source: doc/theses/mubeen_zulfiqar_MMath/performance.tex @ 1bb0170

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final proofread of Mubeen's MMath thesis

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[d286e94d]1\chapter{Performance}
[6978468]2\label{c:Performance}
[080471a]3
[c9136d9]4This chapter uses the micro-benchmarks from \VRef[Chapter]{s:Benchmarks} to test a number of current memory allocators, including llheap.
[29d8c02]5The goal is to see if llheap is competitive with the currently popular memory allocators.
[c9136d9]6
7
[028404f]8\section{Machine Specification}
9
[b81ab1c6]10The performance experiments were run on two different multi-core architectures (x64 and ARM) to determine if there is consistency across platforms:
[028404f]11\begin{itemize}
12\item
[c9136d9]13\textbf{Algol} Huawei ARM TaiShan 2280 V2 Kunpeng 920, 24-core socket $\times$ 4, 2.6 GHz, GCC version 9.4.0
[29d8c02]14\item
15\textbf{Nasus} AMD EPYC 7662, 64-core socket $\times$ 2, 2.0 GHz, GCC version 9.3.0
[028404f]16\end{itemize}
17
18
[c9136d9]19\section{Existing Memory Allocators}
20\label{sec:curAllocatorSec}
[028404f]21
[c9136d9]22With dynamic allocation being an important feature of C, there are many stand-alone memory allocators that have been designed for different purposes.
[b81ab1c6]23For this thesis, 7 of the most popular and widely used memory allocators were selected for comparison, along with llheap.
[c9136d9]24
[a6c10de]25\paragraph{llheap (\textsf{llh})}
[b81ab1c6]26is the thread-safe allocator from \VRef[Chapter]{c:Allocator}
27\\
28\textbf{Version:} 1.0
29\textbf{Configuration:} Compiled with dynamic linking, but without statistics or debugging.\\
30\textbf{Compilation command:} @make@
31
32\paragraph{glibc (\textsf{glc})}
[29d8c02]33\cite{glibc} is the default glibc thread-safe allocator.
[ba897d21]34\\
[c9136d9]35\textbf{Version:} Ubuntu GLIBC 2.31-0ubuntu9.7 2.31\\
36\textbf{Configuration:} Compiled by Ubuntu 20.04.\\
37\textbf{Compilation command:} N/A
38
[b81ab1c6]39\paragraph{dlmalloc (\textsf{dl})}
40\cite{dlmalloc} is a thread-safe allocator that is single threaded and single heap.
[c9136d9]41It maintains free-lists of different sizes to store freed dynamic memory.
[ba897d21]42\\
[c9136d9]43\textbf{Version:} 2.8.6\\
44\textbf{Configuration:} Compiled with preprocessor @USE_LOCKS@.\\
45\textbf{Compilation command:} @gcc -g3 -O3 -Wall -Wextra -fno-builtin-malloc -fno-builtin-calloc@ @-fno-builtin-realloc -fno-builtin-free -fPIC -shared -DUSE_LOCKS -o libdlmalloc.so malloc-2.8.6.c@
[028404f]46
[b81ab1c6]47\paragraph{hoard (\textsf{hrd})}
[29d8c02]48\cite{hoard} is a thread-safe allocator that is multi-threaded and uses a heap layer framework. It has per-thread heaps that have thread-local free-lists, and a global shared heap.
[ba897d21]49\\
[c9136d9]50\textbf{Version:} 3.13\\
51\textbf{Configuration:} Compiled with hoard's default configurations and @Makefile@.\\
52\textbf{Compilation command:} @make all@
[028404f]53
[b81ab1c6]54\paragraph{jemalloc (\textsf{je})}
55\cite{jemalloc} is a thread-safe allocator that uses multiple arenas. Each thread is assigned an arena.
56Each arena has chunks that contain contagious memory regions of same size. An arena has multiple chunks that contain regions of multiple sizes.
[ba897d21]57\\
[c9136d9]58\textbf{Version:} 5.2.1\\
59\textbf{Configuration:} Compiled with jemalloc's default configurations and @Makefile@.\\
60\textbf{Compilation command:} @autogen.sh; configure; make; make install@
[028404f]61
[8f94a63]62\paragraph{ptmalloc3 (\textsf{pt3})}
63\cite{ptmalloc3} is a modification of dlmalloc.
