让我们定义:
来自多处理导入池将 numpy 导入为 np定义函数(x):对于我在范围内(1000):我**2返回 1
注意 func()
做了一些事情,它总是返回一个小数字 1
.
然后,我比较 8 核并行 Pool.map()
与串行、python 内置 map()
n=10**3a=np.random.random(n).tolist()使用 Pool(8) 作为 p:%timeit -r1 -n2 p.map(func,a)%timeit -r1 -n2 列表(地图(函数,a))
这给出了:
38.4 ms ± 0 ns 每个循环(平均值 ± 标准偏差.1 次运行,每次 2 个循环)每个循环 200 ms ± 0 ns(平均值 ± 标准偏差.1 次运行,每个循环 2 个)
这显示了相当好的并行缩放.因为我用的是8核,38.3 [ms]
大概是200[s]
然后让我们尝试 Pool.map()
在一些更大的东西的列表上,为简单起见,我以这种方式使用列表列表:
n=10**3m=10**4a=np.random.random((n,m)).tolist()使用 Pool(8) 作为 p:%timeit -r1 -n2 p.map(func,a)%timeit -r1 -n2 列表(地图(函数,a))
给出:
292 ms ± 0 ns 每个循环(平均值 ± 标准偏差.1 次运行,每次 2 次循环)每个循环 209 ms ± 0 ns(平均值 ± 标准偏差.1 次运行,每个循环 2 个)
你看,并行扩展已经不复存在了!1s ~ 1.76s
我们可以让它变得更糟,尝试让每个子列表通过更大:
n=10**3m=10**5a=np.random.random((n,m)).tolist()使用 Pool(8) 作为 p:%timeit -r1 -n2 p.map(func,a)%timeit -r1 -n2 列表(地图(函数,a))
这给出了:
3.29 s ± 0 ns 每个循环(平均值 ± 标准偏差.1 次运行,每次 2 次循环)每个循环 179 ms ± 0 ns(平均值 ± 标准偏差.1 次运行,每个循环 2 个)
哇,再大的子列表,计时结果完全颠倒了.我们使用 8 个核心来获得慢 20 倍的时序!!
您还可以注意到串行 map()
的时序与子列表大小无关.所以一个合理的解释是,Pool.map()
真的是在围绕导致额外复制的进程传递那些大子列表的内容?
我不确定.但如果是这样,为什么它不传递子列表的地址?毕竟子列表已经在内存中了,在实践中我使用的func()
保证不会改变/修改子列表.
那么,在 python 中,当在大型事物列表上映射某些操作时,保持并行缩放的正确方法是什么?
在我们开始之前
并深入研究任何纳秒(没错,它很快就会开始,因为每个 [ns]
都很重要,因为缩放会打开整个潘多拉盒子的问题),让我们就比例达成一致 - 最简单且通常 便宜" 一旦问题规模扩大到现实规模,过早的技巧可能而且经常会破坏你的梦想 - 成千上万(在上面的两个迭代器中看到)对于 缓存计算 与 <0.5 [ns]
次数据提取,比一次增长超过 L1/L2/L3 缓存大小1E+5、1E+6、1E+9、
code> 高于 [GB]
s,where 每个未对齐的 fetch 比几个 100 [ns] 贵得多
Q : "...因为我有 8 个内核,我想用它们来提高 8 倍的速度"
我希望你可以,确实.然而,很抱歉直截了当地说实话,世界不是这样运作的.
<块引用>查看这个交互式工具,它将向您显示加速限制及其对实际生产成本的主要依赖性-初始问题的世界缩放,因为它从微不足道的大小和这些组合效果按比例增长 只需单击-它并播放 使用滑块实时查看它的实际效果:
Q : (is)Pool.map()
确实将那些大子列表的内容传递到导致额外的副本?
是的,
它必须按照设计这样做
此外,它通过将所有数据传递通过"另一个昂贵" SER/DES 处理,
以便实现交付那里".
