source: doc/theses/mubeen_zulfiqar_MMath/intro.tex @ 41d3c8d

ADTast-experimentalenumpthread-emulationqualifiedEnum
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1\chapter{Introduction}
2
3% Shared-memory multi-processor computers are ubiquitous and important for improving application performance.
4% However, writing programs that take advantage of multiple processors is not an easy task~\cite{Alexandrescu01b}, \eg shared resources can become a bottleneck when increasing (scaling) threads.
5% One crucial shared resource is program memory, since it is used by all threads in a shared-memory concurrent-program~\cite{Berger00}.
6% Therefore, providing high-performance, scalable memory-management is important for virtually all shared-memory multi-threaded programs.
7
8\vspace*{-23pt}
9Memory management takes a sequence of program generated allocation/deallocation requests and attempts to satisfy them within a fixed-sized block of memory while minimizing the total amount of memory used.
10A general-purpose dynamic-allocation algorithm cannot anticipate future allocation requests so its output is rarely optimal.
11However, memory allocators do take advantage of regularities in allocation patterns for typical programs to produce excellent results, both in time and space (similar to LRU paging).
12In general, allocators use a number of similar techniques, each optimizing specific allocation patterns.
13Nevertheless, memory allocators are a series of compromises, occasionally with some static or dynamic tuning parameters to optimize specific program-request patterns.
14
15
16\section{Memory Structure}
17\label{s:MemoryStructure}
18
19\VRef[Figure]{f:ProgramAddressSpace} shows the typical layout of a program's address space divided into the following zones (right to left): static code/data, dynamic allocation, dynamic code/data, and stack, with free memory surrounding the dynamic code/data~\cite{memlayout}.
20Static code and data are placed into memory at load time from the executable and are fixed-sized at runtime.
21Dynamic-allocation memory starts empty and grows/shrinks as the program dynamically creates/deletes variables with independent lifetime.
22The programming-language's runtime manages this area, where management complexity is a function of the mechanism for deleting variables.
23Dynamic code/data memory is managed by the dynamic loader for libraries loaded at runtime, which is complex especially in a multi-threaded program~\cite{Huang06}.
24However, changes to the dynamic code/data space are typically infrequent, many occurring at program startup, and are largely outside of a program's control.
25Stack memory is managed by the program call-mechanism using a simple LIFO technique, which works well for sequential programs.
26For multi-threaded programs (and coroutines), a new stack is created for each thread;
27these thread stacks are commonly created in dynamic-allocation memory.
28This thesis focuses on management of the dynamic-allocation memory.
29
30\begin{figure}
31\centering
32\input{AddressSpace}
33\vspace{-5pt}
34\caption{Program Address Space Divided into Zones}
35\label{f:ProgramAddressSpace}
36\end{figure}
37
38
39\section{Dynamic Memory-Management}
40\label{s:DynamicMemoryManagement}
41
42Modern programming languages manage dynamic-allocation memory in different ways.
43Some languages, such as Lisp~\cite{CommonLisp}, Java~\cite{Java}, Haskell~\cite{Haskell}, Go~\cite{Go}, provide explicit allocation but \emph{implicit} deallocation of data through garbage collection~\cite{Wilson92}.
44In general, garbage collection supports memory compaction, where dynamic (live) data is moved during runtime to better utilize space.
45However, moving data requires finding pointers to it and updating them to reflect new data locations.
46Programming languages such as C~\cite{C}, \CC~\cite{C++}, and Rust~\cite{Rust} provide the programmer with explicit allocation \emph{and} deallocation of data.
47These languages cannot find and subsequently move live data because pointers can be created to any storage zone, including internal components of allocated objects, and may contain temporary invalid values generated by pointer arithmetic.
48Attempts have been made to perform quasi garbage collection in C/\CC~\cite{Boehm88}, but it is a compromise.
49This thesis only examines dynamic memory-management with \emph{explicit} deallocation.
50While garbage collection and compaction are not part this work, many of the results are applicable to the allocation phase in any memory-management approach.