[b81ab1c6]64It is a thread-safe multi-threaded memory allocator that uses multiple heaps.
[8f94a63]65ptmalloc3 heap has similar design to dlmalloc's heap.
[ba897d21]66\\
[c9136d9]67\textbf{Version:} 1.8\\
[8f94a63]68\textbf{Configuration:} Compiled with ptmalloc3's @Makefile@ using option ``linux-shared''.\\
[c9136d9]69\textbf{Compilation command:} @make linux-shared@
[028404f]70
[b81ab1c6]71\paragraph{rpmalloc (\textsf{rp})}
72\cite{rpmalloc} is a thread-safe allocator that is multi-threaded and uses per-thread heap.
73Each heap has multiple size-classes and each size-class contains memory regions of the relevant size.
[ba897d21]74\\
[c9136d9]75\textbf{Version:} 1.4.1\\
76\textbf{Configuration:} Compiled with rpmalloc's default configurations and ninja build system.\\
77\textbf{Compilation command:} @python3 configure.py; ninja@
[028404f]78
[b81ab1c6]79\paragraph{tbb malloc (\textsf{tbb})}
[29d8c02]80\cite{tbbmalloc} is a thread-safe allocator that is multi-threaded and uses a private heap for each thread.
[b81ab1c6]81Each private-heap has multiple bins of different sizes. Each bin contains free regions of the same size.
[ba897d21]82\\
[c9136d9]83\textbf{Version:} intel tbb 2020 update 2, tbb\_interface\_version == 11102\\
84\textbf{Configuration:} Compiled with tbbmalloc's default configurations and @Makefile@.\\
85\textbf{Compilation command:} @make@
[080471a]86
[c9136d9]87% \section{Experiment Environment}
88% We used our micro benchmark suite (FIX ME: cite mbench) to evaluate these memory allocators \ref{sec:curAllocatorSec} and our own memory allocator uHeap \ref{sec:allocatorSec}.
[080471a]89
[c9136d9]90\section{Experiments}
[b81ab1c6]91
[29d8c02]92Each micro-benchmark is configured and run with each of the allocators,
[fb6691a]93The less time an allocator takes to complete a benchmark the better so lower in the graphs is better, except for the Memory micro-benchmark graphs.
[1b64344]94All graphs use log scale on the Y-axis, except for the Memory micro-benchmark (see \VRef{s:MemoryMicroBenchmark}).
[080471a]95
[ba897d21]96%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
97%% CHURN
98%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
[080471a]99
[c9136d9]100\subsection{Churn Micro-Benchmark}
[080471a]101
[c9136d9]102Churn tests allocators for speed under intensive dynamic memory usage (see \VRef{s:ChurnBenchmark}).
[ba897d21]103This experiment was run with following configurations:
[c9136d9]104\begin{description}[itemsep=0pt,parsep=0pt]
105\item[thread:]
[d8075d28]1061, 2, 4, 8, 16, 32, 48
[c9136d9]107\item[spots:]
10816
109\item[obj:]
110100,000
111\item[max:]
112500
113\item[min:]
11450
115\item[step:]
11650
117\item[distro:]
118fisher
119\end{description}
120
121% -maxS          : 500
122% -minS          : 50
123% -stepS                 : 50
124% -distroS       : fisher
125% -objN          : 100000
126% -cSpots                : 16
127% -threadN       : 1, 2, 4, 8, 16
128
129\VRef[Figure]{fig:churn} shows the results for algol and nasus.
[b81ab1c6]130The X-axis shows the number of threads;
131the Y-axis shows the total experiment time.
[c9136d9]132Each allocator's performance for each thread is shown in different colors.
[ba897d21]133
134\begin{figure}
135\centering
[b81ab1c6]136    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/churn} }
137    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/churn} }
[ba897d21]138\caption{Churn}
139\label{fig:churn}
140\end{figure}
141
[1b64344]142\paragraph{Assessment}
[b81ab1c6]143All allocators did well in this micro-benchmark, except for \textsf{dl} on the ARM.
[1b64344]144\textsf{dl}'s is the slowest, indicating some small bottleneck with respect to the other allocators.
145\textsf{je} is the fastest, with only a small benefit over the other allocators.
146% llheap is slightly slower because it uses ownership, where many of the allocations have remote frees, which requires locking.
147% When llheap is compiled without ownership, its performance is the same as the other allocators (not shown).
