloced, resized, or passed through a similar allocator routine.
     207\paragraph{Usage}
     208malloc_size takes one parameters.
     209\begin{itemize}
     210\item
     211addr: the address of the currently allocated dynamic object.
     212\end{itemize}
     213malloc_size returns the allocation size of the given dynamic object. On failure, it return zero.
     214
     215\subsubsection void * realloc( void * oaddr, size_t nalign, size_t size )
     216This realloc is an extension of the default realloc (FIX ME: cite default realloc). In addition to reallocating an old object and preserving the data in old object, it can also realign the old object to a new alignment requirement.
     217\paragraph{Usage}
     218This realloc takes three parameters. It takes an additional parameter of nalign as compared to the default realloc.
     219\begin{itemize}
     220\item
     221oaddr: the address of the old object that needs to be reallocated.
     222\item
     223nalign: the new alignment to which the old object needs to be realigned.
     224\item
     225size: the new size requirement of the to which the old object needs to be resized.
     226\end{itemize}
     227It returns an object with the size and alignment given in the parameters that preserves the data in the old object. On failure, it returns a NULL pointer.
     228
     229\subsection{CFA Malloc Interface}
     230We added some routines to the malloc interface of CFA. These routines can only be used in CFA and not in our standalone uHeapLmmm allocator as these routines use some features that are only provided by CFA and not by C. It makes the allocator even more usable to the programmers.
     231CFA provides the liberty to know the returned type of a call to the allocator. So, mainly in these added routines, we removed the object size parameter from the routine as allocator can calculate the size of the object from the returned type.
     232
     233\subsubsection T * malloc( void )
     234This malloc is a simplified polymorphic form of defualt malloc (FIX ME: cite malloc). It does not take any parameter as compared to default malloc that takes one parameter.
     235\paragraph{Usage}
     236This malloc takes no parameters.
     237It returns a dynamic object of the size of type T. On failure, it return NULL pointer.
     238
     239\subsubsection T * aalloc( size_t dim )
     240This aalloc is a simplified polymorphic form of above aalloc (FIX ME: cite aalloc). It takes one parameter as compared to the above aalloc that takes two parameters.
     241\paragraph{Usage}
     242aalloc takes one parameters.
     243\begin{itemize}
     244\item
     245dim: required number of objects in the array.
     246\end{itemize}
     247It returns a dynamic object that has the capacity to contain dim number of objects, each of the size of type T. On failure, it return NULL pointer.
     248
     249\subsubsection T * calloc( size_t dim )
     250This calloc is a simplified polymorphic form of defualt calloc (FIX ME: cite calloc). It takes one parameter as compared to the default calloc that takes two parameters.
     251\paragraph{Usage}
     252This calloc takes one parameter.
     253\begin{itemize}
     254\item
     255dim: required number of objects in the array.
     256\end{itemize}
     257It returns a dynamic object that has the capacity to contain dim number of objects, each of the size of type T. On failure, it return NULL pointer.
     258
     259\subsubsection T * resize( T * ptr, size_t size )
     260This resize is a simplified polymorphic form of above resize (FIX ME: cite resize with alignment). It takes two parameters as compared to the above resize that takes three parameters. It frees the programmer from explicitly mentioning the alignment of the allocation as CFA provides gives allocator the liberty to get the alignment of the returned type.
     261\paragraph{Usage}
     262This resize takes two parameters.
     263\begin{itemize}
     264\item
     265ptr: address of the old object.
     266\item
     267size: the required size of the new object.
     268\end{itemize}
     269It returns a dynamic object of the size given in paramters. The returned object is aligned to the alignemtn of type T. On failure, it return NULL pointer.
     270
     271\subsubsection T * realloc( T * ptr, size_t size )
     272This realloc is a simplified polymorphic form of defualt realloc (FIX ME: cite realloc with align). It takes two parameters as compared to the above realloc that takes three parameters. It frees the programmer from explicitly mentioning the alignment of the allocation as CFA provides gives allocator the liberty to get the alignment of the returned type.
     273\paragraph{Usage}
     274This realloc takes two parameters.
     275\begin{itemize}
     276\item
     277ptr: address of the old object.