只要您尝试过,反之亦然返回 "back" 一些乳齿象大小的结果,你没有,在上面.
Q:如果是这样,为什么不传递子列表的地址?
因为远程(参数接收)进程是另一个完全自治的进程,具有自己的、独立的和受保护的,地址空间我们不能只传递一个地址引用 "into",我们希望它是一个完全独立、自主工作的 python 进程(因为愿意使用这个技巧来逃避
A )
了解避免或至少减少开支的方法:
了解所有类型的 您必须支付和将支付的费用:
花费尽可能少流程实例化成本尽可能(相当昂贵)最好只作为一次性成本
在 macOS 上,spawn
现在是默认启动方法.fork
start 方法应该被认为是不安全的,因为它可能导致子进程崩溃.请参阅 bpo-33725.
尽可能少地花费参数传递成本(是的,最好避免重复传递那些大东西"作为参数)
len( os.sched_getaffinity( 0 ) 报告的更多的进程)
- 任何进程不止于此,它将等待其下一个 CPU 核心插槽,并且将驱逐其他缓存效率高的进程,从而重新支付所有已支付的获取成本,以再次重新获取所有数据以便camp-em回到缓存中很快就会再次被驱逐出缓存中计算,而到目前为止以这种方式工作的那些进程被正确驱逐(有什么好处?)通过天真的使用多达 multiprocessing.cpu_count()
-reported 进程,在最初的 Pool
-creation 中产生的代价非常高昂)gc
,如果不避免可能会阻塞,或者 Pool.map()
哪个会阻止B )
了解提高效率的方法 :
了解所有提高效率的技巧,即使以代码复杂性为代价(一些 SLOC-s 很容易在教科书中展示,但同时牺牲了效率和性能 - 尽管这两者都是 你的主要敌人,在整个scaling(问题大小或迭代深度,或者同时增长两者).
A 中的某些类别的实际成本大幅改变了限制 进入某种形式的 [PARALLEL]
流程编排可以预期的理论上可实现的加速(这里,使代码执行的某些部分在生成的子中执行-processes ),其最初的观点早在 60 多年前由 Gene Amdahl 博士首次提出(最近添加了两个与流程实例化相关的主要扩展设置 + termination 增加成本(在 py2 always 和 py3.5+ 中对于 MacOS 和 Windows 非常重要)和 原子性-of-work
,这将在下面讨论.
S = N 个处理器可以实现的加速s = 计算的比例,即 [SERIAL]1-s = 可并行化的部分,可以运行 [PAR]N = 积极参与 [PAR] 处理的处理器(CPU 核心)数量1S = __________________________;其中 s, ( 1 - s ), N 在上面定义( 1 - s ) pSO:= [PAR]-Setup-Overhead add-on cost/latencys + pSO + _________ + pTO pTO:= [PAR]-Terminate-Overhead 附加成本/延迟ñ
1 其中 s, ( 1 - s ), NS = ______________________________________________ ;pSO, pTO|( 1 - s ) |上面定义的s + pSO + 最大值|_________ , atomicP |+ pTO atomicP:= 一个工作单元,|N |进一步不可分割,持续时间原子进程块
<小时>
1E+6
任何简化的模型示例都会以某种方式扭曲您对实际工作负载如何在体内执行的预期.低估的 RAM 分配,在小规模上看不到,后来可能会在规模上大吃一惊,有时甚至会使操作系统进入缓慢状态,交换和颠簸.一些更智能的工具( numba.jit()
)甚至可以分析代码并缩短一些代码段落,这些段落永远不会被访问或不会产生任何结果,因此请注意简化示例可能会导致令人惊讶的观察.