[c9136d9]148
[ba897d21]149%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
150%% THRASH
151%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
[080471a]152
153\subsection{Cache Thrash}
[4b2ea0d]154\label{sec:cache-thrash-perf}
[080471a]155
[c9136d9]156Thrash tests memory allocators for active false sharing (see \VRef{sec:benchThrashSec}).
[ba897d21]157This experiment was run with following configurations:
[c9136d9]158\begin{description}[itemsep=0pt,parsep=0pt]
[b81ab1c6]159\item[threads:]
[d8075d28]1601, 2, 4, 8, 16, 32, 48
[c9136d9]161\item[iterations:]
1621,000
163\item[cacheRW:]
1641,000,000
165\item[size:]
1661
167\end{description}
168
169% * Each allocator was tested for its performance across different number of threads.
170% Experiment was repeated for each allocator for 1, 2, 4, 8, and 16 threads by setting the configuration -threadN.
[ba897d21]171
[b81ab1c6]172\VRef[Figure]{fig:cacheThrash} shows the results for algol and nasus.
173The X-axis shows the number of threads;
174the Y-axis shows the total experiment time.
175Each allocator's performance for each thread is shown in different colors.
[ba897d21]176
177\begin{figure}
178\centering
[a6c10de]179    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/cache_thrash_0-thrash} }
180    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/cache_thrash_0-thrash} }
[ba897d21]181\caption{Cache Thrash}
182\label{fig:cacheThrash}
183\end{figure}
184
[1b64344]185\paragraph{Assessment}
[4b2ea0d]186All allocators did well in this micro-benchmark, except for \textsf{dl} and \textsf{pt3}.
[1b64344]187\textsf{dl} uses a single heap for all threads so it is understandable that it generates so much active false-sharing.
188Requests from different threads are dealt with sequentially by the single heap (using a single lock), which can allocate objects to different threads on the same cache line.
189\textsf{pt3} uses the T:H model, so multiple threads can use one heap, but the active false-sharing is less than \textsf{dl}.
190The rest of the memory allocators generate little or no active false-sharing.
[b81ab1c6]191
[ba897d21]192%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
193%% SCRATCH
194%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
195
196\subsection{Cache Scratch}
197
[b81ab1c6]198Scratch tests memory allocators for program-induced allocator-preserved passive false-sharing (see \VRef{s:CacheScratch}).
[ba897d21]199This experiment was run with following configurations:
[c9136d9]200\begin{description}[itemsep=0pt,parsep=0pt]
201\item[threads:]
[d8075d28]2021, 2, 4, 8, 16, 32, 48
[c9136d9]203\item[iterations:]
2041,000
205\item[cacheRW:]
2061,000,000
207\item[size:]
2081
209\end{description}
210
211% * Each allocator was tested for its performance across different number of threads.
212% Experiment was repeated for each allocator for 1, 2, 4, 8, and 16 threads by setting the configuration -threadN.
[ba897d21]213
[b81ab1c6]214\VRef[Figure]{fig:cacheScratch} shows the results for algol and nasus.
215The X-axis shows the number of threads;
216the Y-axis shows the total experiment time.
217Each allocator's performance for each thread is shown in different colors.
[ba897d21]218
219\begin{figure}
220\centering
[a6c10de]221    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/cache_scratch_0-scratch} }
222    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/cache_scratch_0-scratch} }
[ba897d21]223\caption{Cache Scratch}
224\label{fig:cacheScratch}
225\end{figure}
226
[1b64344]227\paragraph{Assessment}
228This micro-benchmark divides the allocators into two groups.
229First is the high-performer group: \textsf{llh}, \textsf{je}, and \textsf{rp}.
230These memory allocators generate little or no passive false-sharing and their performance difference is negligible.
231Second is the low-performer group, which includes the rest of the memory allocators.
232These memory allocators have significant program-induced passive false-sharing, where \textsf{hrd}'s is the worst performing allocator.
[29d8c02]233All of the allocators in this group are sharing heaps among threads at some level.
[4b2ea0d]234
[29d8c02]235Interestingly, allocators such as \textsf{hrd} and \textsf{glc} performed well in micro-benchmark cache thrash (see \VRef{sec:cache-thrash-perf}), but, these allocators are among the low performers in the cache scratch.
236It suggests these allocators do not actively produce false-sharing, but preserve program-induced passive false sharing.