     278\item
     279size: the required size of the new object.
     280\end{itemize}
     281It returns a dynamic object of the size given in paramters that preserves the data in the given object. The returned object is aligned to the alignemtn of type T. On failure, it return NULL pointer.
     282
     283\subsubsection T * memalign( size_t align )
     284This memalign is a simplified polymorphic form of defualt memalign (FIX ME: cite memalign). It takes one parameters as compared to the default memalign that takes two parameters.
     285\paragraph{Usage}
     286memalign takes one parameters.
     287\begin{itemize}
     288\item
     289align: the required alignment of the dynamic object.
     290\end{itemize}
     291It returns a dynamic object of the size of type T that is aligned to given parameter align. On failure, it return NULL pointer.
     292
     293\subsubsection T * amemalign( size_t align, size_t dim )
     294This amemalign is a simplified polymorphic form of above amemalign (FIX ME: cite amemalign). It takes two parameter as compared to the above amemalign that takes three parameters.
     295\paragraph{Usage}
     296amemalign takes two parameters.
     297\begin{itemize}
     298\item
     299align: required alignment of the dynamic array.
     300\item
     301dim: required number of objects in the array.
     302\end{itemize}
     303It returns a dynamic object that has the capacity to contain dim number of objects, each of the size of type T. The returned object is aligned to the given parameter align. On failure, it return NULL pointer.
     304
     305\subsubsection T * cmemalign( size_t align, size_t dim  )
     306This cmemalign is a simplified polymorphic form of above cmemalign (FIX ME: cite cmemalign). It takes two parameter as compared to the above cmemalign that takes three parameters.
     307\paragraph{Usage}
     308cmemalign takes two parameters.
     309\begin{itemize}
     310\item
     311align: required alignment of the dynamic array.
     312\item
     313dim: required number of objects in the array.
     314\end{itemize}
     315It returns a dynamic object that has the capacity to contain dim number of objects, each of the size of type T. The returned object is aligned to the given parameter align and is zero filled. On failure, it return NULL pointer.
     316
     317\subsubsection T * aligned_alloc( size_t align )
     318This aligned_alloc is a simplified polymorphic form of defualt aligned_alloc (FIX ME: cite aligned_alloc). It takes one parameter as compared to the default aligned_alloc that takes two parameters.
     319\paragraph{Usage}
     320This aligned_alloc takes one parameter.
     321\begin{itemize}
     322\item
     323align: required alignment of the dynamic object.
     324\end{itemize}
     325It returns a dynamic object of the size of type T that is aligned to the given parameter. On failure, it return NULL pointer.
     326
     327\subsubsection int posix_memalign( T ** ptr, size_t align )
     328This posix_memalign is a simplified polymorphic form of defualt posix_memalign (FIX ME: cite posix_memalign). It takes two parameters as compared to the default posix_memalign that takes three parameters.
     329\paragraph{Usage}
     330This posix_memalign takes two parameter.
     331\begin{itemize}
     332\item
     333ptr: variable address to store the address of the allocated object.
     334\item
     335align: required alignment of the dynamic object.
     336\end{itemize}
     337It stores address of the dynamic object of the size of type T in given parameter ptr. This object is aligned to the given parameter. On failure, it return NULL pointer.
     338
     339\subsubsection T * valloc( void )
     340This valloc is a simplified polymorphic form of defualt valloc (FIX ME: cite valloc). It takes no parameters as compared to the default valloc that takes one parameter.
     341\paragraph{Usage}
     342valloc takes no parameters.
     343It returns a dynamic object of the size of type T that is aligned to the page size. On failure, it return NULL pointer.
     344
     345\subsubsection T * pvalloc( void )
     346This pcvalloc is a simplified polymorphic form of defualt pcvalloc (FIX ME: cite pcvalloc). It takes no parameters as compared to the default pcvalloc that takes one parameter.
     347\paragraph{Usage}
     348pvalloc takes no parameters.
     349It returns a dynamic object of the size that is calcutaed by rouding the size of type T. The returned object is also aligned to the page size. On failure, it return NULL pointer.
    120350
    121351\subsection{Alloc Interface}
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