51
52Most programs use a general-purpose allocator, often the one provided implicitly by the programming-language's runtime.
53When this allocator proves inadequate, programmers often write specialize allocators for specific needs.
54C and \CC allow easy replacement of the default memory allocator with an alternative specialized or general-purpose memory-allocator.
55(Jikes RVM MMTk~\cite{MMTk} provides a similar generalization for the Java virtual machine.)
56However, high-performance memory-allocators for kernel and user multi-threaded programs are still being designed and improved.
57For this reason, several alternative general-purpose allocators have been written for C/\CC with the goal of scaling in a multi-threaded program~\cite{Berger00,mtmalloc,streamflow,tcmalloc}.
58This thesis examines the design of high-performance allocators for use by kernel and user multi-threaded applications written in C/\CC.
59
60
61\section{Contributions}
62\label{s:Contributions}
63
64This work provides the following contributions in the area of concurrent dynamic allocation:
65\begin{enumerate}[leftmargin=*]
66\item
67Implementation of a new stand-lone concurrent low-latency memory-allocator ($\approx$1,200 lines of code) for C/\CC programs using kernel threads (1:1 threading), and specialized versions of the allocator for programming languages \uC and \CFA using user-level threads running over multiple kernel threads (M:N threading).
68
69\item
70Adopt returning of @nullptr@ for a zero-sized allocation, rather than an actual memory address, both of which can be passed to @free@.
71
72\item
73Extended the standard C heap functionality by preserving with each allocation its original request size versus the amount allocated, if an allocation is zero fill, and the allocation alignment.
74
75\item
76Use the zero fill and alignment as \emph{sticky} properties for @realloc@, to realign existing storage, or preserve existing zero-fill and alignment when storage is copied.
77Without this extension, it is unsafe to @realloc@ storage initially allocated with zero-fill/alignment as these properties are not preserved when copying.
78This silent generation of a problem is unintuitive to programmers and difficult to locate because it is transient.
79
80\item
81Provide additional heap operations to complete programmer expectation with respect to accessing different allocation properties.
82\begin{itemize}
83\item
84@resize( oaddr, size )@ re-purpose an old allocation for a new type \emph{without} preserving fill or alignment.
85\item
86@resize( oaddr, alignment, size )@ re-purpose an old allocation with new alignment but \emph{without} preserving fill.
87\item
88@realloc( oaddr, alignment, size )@ same as previous @realloc@ but adding or changing alignment.
89\item
90@aalloc( dim, elemSize )@ same as @calloc@ except memory is \emph{not} zero filled.
91\item
92@amemalign( alignment, dim, elemSize )@ same as @aalloc@ with memory alignment.
93\item
94@cmemalign( alignment, dim, elemSize )@ same as @calloc@ with memory alignment.
95\end{itemize}
96
97\item
98Provide additional heap wrapper functions in \CFA to provide a complete orthogonal set of allocation operations and properties.
99
100\item
101Provide additional query operations to access information about an allocation:
102\begin{itemize}
103\item
104@malloc_alignment( addr )@ returns the alignment of the allocation pointed-to by @addr@.
105If the allocation is not aligned or @addr@ is the @nulladdr@, the minimal alignment is returned.
106\item
107@malloc_zero_fill( addr )@ returns a boolean result indicating if the memory pointed-to by @addr@ is allocated with zero fill, e.g., by @calloc@/@cmemalign@.
108\item
109@malloc_size( addr )@ returns the size of the memory allocation pointed-to by @addr@.
110\item
111@malloc_usable_size( addr )@ returns the usable size of the memory pointed-to by @addr@, i.e., the bin size containing the allocation, where @malloc_size( addr )@ $\le$ @malloc_usable_size( addr )@.
112\end{itemize}
113
114\item
115Provide mostly contention-free allocation and free operations via a heap-per-kernel-thread implementation.
116
117\item
118Provide complete, fast, and contention-free allocation statistics to help understand program behaviour:
119\begin{itemize}
120\item
121@malloc_stats()@ print memory-allocation statistics on the file-descriptor set by @malloc_stats_fd@.