来自多处理导入池将 numpy 导入为 np导入操作系统比例 = 整数(1E9)STEP = int(1E1)aLIST = np.random.random( ( 10**3, 10**4 ) ).tolist()####################################################################################### func() 做了一些 SCALE 的工作,然而# 传递几乎零字节作为参数# 什么都不分配,但迭代器# 返回一个字节,# 对任何昂贵的输入都是不变的定义函数(x):对于我在范围内(SCALE):我**2返回 1
关于使扩展策略降低间接成本的一些提示:
##################################################################################### more_work_en_block() 包装了一些 SCALE 的工作量,指定的子列表def more_work_en_block(en_block = [无,]):return [ func( nth_item ) for nth_item in en_block ]
如果确实必须传递一个大列表,最好传递更大的块,远程迭代其部分(而不是为每个传递的每个项目支付传输成本,而不是使用 sub_blocks
(参数得到 SER/DES 处理(~ pickle.dumps()
+ pickle.loads()
的成本)[每次调用],再次,在附加成本,这会降低最终的效率并恶化扩展的、严格管理费用的阿姆达尔定律的管理费用部分)
##################################################################################### some_work_en_block() 包装了一些 SCALE 的工作量,元组指定def some_work_en_block( sub_block = ( [ 无, ], 0, 1 ) ):返回 more_work_en_block(en_block = sub_block[0][sub_block[1]:sub_block[2]])
<小时>
aMaxNumOfProcessesThatMakesSenseToSPAWN = len( os.sched_getaffinity( 0 ) ) # 不再使用 Pool(aMaxNumOfProcessesThatMakesSenseToSPAWN) 作为 p:p.imap_unordered(more_work_en_block, [ ( aLIST,开始,开始+步骤)在范围内开始(0,len(aLIST),STEP)])
最后但同样重要的是,预计智能使用 numpy
智能矢量化代码可以极大地提升性能,最好不要重复传递静态、预复制(在进程实例化期间),因此支付为合理缩放的(此处不可避免的)成本)BLOB,在代码中使用,无需通过参数传递传递相同的数据,以向量化(CPU 非常高效)的方式作为只读数据.如何使 ~ +500 x
加速的一些示例可以阅读这里 或 here,大约但是 ~ +400 x
加速 或大约一个大约 ~ +100 x
加速 的案例,以及一些问题隔离的示例 测试场景.
无论如何,模型代码越接近您的实际工作负载,基准测试就越有意义(在规模和生产中).
祝你探索世界好运,就像它一样,
如果它不同,就不是梦想,
不是希望它不同或我们希望它是不同的
:o)
事实和科学很重要 - 两者 + 一起
证据记录是实现尽可能高绩效的核心步骤,
没有任何产品营销,
没有任何传福音氏族战争,
没有任何博客帖子的喋喋不休
至少不要说你没有被警告
:o)
Let us define :
from multiprocessing import Pool
import numpy as np
def func(x):
for i in range(1000):
i**2
return 1
Notice that func()
does something and it always returns a small number 1
.
Then, I compare an 8-core parallel Pool.map()
v/s a serial, python built in, map()
n=10**3
a=np.random.random(n).tolist()
with Pool(8) as p:
%timeit -r1 -n2 p.map(func,a)
%timeit -r1 -n2 list(map(func,a))
This gives :
38.4 ms ± 0 ns per loop (mean ± std. dev. of 1 run, 2 loops each)
200 ms ± 0 ns per loop (mean ± std. dev. of 1 run, 2 loops each)
which shows quite good parallel scaling. Because I use 8 cores, and 38.3 [ms]
is roughly 1/8 of 200[s]
Then let us try Pool.map()
on lists of some bigger things, for simplicity, I use a list-of-lists this way :
n=10**3
m=10**4
a=np.random.random((n,m)).tolist()
with Pool(8) as p:
%timeit -r1 -n2 p.map(func,a)
%timeit -r1 -n2 list(map(func,a))
which gives :
292 ms ± 0 ns per loop (mean ± std. dev. of 1 run, 2 loops each)
209 ms ± 0 ns per loop (mean ± std. dev. of 1 run, 2 loops each)
You see, parallel scaling is gone! 1s ~ 1.76s
We can make it much worse, try to make each sub list to pass even bigger :
n=10**3
m=10**5
a=np.random.random((n,m)).tolist()
with Pool(8) as p:
%timeit -r1 -n2 p.map(func,a)
%timeit -r1 -n2 list(map(func,a))
This gives :
3.29 s ± 0 ns per loop (mean ± std. dev. of 1 run, 2 loops each)
179 ms ± 0 ns per loop (mean ± std. dev. of 1 run, 2 loops each)
Wow, with even larger sub lists, the timing result is totally reversed. We use 8 cores to get a 20 times slower timing!!
