X-Git-Url: https://bilbo.iut-bm.univ-fcomte.fr/and/gitweb/book_gpu.git/blobdiff_plain/f69f75dd5354fe34ad3b1360af061a8f1aebb9aa..c3b7094dd3736e534d20ccb83621a4f8aff0472c:/BookGPU/Chapters/chapter1/ch1.tex diff --git a/BookGPU/Chapters/chapter1/ch1.tex b/BookGPU/Chapters/chapter1/ch1.tex index 9a3f4eb..42b018c 100755 --- a/BookGPU/Chapters/chapter1/ch1.tex +++ b/BookGPU/Chapters/chapter1/ch1.tex @@ -10,7 +10,11 @@ This chapter introduces the Graphics Processing Unit (GPU) architecture and all the concepts needed to understand how GPUs work and can be used to speed up the execution of some algorithms. First of all this chapter gives a brief history of the development of Graphics card until they can be used in order to make general -purpose computation. +purpose computation. Then the architecture of a GPU is illustrated. There are +many fundamental differences between a GPU and a tradition processor. In order +to benefit from the power of a GPU, a CUDA programmer needs to use threads. They +have some particularities which enables the CUDA model to be efficient and +scalable when some constraints are addressed. @@ -23,9 +27,9 @@ repetitive and very specific. Hence, some manufacturers have produced more and more sofisticated video cards, providing 2D accelerations then 3D accelerations, then some light transforms. Video cards own their own memory to perform their computation. From at least two dedaces, every personnal computer has a video -card which a simple for desktop computers or which provides many accelerations +card which is simple for desktop computers or which provides many accelerations for game and/or graphic oriented computers. In the latter case, graphic cards -may be more expensive than the CPU. +may be more expensive than a CPU. After 2000, video cards allowed to apply arithmetics operations simulatenously on a sequence of pixels, also later called stream processing. In this case, @@ -33,7 +37,7 @@ information of the pixels (color, location and other information) are combined in order to produce a pixel color that can be displayed on a screen. Simultaneous computations are provided by shaders which calculate rendering effects on graphics hardware with a high degree of flexibility. These -shaders handles the stream data with pipelines +shaders handles the stream data with pipelines. Some reasearchers tried to apply those operations on other data, representing @@ -70,12 +74,13 @@ comparison with OpenCL, interested readers may refer to~\cite{ch1:CMR:12}. \section{Architecture of current GPUs} -Architecure of current GPUs is constantly evolving. Nevertheless some trends -remains true through this evolution. Processing units composing a GPU are far -more simpler than a traditional CPU but it is much easier to integrate many -computing units inside a GPU card than many cores inside a CPU. This is due to -the fact that cores of a GPU a simpler than cores of a CPU. In 2012, the most -powerful GPUs own more than 500 cores and the most powerful CPUs have 8 +Architecture \index{Architecture of a GPU} of current GPUs is constantly +evolving. Nevertheless some trends remains true through this +evolution. Processing units composing a GPU are far more simpler than a +traditional CPU but it is much easier to integrate many computing units inside a +GPU card than many cores inside a CPU. This is due to the fact that cores of a +GPU are simpler than cores of a CPU. In 2012, the most powerful GPUs own more +than 500 cores and the most powerful CPUs have 8 cores. Figure~\ref{ch1:fig:comparison_cpu_gpu} shows the number of cores inside a CPU and inside a GPU. In fact, in a current NVidia GPU, there are multiprocessors which have 32 cores (for example on Fermi cards). The core clock @@ -99,7 +104,7 @@ get maximum performance. On most powerful GPU cards, called Fermi, multiprocessors are called streaming multiprocessors (SM). Each SM contains 32 cores and is able to perform 32 floating point or integer operations on 32bits numbers per clock or 16 floating -point on 64bits number per clock. SM have their own registers, execution +point on 64bits number per clock. SMs have their own registers, execution pipelines and caches. On Fermi architecture, there are 64Kb shared memory + L1 cache and 32,536 32bits registers per SM. More precisely the programmer can decide what amount of shared memory and L1 cache SM can use. The constaint is @@ -119,7 +124,9 @@ through the use of cache memories. Moreover, nowadays CPUs perform many performance optimizations such as speculative execution which roughly speaking consists in executing a small part of code in advance even if later this work reveals to be useless. In opposite, GPUs do not have low latency memory. In -comparison GPUs have ridiculous cache memories. Nevertheless the architecture of GPUs is optimized for throughtput computation and it takes