[b81ab1c6]237
[ba897d21]238%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
239%% SPEED
240%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
241
[c9136d9]242\subsection{Speed Micro-Benchmark}
[ba897d21]243
[b81ab1c6]244Speed tests memory allocators for runtime latency (see \VRef{s:SpeedMicroBenchmark}).
[ba897d21]245This experiment was run with following configurations:
[c9136d9]246\begin{description}[itemsep=0pt,parsep=0pt]
247\item[max:]
248500
249\item[min:]
25050
251\item[step:]
25250
253\item[distro:]
254fisher
255\item[objects:]
[d8075d28]256100,000
[c9136d9]257\item[workers:]
[d8075d28]2581, 2, 4, 8, 16, 32, 48
[c9136d9]259\end{description}
260
261% -maxS    :  500
262% -minS    :  50
263% -stepS   :  50
264% -distroS :  fisher
265% -objN    :  1000000
266% -threadN    : \{ 1, 2, 4, 8, 16 \} *
267
268%* Each allocator was tested for its performance across different number of threads.
269%Experiment was repeated for each allocator for 1, 2, 4, 8, and 16 threads by setting the configuration -threadN.
[3c79ea9]270
[b81ab1c6]271\VRefrange[Figures]{fig:speed-3-malloc}{fig:speed-14-malloc-calloc-realloc-free} show 12 figures, one figure for each chain of the speed benchmark.
272The X-axis shows the number of threads;
273the Y-axis shows the total experiment time.
274Each allocator's performance for each thread is shown in different colors.
[3c79ea9]275
276\begin{itemize}
[b81ab1c6]277\item \VRef[Figure]{fig:speed-3-malloc} shows results for chain: malloc
278\item \VRef[Figure]{fig:speed-4-realloc} shows results for chain: realloc
279\item \VRef[Figure]{fig:speed-5-free} shows results for chain: free
280\item \VRef[Figure]{fig:speed-6-calloc} shows results for chain: calloc
281\item \VRef[Figure]{fig:speed-7-malloc-free} shows results for chain: malloc-free
282\item \VRef[Figure]{fig:speed-8-realloc-free} shows results for chain: realloc-free
283\item \VRef[Figure]{fig:speed-9-calloc-free} shows results for chain: calloc-free
284\item \VRef[Figure]{fig:speed-10-malloc-realloc} shows results for chain: malloc-realloc
285\item \VRef[Figure]{fig:speed-11-calloc-realloc} shows results for chain: calloc-realloc
286\item \VRef[Figure]{fig:speed-12-malloc-realloc-free} shows results for chain: malloc-realloc-free
287\item \VRef[Figure]{fig:speed-13-calloc-realloc-free} shows results for chain: calloc-realloc-free
288\item \VRef[Figure]{fig:speed-14-malloc-calloc-realloc-free} shows results for chain: malloc-realloc-free-calloc
[3c79ea9]289\end{itemize}
[ba897d21]290
[1b64344]291\paragraph{Assessment}
292This micro-benchmark divides the allocators into two groups: with and without @calloc@.
293@calloc@ uses @memset@ to set the allocated memory to zero, which dominates the cost of the allocation chain (large performance increase) and levels performance across the allocators.
294But the difference among the allocators in a @calloc@ chain still gives an idea of their relative performance.
[4b2ea0d]295
[1b64344]296All allocators did well in this micro-benchmark across all allocation chains, except for \textsf{dl}, \textsf{pt3}, and \textsf{hrd}.
297Again, the low-performing allocators are sharing heaps among threads, so the contention causes performance increases with increasing numbers of threads.
298Furthermore, chains with @free@ can trigger coalescing, which slows the fast path.
299The high-performing allocators all illustrate low latency across the allocation chains, \ie there are no performance spikes as the chain lengths, that might be caused by contention and/or coalescing.
300Low latency is important for applications that are sensitive to unknown execution delays.