122\item
123@malloc_info( options, stream )@ print memory-allocation statistics as an XML string on the specified file-descriptor set by @malloc_stats_fd@.
124\item
125@malloc_stats_fd( fd )@ set file-descriptor number for printing memory-allocation statistics (default @STDERR_FILENO@).
126This file descriptor is used implicitly by @malloc_stats@ and @malloc_info@.
127\end{itemize}
128
129\item
130Provide extensive runtime checks to valid allocation operations and identify the amount of unfreed storage at program termination.
131
132\item
133Build 4 different versions of the allocator:
134\begin{itemize}
135\item
136static or dynamic linking
137\item
138statistic/debugging (testing) or no statistic/debugging (performance)
139\end{itemize}
140A program may link to any of these 4 versions of the allocator often without recompilation.
141(It is possible to separate statistics and debugging, giving 8 different versions.)
142
143\item
144A micro-benchmark test-suite for comparing allocators rather than relying on a suite of arbitrary programs.
145These micro-benchmarks have adjustment knobs to simulate allocation patterns hard-coded into arbitrary test programs
146\end{enumerate}
147
148\begin{comment}
149\noindent
150====================
151
152Writing Points:
153\begin{itemize}
154\item
155Introduce dynamic memory allocation with brief background.
156\item
157Scope of the thesis.
158\item
159Importance of memory allocation and micro-benchmark suite.
160\item
161Research problem.
162\item
163Research objectives.
164\item
165The vision behind cfa-malloc.
166\item
167An outline of the thesis.
168\end{itemize}
169
170\noindent
171====================
172
173\section{Introduction}
174Dynamic memory allocation and management is one of the core features of C. It gives programmer the freedom to allocate, free, use, and manage dynamic memory himself. The programmer is not given the complete control of the dynamic memory management instead an interface of memory allocator is given to the programmer that can be used to allocate/free dynamic memory for the application's use.
175
176Memory allocator is a layer between the programmer and the system. Allocator gets dynamic memory from the system in heap/mmap area of application storage and manages it for programmer's use.
177
178GNU C Library (FIX ME: cite this) provides an interchangeable memory allocator that can be replaced with a custom memory allocator that supports required features and fulfills application's custom needs. It also allows others to innovate in memory allocation and design their own memory allocator. GNU C Library has set guidelines that should be followed when designing a stand-alone memory allocator. GNU C Library requires new memory allocators to have at lease following set of functions in their allocator's interface:
179
180\begin{itemize}
181\item
182malloc: it allocates and returns a chunk of dynamic memory of requested size (FIX ME: cite man page).
183\item
184calloc: it allocates and returns an array in dynamic memory of requested size (FIX ME: cite man page).
185\item
186realloc: it reallocates and returns an already allocated chunk of dynamic memory to a new size (FIX ME: cite man page).
187\item
188free: it frees an already allocated piece of dynamic memory (FIX ME: cite man page).
189\end{itemize}
190
191In addition to the above functions, GNU C Library also provides some more functions to increase the usability of the dynamic memory allocator. Most stand-alone allocators also provide all or some of the above additional functions.
192
193\begin{itemize}
194\item
195aligned\_alloc
196\item
197malloc\_usable\_size
198\item
199memalign
200\item
201posix\_memalign
202\item
203pvalloc
204\item
205valloc
206\end{itemize}
207
208With the rise of concurrent applications, memory allocators should be able to fulfill dynamic memory requests from multiple threads in parallel without causing contention on shared resources. There needs to be a set of a standard benchmarks that can be used to evaluate an allocator's performance in different scenarios.
209
210\section{Research Objectives}
211Our research objective in this thesis is to:
212
213\begin{itemize}
214\item
215Design a lightweight concurrent memory allocator with added features and usability that are currently not present in the other memory allocators.
216\item
217Design a suite of benchmarks to evaluate multiple aspects of a memory allocator.
218\end{itemize}
219
220\section{An outline of the thesis}
221LAST FIX ME: add outline at the end
222\end{comment}
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