into account the memory latency. +comparison GPUs have ridiculous cache memories. Nevertheless the architecture of +GPUs is optimized for throughtput computation and it takes into account the +memory latency. @@ -145,13 +152,13 @@ computation of other tasks. \section{Kinds of parallelism} Many kinds of parallelism are avaible according to the type of hardware. -Roughtly speaking, there are three classes of parallism: instruction-level -parallelism, data parallelism and task parallelism. +Roughtly speaking, there are three classes of parallelism: instruction-level +parallelism, data parallelism and task parallelism. Instruction-level parallelism consists in re-ordering some instructions in order -to executed some of them in parallel without changing the result of the code. +to execute some of them in parallel without changing the result of the code. In modern CPUs, instruction pipelines allow processor to execute instruction -faster. With a pipeline a processor can execute multiple instruction +faster. With a pipeline a processor can execute multiple instructions simultaneously due to the fact that the output of a task is the input of the next one. @@ -162,24 +169,28 @@ data parallelism paradigm. This paradigm is linked with the Single Instructions Multiple Data (SIMD) architecture. This is the kind of parallism providing by GPUs. -Taks parallelism is the common parallism achieved out on cluster and grid and -high performance architecture where different tasks are executed by different +Taks parallelism is the common parallism achieved out on clusters and grids and +high performance architectures where different tasks are executed by different computing units. \section{CUDA Multithreading} The data parallelism of CUDA is more precisely based on the Single Instruction -Multiple Thread (SIMT) model. This is due to the fact that the programmer access +Multiple Thread (SIMT) model. This is due to the fact that a programmer accesses to the cores by the intermediate of threads. In the CUDA model, all cores execute the same set of instructions but with different data. This model has similarities with vector programming model proposed for vector machines through the 1970s into the 90s, notably the various Cray platforms. On the CUDA architecture, the performance is led by the use of a huge number of threads (from thousand upto to millions). The particularity of the model is that there -is no context switching as in CPUs and each thread has its own registers. In practice, threads are executed by SM and are gathered into groups of 32 threads. Those groups are call ``warps''. Each SM alternatively executes ``active warps'' and warps becoming temporaly inactive due to waiting of data (as shown in Figure~\ref{ch1:fig:latency_throughput}). +is no context switching as in CPUs and each thread has its own registers. In +practice, threads are executed by SM and are gathered into groups of 32 +threads. Those groups are call ``warps''. Each SM alternatively executes +``active warps'' and warps becoming temporaly inactive due to waiting of data +(as shown in Figure~\ref{ch1:fig:latency_throughput}). The key to scalability in the CUDA model is the use of a huge number of threads. -In practice threads are not only gathered in warps but also in thread blocks. A +In practice, threads are not only gathered in warps but also in thread blocks. A thread block is executed by only one SM and it cannot migrate. Typical size of thread block is a number power of two (for example: 64, 128, 256 or 512). @@ -187,7 +198,7 @@ thread block is a number power of two (for example: 64, 128, 256 or 512). In this case, without changing anything inside a CUDA code, it is possible to run your code with a small CUDA device or most performant Tesla CUDA cards. -Blocks are executed in any number depending on the number of SM available. So +Blocks are executed in any order depending on the number of SMs available. So the programmer must conceive its code having this issue in mind. This independence between threads blocks provides the scalability of CUDA codes. @@ -198,43 +209,56 @@ independence between threads blocks provides the scalability of CUDA codes. \end{figure} -A kernel is a function which contains a block a instruction that are executed by -threads of a GPU. When the problem considered is a 2 dimensions or 3 dimensions -problem, it is possible to group thread blocks into grid. In practice, the -number of thread blocks and the size of thread block is given in parameter to -each kernel. Figure~\ref{ch1:fig:scalability} illustrates an example of a -kernel composed of 8 thread blocks. Then this kernel is executed on a small -device containing only 2 SMs. So in in this case, blocks are executed 2 by 2 in -any order. If the kernel is executed on a larger CUDA device containing 4 SMs, -blocks are executed 4 by 4 