You can also notice the serial map()
's timing has nothing to do with a sub list size. So a reasonable explanation would be that Pool.map()
are really passing the content of those big sub list around processes which cause additional copy?
I am not sure. But if so, why doesn't it passing the address of sub-list? After all, the sub-list is already in the memory, and in practice the func()
I used is guaranteed not to change/modify the sub-list.
So, in python, what is the correct way to keep parallel scaling when mapping some operations on a list of large things?
Before we start
and dive deeper into any hunt for nanoseconds ( and right, it will soon start, as each [ns]
matters as the scaling opens the whole Pandora Box of the problems ), lets agree on the scales - most easy and often "cheap" premature tricks may and often will derail your dreams once the scales of the problem size have grown into realistic scales - the thousands (seen above in both iterators) behave way different for in-cache computing with < 0.5 [ns]
data-fetches, than once having grown beyond the L1/L2/L3-cache-sizes for scales above 1E+5, 1E+6, 1E+9,
above [GB]
s, where each mis-aligned fetch is WAY more EXPENSIVE, than a few 100 [ns]
Q : "... because I have 8 cores, I want to use them to get 8 times faster"
I wish you could, indeed. Yet, sorry for telling the truth straight, the World does not work this way.
See this interactive tool, it will show you both the speedup limits and their principal dependence on the actual production costs of the real-world scaling of the initial problem, as it grows from trivial sizes and these combined effects at scale just click-it and play with the sliders to see it live, in action :
Q : (is)
Pool.map()
really passing the content of those big sub list around processes which cause additional copy?
Yes,
it must do so, by design
plus it does that by passing all that data "through" another "expensive" SER/DES processing,
so as to make it happen delivered "there".
The very same would apply vice-versa whenever you would have tried to return "back" some mastodon-sized result(s), which you did not, here above.
Q : But if so, why doesn't it passing the address of sub-list?
Because the remote ( parameter-receiving ) process is another, fully autonomous process, with its own, separate and protected, address-space we cannot just pass an address-reference "into", and we wanted that to be a fully independent, autonomously working python process ( due to a will to use this trick so as to escape from GIL-lock dancing ), didn't we? Sure we did - this is a central step of our escape from the GIL-Wars ( for better understanding of the GIL-lock pros and cons, may like this and this ( Pg.15+ on CPU-bound processing ).
0.1 ns - NOP
0.3 ns - XOR, ADD, SUB
0.5 ns - CPU L1 dCACHE reference (1st introduced in late 80-ies )
0.9 ns - JMP SHORT
1 ns - speed-of-light (a photon) travel a 1 ft (30.5cm) distance -- will stay, throughout any foreseeable future :o)
?~~~~~~~~~~~ 1 ns - MUL ( i**2 = MUL i, i )~~~~~~~~~ doing this 1,000 x is 1 [us]; 1,000,000 x is 1 [ms]; 1,000,000,000 x is 1 [s] ~~~~~~~~~~~~~~~~~~~~~~~~~
3~4 ns - CPU L2 CACHE reference (2020/Q1)
5 ns - CPU L1 iCACHE Branch mispredict
7 ns - CPU L2 CACHE reference
10 ns - DIV
19 ns - CPU L3 CACHE reference (2020/Q1 considered slow on 28c Skylake)
71 ns - CPU cross-QPI/NUMA best case on XEON E5-46*
100 ns - MUTEX lock/unlock
100 ns - own DDR MEMORY reference
135 ns - CPU cross-QPI/NUMA best case on XEON E7-*
202 ns - CPU cross-QPI/NUMA worst case on XEON E7-*
325 ns - CPU cross-QPI/NUMA worst case on XEON E5-46*
10,000 ns - Compress 1K bytes with a Zippy PROCESS
20,000 ns - Send 2K bytes over 1 Gbps NETWORK
250,000 ns - Read 1 MB sequentially from MEMORY
500,000 ns - Round trip within a same DataCenter
?~~~ 2,500,000 ns - Read 10 MB sequentially from MEMORY~~(about an empty python process to copy on spawn)~~~~ x ( 1 + nProcesses ) on spawned process instantiation(s), yet an empty python interpreter is indeed not a real-world, production-grade use-case, is it?