[b81ab1c6]301
[ba897d21]302%speed-3-malloc.eps
303\begin{figure}
304\centering
[b81ab1c6]305    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-3-malloc} }
306    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-3-malloc} }
[3c79ea9]307\caption{Speed benchmark chain: malloc}
[ba897d21]308\label{fig:speed-3-malloc}
309\end{figure}
310
311%speed-4-realloc.eps
312\begin{figure}
313\centering
[b81ab1c6]314    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-4-realloc} }
315    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-4-realloc} }
[3c79ea9]316\caption{Speed benchmark chain: realloc}
[ba897d21]317\label{fig:speed-4-realloc}
318\end{figure}
319
320%speed-5-free.eps
321\begin{figure}
322\centering
[b81ab1c6]323    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-5-free} }
324    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-5-free} }
[3c79ea9]325\caption{Speed benchmark chain: free}
[ba897d21]326\label{fig:speed-5-free}
327\end{figure}
328
329%speed-6-calloc.eps
330\begin{figure}
331\centering
[b81ab1c6]332    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-6-calloc} }
333    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-6-calloc} }
[3c79ea9]334\caption{Speed benchmark chain: calloc}
[ba897d21]335\label{fig:speed-6-calloc}
336\end{figure}
337
338%speed-7-malloc-free.eps
339\begin{figure}
340\centering
[b81ab1c6]341    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-7-malloc-free} }
342    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-7-malloc-free} }
[3c79ea9]343\caption{Speed benchmark chain: malloc-free}
[ba897d21]344\label{fig:speed-7-malloc-free}
345\end{figure}
346
347%speed-8-realloc-free.eps
348\begin{figure}
349\centering
[b81ab1c6]350    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-8-realloc-free} }
351    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-8-realloc-free} }
[3c79ea9]352\caption{Speed benchmark chain: realloc-free}
[ba897d21]353\label{fig:speed-8-realloc-free}
354\end{figure}
355
356%speed-9-calloc-free.eps
357\begin{figure}
358\centering
[b81ab1c6]359    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-9-calloc-free} }
360    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-9-calloc-free} }
[3c79ea9]361\caption{Speed benchmark chain: calloc-free}
[ba897d21]362\label{fig:speed-9-calloc-free}
363\end{figure}
364
365%speed-10-malloc-realloc.eps
366\begin{figure}
367\centering
[b81ab1c6]368    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-10-malloc-realloc} }
369    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-10-malloc-realloc} }
[3c79ea9]370\caption{Speed benchmark chain: malloc-realloc}
[ba897d21]371\label{fig:speed-10-malloc-realloc}
372\end{figure}
373
374%speed-11-calloc-realloc.eps
375\begin{figure}
376\centering
[b81ab1c6]377    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-11-calloc-realloc} }
378    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-11-calloc-realloc} }
[3c79ea9]379\caption{Speed benchmark chain: calloc-realloc}
[ba897d21]380\label{fig:speed-11-calloc-realloc}
381\end{figure}
382
383%speed-12-malloc-realloc-free.eps
384\begin{figure}
385\centering
[b81ab1c6]386    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-12-malloc-realloc-free} }
387    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-12-malloc-realloc-free} }
[3c79ea9]388\caption{Speed benchmark chain: malloc-realloc-free}
[ba897d21]389\label{fig:speed-12-malloc-realloc-free}
390\end{figure}
391
392%speed-13-calloc-realloc-free.eps
393\begin{figure}
394\centering
[b81ab1c6]395    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-13-calloc-realloc-free} }
396    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-13-calloc-realloc-free} }
[3c79ea9]397\caption{Speed benchmark chain: calloc-realloc-free}
[ba897d21]398\label{fig:speed-13-calloc-realloc-free}
399\end{figure}
400
401%speed-14-{m,c,re}alloc-free.eps
402\begin{figure}
403\centering
[b81ab1c6]404    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/speed-14-m-c-re-alloc-free} }
405    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/speed-14-m-c-re-alloc-free} }
[3c79ea9]406\caption{Speed benchmark chain: malloc-calloc-realloc-free}
407\label{fig:speed-14-malloc-calloc-realloc-free}
[ba897d21]408\end{figure}
409
410%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
411%% MEMORY
412%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
413
[b81ab1c6]414\newpage
[c9136d9]415\subsection{Memory Micro-Benchmark}
[1b64344]416\label{s:MemoryMicroBenchmark}
[ba897d21]417
[b81ab1c6]418This experiment is run with the following two configurations for each allocator.
[c9136d9]419The difference between the two configurations is the number of producers and consumers.
[b81ab1c6]420Configuration 1 has one producer and one consumer, and configuration 2 has 4 producers, where each producer has 4 consumers.
