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  • If youre familiar with Deep Learning, then I’m sure youve heard a lot of talk about

  • the importance of GPUs. GPUs are a powerful tool for training deep nets, and nearly every

  • software library supports them. But when it comes to speeding up the training process,

  • there are several alternatives to GPUs that are worth considering. Let’s take a closer

  • look.

  • The CPU in your computer is capable of performing many different tasks across a wide variety

  • of domains. But this versatility comes at a costCPUs require sophisticated control

  • mechanisms in order to manage the flow of tasks. The CPU is also designed to perform

  • tasks seriallyone after anotherrather than in parallel. Parallelism can also be

  • achieved by building in a limited number of cores directly into the CPU.

  • These cores are also versatile, but they need to be created with general-purpose computing in mind. You

  • may have also noticed that CPU clock speeds haven’t improved much over the last few

  • years, even though there have been some minor improvements with CPU memory. Since training

  • a deep net requires so many computational resources, a CPU is impractical for large-scale

  • deep nets.

  • So if a lone CPU isn’t powerful enough for the job, what can we use to train a deep net

  • in a reasonable time window? There are a few tricks we can use, one of which is to implement

  • deep nets using vectors. Vector algebralike addition, dot products, and transposesare

  • all operations that can be performed in parallel. Take the dot product for exampleEach multiplication

  • step can be performed in parallel, and the resulting products can then be added together.

  • Through the use of a parallel implementation, deep nets can be trained orders of magnitude

  • faster. Parallelism implemented at the hardware level is known as parallel processing, and

  • parallelism at the software level is parallel programming.

  • Parallel processing can be broken down into two general categoriesshared memory,

  • and distributed computing. Let’s start by looking at a few shared memory options.

  • The first option is the GPU, a popular tool in the world of deep learning. Unlike a CPU,

  • where the number of built-in cores is typically in the single or double digits, GPUs implement

  • 100s and sometimes even 1000s of cores. Each GPU core is versatile, and capable of general-purpose

  • parallel computing. Any task that can be implemented in parallel, can be performed on a GPU. With

  • regards to deep nets, the most popular application for GPUs is the training process. The Deep

  • Learning community provides great support for GPUs through libraries, implementations,

  • and a vibrant ecosystem fostered by nVidia. Despite all their advantages, GPUs do come

  • with one big drawback. Their versatility and general-purpose design leads to extremely

  • high power consumption. This becomes a significant issue for large scale deep nets, like the

  • ones that are used by the tech giants.

  • One alternative to the GPU is theField Programmable Gate Array”, or FPGA. FPGAs

  • are highly configurable, and they were originally used by electrical engineers to build mock-ups

  • of different chip designsthat way the engineers could test different solutions to a given

  • problem, without having to actually design a chip each time. FPGAs allow you to tweak

  • the chip’s function at the lowest level, which is the logic gate. So an FPGA can be

  • tailored specifically for a deep net application, allowing them to consume much less power than

  • a GPU. But there’s an additional benefit, since FPGAs can be used to run a deep net

  • model and generate predictions. This would come in handy if, for example, you needed

  • to run a large-scale convolutional net across 1000s of images per second. So FPGAs are a

  • great tool, but their big strengththat is, their configurabilitycan also be somewhat

  • of a weakness. To properly setup and configure an FPGA, an engineer would need highly-specialized

  • knowledge in digital and integrated circuit design.

  • Another option is anApplication Specific Integrated Circuit”, or ASIC. ASICs are

  • highly specialized with designs built in at the hardware and integrated circuit level.

  • Once built they will perform very well at the task they were designed for but are generally

  • unusable at any other tasks. Compared to GPUs and FGPAs, ASICs tend to have the lowest power

  • consumption requirements. There are several Deep Learning ASICs such as the Google Tensor

  • Processing Unit TPU, and the chip being built by Nervana Systems.

  • Aside from shared memory, parallelism can also be implemented using distributed computing.

  • Generally speaking, the three options for distributed computing are data parallelism,

  • model parallelism, and pipeline parallelism.

  • Data parallelism allows you to train different subsets of the data on different nodes in

  • a cluster for each training pass. This is followed by parameter averaging and replacement

  • across the cluster. We saw model parallelism with TensorFlow, where different portions

  • of the model are trained on different devices in parallel.

  • Pipeline Parallelism works like a production assembly line. Generally, there will be a

  • number of jobs to be completed, each of which can be broken up into independent tasks. Each

  • task for a given job will be dedicated to a worker, ensuring that each worker is relatively

  • well-utilized. When a worker finishes its task, it can move on to a task for another

  • job down the line, even if the other workers are still working on the current job. Here

  • is an example of a job involving 4 tasks, each of which is dedicated to a worker. When

  • worker 1 finishes task 1 for the first job, worker 1 can start working on a task for job

  • 2. Worker 2 may still be working on task 2 for job 1, and when worker 2 finishes and

  • moves to job 2, worker 3 may still be working on task 3 for job 1, and so on. Even though

  • this is a bit simplified and processing times can be variable in practice, this example

  • should illustrate the concept of pipeline parallelism.

  • Computer scientists have been researching parallel programming for decades, and in that

  • time theyve developed a set of advanced techniques. Most of these are beyond the scope

  • of this video, but the main idea is that designing algorithms with parallelism in mind will allow

  • you to take full advantage of the parallelism capabilities of the hardware. Let’s look

  • at three general ways to parallelize your codenote that this is an extensive area

  • of computer science, so we are not providing an exhaustive list.

  • The first method is to decompose your data model into chunks, where each chunk is needed

  • to perform an instance of a task. In this example, we see a data table where each row

  • represents a chunk of data that is independent from the others. By organizing your data in

  • this manner, each row can be used as an input in parallel.

  • The second method is to identify tasks that have dependencies, and place them into a single

  • group. By creating multiple groups that have no dependencies on one another, you can process

  • the final job in parallel by dividing up the groups.

  • The third method is to implement threads and processes that handle different tasks or task

  • groups. This method can be performed independently, but the performance benefits can be significant

  • when combined with the second method.

  • If you want to learn more about this topic, a great resource is the Open HPI Massive Open

  • Online Course on Parallel Programming.

  • Hopefully by now, you have a better understanding of the available options for training deep

  • nets in parallel. Next up, well take a look at the use of deep neural networks for

  • Text Analytics.

If youre familiar with Deep Learning, then I’m sure youve heard a lot of talk about

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ディープネットパフォーマンス 第24話(ディープラーニングSIMPLIFIED (Deep Net Performance - Ep. 24 (Deep Learning SIMPLIFIED))

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    alex に公開 2021 年 01 月 14 日
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