10,000,000 ns - DISK seek
10,000,000 ns - Read 1 MB sequentially from NETWORK
?~~ 25,000,000 ns - Read 100 MB sequentially from MEMORY~~(somewhat light python process to copy on spawn)~~~~ x ( 1 + nProcesses ) on spawned process instantiation(s)
30,000,000 ns - Read 1 MB sequentially from a DISK
?~~ 36,000,000 ns - Pickle.dump() SER a 10 MB object for IPC-transfer and remote DES in spawned process~~~~~~~~ x ( 2 ) for a single 10MB parameter-payload SER/DES + add an IPC-transport costs thereof or NETWORK-grade transport costs, if going into [distributed-computing] model Cluster ecosystem
150,000,000 ns - Send a NETWORK packet CA -> Netherlands
| | | |
| | | ns|
| | us|
| ms|
Q : " what is the correct way to keep parallel scaling when parallel mapping some operations on a list of large things? "
A )
UNDERSTAND THE WAYS TO AVOID OR AT LEAST REDUCE EXPENSES :
Understand all the types of the costs you have to pay and will pay :
spend as low process instantiation costs as possible (rather expensive ) best as a one-time cost only
On macOS, the
spawn
start method is now the default. Thefork
start method should be considered unsafe as it can lead to crashes of the subprocess. See bpo-33725.
spend as small amount of costs of parameter-passing as you must ( yes, best avoid repetitive passing those "large things" as parameters )
len( os.sched_getaffinity( 0 ) )
- any process more than this will but wait for its next CPU-core-slot, and will but evict other, cache-efficient process, thus re-paying all the fetch-costs once already paid to re-fetch again all data so to camp-em back in-cache for a soon to get evicted again in-cache computing, while those processes that worked so far this way were right evicted (for what good?) by a naive use of as many as multiprocessing.cpu_count()
-reported processes, so expensively spawned in the initial Pool
-creation )gc
which may block if not avoided, or Pool.map()
which blocks eitherB )
UNDERSTAND THE WAYS TO INCREASE THE EFFICIENCY :
Understand all efficiency increasing tricks, even at a cost of complexity of code ( a few SLOC-s are easy to show in school-books, yet sacrificing both the efficiency and the performance - in spite of these both being your main enemy in a fight for a sustainable performance throughout the scaling ( of either of problem size or iteration depths, or when growing both of them at the same time ).
Some categories of the real-world costs from A ) have dramatically changed the limits of the theoretically achievable speedups to be expected from going into some form of [PARALLEL]
process orchestrations ( here, making some parts of the code-execution got executed in the spawned sub-processes ), the initial view of which was first formulated by Dr. Gene Amdahl as early as 60+ years ago ( for which there were recently added two principal extensions of both the process instantiation(s) related setup + termination add on costs ( extremely important in py2 always & py3.5+ for MacOS and Windows ) and an atomicity-of-work
, which will be discussed below.