[3c79ea9]421
[c9136d9]422\noindent
[3c79ea9]423Configuration 1:
[c9136d9]424\begin{description}[itemsep=0pt,parsep=0pt]
425\item[producer (K):]
4261
427\item[consumer (M):]
4281
429\item[round:]
430100,000
431\item[max:]
432500
433\item[min:]
43450
435\item[step:]
43650
437\item[distro:]
438fisher
439\item[objects (N):]
440100,000
441\end{description}
442
443% -threadA :  1
444% -threadF :  1
445% -maxS    :  500
446% -minS    :  50
447% -stepS   :  50
448% -distroS :  fisher
449% -objN    :  100000
450% -consumeS:  100000
451
452\noindent
[3c79ea9]453Configuration 2:
[c9136d9]454\begin{description}[itemsep=0pt,parsep=0pt]
455\item[producer (K):]
4564
457\item[consumer (M):]
4584
459\item[round:]
460100,000
461\item[max:]
462500
463\item[min:]
46450
465\item[step:]
46650
467\item[distro:]
468fisher
469\item[objects (N):]
470100,000
471\end{description}
472
473% -threadA :  4
474% -threadF :  4
475% -maxS    :  500
476% -minS    :  50
477% -stepS   :  50
478% -distroS :  fisher
479% -objN    :  100000
480% -consumeS:  100000
481
[4994d67]482% \begin{table}[b]
483% \centering
484%     \begin{tabular}{ |c|c|c| }
485%      \hline
486%     Memory Allocator & Configuration 1 Result & Configuration 2 Result\\
487%      \hline
[a6c10de]488%     llh & \VRef[Figure]{fig:mem-1-prod-1-cons-100-llh} & \VRef[Figure]{fig:mem-4-prod-4-cons-100-llh}\\
[4994d67]489%      \hline
490%     dl & \VRef[Figure]{fig:mem-1-prod-1-cons-100-dl} & \VRef[Figure]{fig:mem-4-prod-4-cons-100-dl}\\
491%      \hline
492%     glibc & \VRef[Figure]{fig:mem-1-prod-1-cons-100-glc} & \VRef[Figure]{fig:mem-4-prod-4-cons-100-glc}\\
493%      \hline
494%     hoard & \VRef[Figure]{fig:mem-1-prod-1-cons-100-hrd} & \VRef[Figure]{fig:mem-4-prod-4-cons-100-hrd}\\
495%      \hline
496%     je & \VRef[Figure]{fig:mem-1-prod-1-cons-100-je} & \VRef[Figure]{fig:mem-4-prod-4-cons-100-je}\\
497%      \hline
498%     pt3 & \VRef[Figure]{fig:mem-1-prod-1-cons-100-pt3} & \VRef[Figure]{fig:mem-4-prod-4-cons-100-pt3}\\
499%      \hline
500%     rp & \VRef[Figure]{fig:mem-1-prod-1-cons-100-rp} & \VRef[Figure]{fig:mem-4-prod-4-cons-100-rp}\\
501%      \hline
502%     tbb & \VRef[Figure]{fig:mem-1-prod-1-cons-100-tbb} & \VRef[Figure]{fig:mem-4-prod-4-cons-100-tbb}\\
503%      \hline
504%     \end{tabular}
505% \caption{Memory benchmark results}
506% \label{table:mem-benchmark-figs}
507% \end{table}
508% Table \ref{table:mem-benchmark-figs} shows the list of figures that contain memory benchmark results.
[3c79ea9]509
[a6c10de]510\VRefrange[Figures]{fig:mem-1-prod-1-cons-100-llh}{fig:mem-4-prod-4-cons-100-tbb} show 16 figures, two figures for each of the 8 allocators, one for each configuration.
[3c79ea9]511Each figure has 2 graphs, one for each experiment environment.
[4994d67]512Each graph has following 5 subgraphs that show memory usage and statistics throughout the micro-benchmark's lifetime.
[3c79ea9]513\begin{itemize}
514\item \textit{\textbf{current\_req\_mem(B)}} shows the amount of dynamic memory requested and currently in-use of the benchmark.
[4994d67]515\item \textit{\textbf{heap}}* shows the memory requested by the program (allocator) from the system that lies in the heap (@sbrk@) area.
516\item \textit{\textbf{mmap\_so}}* shows the memory requested by the program (allocator) from the system that lies in the @mmap@ area.
517\item \textit{\textbf{mmap}}* shows the memory requested by the program (allocator or shared libraries) from the system that lies in the @mmap@ area.