simultaneously. The execution times should be +A kernel is a function which contains a block of instructions that are executed +by the threads of a GPU. When the problem considered is a 2 dimensions or 3 +dimensions problem, it is possible to group thread blocks into grid. In +practice, the number of thread blocks and the size of thread block is given in +parameter to each kernel. Figure~\ref{ch1:fig:scalability} illustrates an +example of a kernel composed of 8 thread blocks. Then this kernel is executed on +a small device containing only 2 SMs. So in in this case, blocks are executed 2 +by 2 in any order. If the kernel is executed on a larger CUDA device containing +4 SMs, blocks are executed 4 by 4 simultaneously. The execution times should be approximately twice faster in the latter case. Of course, that depends on other parameters that will be described later. Thread blocks provide a way to cooperation in the sens that threads of the same block cooperatively load and store blocks of memory they all use. Synchronizations of threads in the same block are possible (but not between -thread of different blocks). Threads of the same block can also share results in -order to compute a single result. In chapter~\ref{chapter2}, some examples will -explicit that. +threads of different blocks). Threads of the same block can also share results +in order to compute a single result. In chapter~\ref{chapter2}, some examples +will explicit that. \section{Memory hierarchy} -The memory hierarchy of GPUs is different from the one of CPUs. In practice, -there is registers, local memory, shared memory, cache memroy and global memory. +The memory hierarchy of GPUs\index{Memory~hierarchy} is different from the CPUs +one. In practice, there are registers\index{Memory~hierarchy!registers}, local +memory\index{Memory~hierarchy!local~memory}, shared +memory\index{Memory~hierarchy!shared~memory}, cache +memory\index{Memory~hierarchy!cache~memory} and global +memory\index{Memory~hierarchy!global~memory}. + As previously mentioned each thread can access its own registers. It is important to keep in mind that the number of registers per block is limited. On recent cards, this number is limited to 64Kb per SM. Access to registers is very fast, so when possible it is a good idea to use them. -Likewise each thread can access local memory which in practice much slower than -registers. In practice, local memory is automatically used by the compiler when -all the registers are occupied. So the best idea is to optimize the use of -registers even if this implies to reduce the number of threads per block. +Likewise each thread can access local memory which, in practice, is much slower +than registers. Local memory is automatically used by the compiler when all the +registers are occupied. So the best idea is to optimize the use of registers +even if this implies to reduce the number of threads per block. + +\begin{figure}[hbtp!] +\centerline{\includegraphics[scale=0.60]{Chapters/chapter1/figures/memory_hierarchy.pdf}} +\caption[Memory hierarchy of a GPU]{Memory hierarchy of a GPU.} +\label{ch1:fig:memory_hierarchy} +\end{figure} + + Shared memory allows cooperation between threads of the same block. This kind -of memory is fast by it requires to be manipulated manually and its size is +of memory is fast because it requires to be manipulated manually and its size is limited. It is accessible during the execution of a kernel. So the principle is to fill the shared memory at the start of the kernel with global data that are used very frequently, then threads can access it for their computation. They @@ -248,11 +272,7 @@ shared memory is attributed to a kernel. The cache memory is a L1 cache which is directly managed by the GPU. Sometimes, this cache provides very efficient result and sometimes the use of shared memory is a better solution. -\begin{figure}[b!] -\centerline{\includegraphics[scale=0.60]{Chapters/chapter1/figures/memory_hierarchy.pdf}} -\caption[Memory hierarchy of a GPU]{Memory hierarchy of a GPU.} -\label{ch1:fig:memory_hierarchy} -\end{figure} + Figure~\ref{ch1:fig:memory_hierarchy} illustrates the memory hierarchy of a @@ -262,6 +282,13 @@ the shared memory of this block. The cache memory is not represented here but it is local to a thread. Then each block can access to the global memory of the GPU. + \section{Conclusion} + +In this chapter, a brief presentation of the video card, which later have been +used to perform computation, has been given. The architecture of a GPU has been +illustrated focusing on the particularity of GPUs in term of parallelism, memory +latency and threads. In order to design an efficient algorithm for GPU, it is +essential to have all these parameters in mind. %%http://people.maths.ox.ac.uk/gilesm/pp10/lec2_2x2.pdf %%https://people.maths.ox.ac.uk/erban/papers/paperCUDA.pdf