S = speedup which can be achieved with N processors
s = a proportion of a calculation, which is [SERIAL]
1-s = a parallelizable portion, that may run [PAR]
N = a number of processors ( CPU-cores ) actively participating on [PAR] processing
1
S = __________________________; where s, ( 1 - s ), N were defined above
( 1 - s ) pSO:= [PAR]-Setup-Overhead add-on cost/latency
s + pSO + _________ + pTO pTO:= [PAR]-Terminate-Overhead add-on cost/latency
N
1 where s, ( 1 - s ), N
S = ______________________________________________ ; pSO, pTO
| ( 1 - s ) | were defined above
s + pSO + max| _________ , atomicP | + pTO atomicP:= a unit of work,
| N | further indivisible,
a duration of an
atomic-process-block
1E+6
Any simplified mock-up example will somehow skew your expectations about how the actual workloads will perform in-vivo. Underestimated RAM-allocations, not seen at small-scales may later surprise at scale, sometimes even throwing the operating system into sluggish states, swapping and thrashing. Some smarter tools ( numba.jit()
) may even analyze the code and shortcut some passages of code, that will never be visited or that does not produce any result, so be warned that simplified examples may lead to surprising observations.
from multiprocessing import Pool
import numpy as np
import os
SCALE = int( 1E9 )
STEP = int( 1E1 )
aLIST = np.random.random( ( 10**3, 10**4 ) ).tolist()
#######################################################################################
# func() does some SCALE'd amount of work, yet
# passes almost zero bytes as parameters
# allocates nothing, but iterator
# returns one byte,
# invariant to any expensive inputs
def func( x ):
for i in range( SCALE ):
i**2
return 1
A few hints on making the strategy of scaling less overhead-costs expensive :
#####################################################################################
# more_work_en_block() wraps some SCALE'd amount of work, sub-list specified
def more_work_en_block( en_block = [ None, ] ):
return [ func( nth_item ) for nth_item in en_block ]
If indeed must pass a big list, better pass larger block, with remote-iterating its parts ( instead of paying transfer-costs for each and every item passed many many more times, than if using sub_blocks
( parameters get SER/DES processed ( ~ the costs of pickle.dumps()
+ pickle.loads()
) [per-each-call], again, at an add-on costs, that decrease the resulting efficiency and worsen the overheads part of the extended, overhead-strict Amdahl's Law )
#####################################################################################
# some_work_en_block() wraps some SCALE'd amount of work, tuple-specified
def some_work_en_block( sub_block = ( [ None, ], 0, 1 ) ):
return more_work_en_block( en_block = sub_block[0][sub_block[1]:sub_block[2]] )
aMaxNumOfProcessesThatMakesSenseToSPAWN = len( os.sched_getaffinity( 0 ) ) # never more
with Pool( aMaxNumOfProcessesThatMakesSenseToSPAWN ) as p:
p.imap_unordered( more_work_en_block, [ ( aLIST,
start,
start + STEP
)
for start in range( 0, len( aLIST ), STEP ) ] )
Last but not least, expect immense performance boosts from smart use of numpy
smart vectorised code, best without repetitive passing of static, pre-copied (during the process instantiation(s), thus paid as the reasonably scaled, here un-avoidable, cost of thereof ) BLOBs, used in the code without passing the same data via parameter-passing, in a vectorised ( CPU-very-efficient ) fashion as read-only data. Some examples on how one can make ~ +500 x
speedup one may read here or here, about but ~ +400 x
speedup or about a case of just about a ~ +100 x
speedup, with some examples of some problem-isolation testing scenarios.
Anyway, the closer will the mock-up code be to your actual workloads, the more sense the benchmarks will get to have ( at scale & in production ).
Good luck on exploring the World, as it is,
not as a dream if it were different,
not as a wish it were different or that we would like it to be
:o)
Facts and Science matter - both + together
Records of Evidence are the core steps forwards to achieve as high performance as possible,
not any Product Marketing,
not any Evangelisation Clans wars,
not any Blog-posts' chatter
At least don't say you was not warned
:o)
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