518\item \textit{\textbf{total\_dynamic}} shows the total usage of dynamic memory by the benchmark program, which is a sum of \textit{heap}, \textit{mmap}, and \textit{mmap\_so}.
[3c79ea9]519\end{itemize}
[4994d67]520* These statistics are gathered by monitoring a process's @/proc/self/maps@ file.
[3c79ea9]521
[4994d67]522The X-axis shows the time when the memory information is polled.
523The Y-axis shows the memory usage in bytes.
[3c79ea9]524
[1b64344]525For this experiment, the difference between the memory requested by the benchmark (\textit{current\_req\_mem(B)}) and the memory that the process has received from system (\textit{heap}, \textit{mmap}) should be minimum.
[3c79ea9]526This difference is the memory overhead caused by the allocator and shows the level of fragmentation in the allocator.
527
[1b64344]528\paragraph{Assessment}
[4994d67]529First, the differences in the shape of the curves between architectures (top ARM, bottom x64) is small, where the differences are in the amount of memory used.
530Hence, it is possible to focus on either the top or bottom graph.
531
[1b64344]532Second, the heap curve is 0 for four memory allocators: \textsf{hrd}, \textsf{je}, \textsf{pt3}, and \textsf{rp}, indicating these memory allocators only use @mmap@ to get memory from the system and ignore the @sbrk@ area.
533
534The total dynamic memory is higher for \textsf{hrd} and \textsf{tbb} than the other allocators.
535The main reason is the use of superblocks (see \VRef{s:ObjectContainers}) containing objects of the same size.
[4b2ea0d]536These superblocks are maintained throughout the life of the program.
[4994d67]537
[1b64344]538\textsf{pt3} is the only memory allocator where the total dynamic memory goes down in the second half of the program lifetime when the memory is freed by the benchmark program.
539It makes pt3 the only memory allocator that gives memory back to the operating system as it is freed by the program.
[4b2ea0d]540
541% FOR 1 THREAD
[4994d67]542
[a6c10de]543%mem-1-prod-1-cons-100-llh.eps
[ba897d21]544\begin{figure}
545\centering
[a6c10de]546    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-1-prod-1-cons-100-llh} }
547    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-1-prod-1-cons-100-llh} }
[4b2ea0d]548\caption{Memory benchmark results with Configuration-1 for llh memory allocator}
[a6c10de]549\label{fig:mem-1-prod-1-cons-100-llh}
[ba897d21]550\end{figure}
551
[4994d67]552%mem-1-prod-1-cons-100-dl.eps
553\begin{figure}
554\centering
555    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-1-prod-1-cons-100-dl} }
556    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-1-prod-1-cons-100-dl} }
[4b2ea0d]557\caption{Memory benchmark results with Configuration-1 for dl memory allocator}
[4994d67]558\label{fig:mem-1-prod-1-cons-100-dl}
559\end{figure}
560
561%mem-1-prod-1-cons-100-glc.eps
562\begin{figure}
563\centering
564    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-1-prod-1-cons-100-glc} }
565    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-1-prod-1-cons-100-glc} }
[4b2ea0d]566\caption{Memory benchmark results with Configuration-1 for glibc memory allocator}
[4994d67]567\label{fig:mem-1-prod-1-cons-100-glc}
568\end{figure}
569
570%mem-1-prod-1-cons-100-hrd.eps
571\begin{figure}
572\centering
573    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-1-prod-1-cons-100-hrd} }
574    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-1-prod-1-cons-100-hrd} }
[4b2ea0d]575\caption{Memory benchmark results with Configuration-1 for hoard memory allocator}
[4994d67]576\label{fig:mem-1-prod-1-cons-100-hrd}
577\end{figure}
578
579%mem-1-prod-1-cons-100-je.eps
580\begin{figure}
581\centering
582    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-1-prod-1-cons-100-je} }
583    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-1-prod-1-cons-100-je} }
[4b2ea0d]584\caption{Memory benchmark results with Configuration-1 for je memory allocator}
[4994d67]585\label{fig:mem-1-prod-1-cons-100-je}
586\end{figure}
587
588%mem-1-prod-1-cons-100-pt3.eps
589\begin{figure}
590\centering
591    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-1-prod-1-cons-100-pt3} }
592    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-1-prod-1-cons-100-pt3} }
[4b2ea0d]593\caption{Memory benchmark results with Configuration-1 for pt3 memory allocator}
[4994d67]594\label{fig:mem-1-prod-1-cons-100-pt3}
595\end{figure}
596
597%mem-1-prod-1-cons-100-rp.eps
598\begin{figure}
599\centering
600    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-1-prod-1-cons-100-rp} }
601    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-1-prod-1-cons-100-rp} }
[4b2ea0d]602\caption{Memory benchmark results with Configuration-1 for rp memory allocator}
[4994d67]603\label{fig:mem-1-prod-1-cons-100-rp}
604\end{figure}
605
606%mem-1-prod-1-cons-100-tbb.eps
607\begin{figure}
608\centering
609    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-1-prod-1-cons-100-tbb} }
610    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-1-prod-1-cons-100-tbb} }
[4b2ea0d]611\caption{Memory benchmark results with Configuration-1 for tbb memory allocator}
[4994d67]612\label{fig:mem-1-prod-1-cons-100-tbb}
613\end{figure}
614
[4b2ea0d]615% FOR 4 THREADS
616
617%mem-4-prod-4-cons-100-llh.eps
618\begin{figure}
619\centering
620    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-4-prod-4-cons-100-llh} }
621    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-4-prod-4-cons-100-llh} }
622\caption{Memory benchmark results with Configuration-2 for llh memory allocator}
623\label{fig:mem-4-prod-4-cons-100-llh}
624\end{figure}
625
626%mem-4-prod-4-cons-100-dl.eps
627\begin{figure}
628\centering
629    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-4-prod-4-cons-100-dl} }
630    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-4-prod-4-cons-100-dl} }
631\caption{Memory benchmark results with Configuration-2 for dl memory allocator}
632\label{fig:mem-4-prod-4-cons-100-dl}
633\end{figure}
634
635%mem-4-prod-4-cons-100-glc.eps
636\begin{figure}
637\centering
638    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-4-prod-4-cons-100-glc} }
639    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-4-prod-4-cons-100-glc} }
640\caption{Memory benchmark results with Configuration-2 for glibc memory allocator}
641\label{fig:mem-4-prod-4-cons-100-glc}
642\end{figure}
643
644%mem-4-prod-4-cons-100-hrd.eps
645\begin{figure}
646\centering
647    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-4-prod-4-cons-100-hrd} }
648    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-4-prod-4-cons-100-hrd} }
649\caption{Memory benchmark results with Configuration-2 for hoard memory allocator}
650\label{fig:mem-4-prod-4-cons-100-hrd}
651\end{figure}
652
653%mem-4-prod-4-cons-100-je.eps
654\begin{figure}
655\centering
656    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-4-prod-4-cons-100-je} }
657    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-4-prod-4-cons-100-je} }
658\caption{Memory benchmark results with Configuration-2 for je memory allocator}
659\label{fig:mem-4-prod-4-cons-100-je}
660\end{figure}
661
662%mem-4-prod-4-cons-100-pt3.eps
663\begin{figure}
664\centering
665    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-4-prod-4-cons-100-pt3} }
666    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-4-prod-4-cons-100-pt3} }
667\caption{Memory benchmark results with Configuration-2 for pt3 memory allocator}
668\label{fig:mem-4-prod-4-cons-100-pt3}
669\end{figure}
670
671%mem-4-prod-4-cons-100-rp.eps
672\begin{figure}
673\centering
674    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-4-prod-4-cons-100-rp} }
675    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-4-prod-4-cons-100-rp} }
676\caption{Memory benchmark results with Configuration-2 for rp memory allocator}
677\label{fig:mem-4-prod-4-cons-100-rp}
678\end{figure}
679
[ba897d21]680%mem-4-prod-4-cons-100-tbb.eps
681\begin{figure}
682\centering
[b81ab1c6]683    \subfigure[Algol]{ \includegraphics[width=0.95\textwidth]{evaluations/algol-perf-eps/mem-4-prod-4-cons-100-tbb} }
684    \subfigure[Nasus]{ \includegraphics[width=0.95\textwidth]{evaluations/nasus-perf-eps/mem-4-prod-4-cons-100-tbb} }
[4b2ea0d]685\caption{Memory benchmark results with Configuration-2 for tbb memory allocator}
[ba897d21]686\label{fig:mem-4-prod-4-cons-100-tbb}
687\end{figure}
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