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I just implemented an algorithm on the GPU that computes the difference btw consecutive indices of an array. I compared it with a CPU based implementation and noticed that for large sized array, the GPU based implementation performs faster.

I am curious WHY does the GPU based implementation perform faster. Please note that i know the surface reasoning that a GPU has several cores and can thus do the operation is parallel i.e., instead of visiting each index sequentially, we can assign a thread to compute the difference for each index.

But can someone tell me a deeper reason as to why GPU's perform faster. What is so different about their architecture that they can beat a CPU based implementation

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This is a "how long is a piece of string?" question -- there is no single answer. What algorithm? What GPU? What CPU? For your trivial differencing example, the kernel is memory bandwidth limited, so the answer is probably "your GPU has more memory bandwidth than your CPU". –  talonmies Feb 11 '12 at 8:53
It's a bit like asking, "Why does a bus carry more people (analogous to bandwidth) than a car? Please note that I already know that a bus has several seats and can thus carry multiple people at the same time, but can someone tell me a deeper reason as to why they can carry more people?" Well, they carry more people because, well, they carry more people... –  Mehrdad Feb 11 '12 at 8:56
@talonmies: What does memory bandwidth limited mean? Please help –  Programmer Feb 11 '12 at 16:49
As the name implies, memory bandwidth limited means that the overall performance of the code is limited by the maximum throughput of the devices memory. The memory throughput of the GPU is the performance bottleneck. –  talonmies Feb 11 '12 at 17:05

3 Answers 3

up vote 4 down vote accepted

They don't perform faster, generally.

The point is: Some algorithms fit better into a CPU, some fit better into a GPU.

The execution model of GPUs differs (see SIMD), the memory model differs, the instruction set differs... The whole architecture is different.

There are no obvious way to compare a CPU versus a GPU. You can only discuss whether (and why) the CPU implementation A of an algorithm is faster or slower than a GPU implementation B of this algorithm.

This ended up kind of vague, so a tip of an iceberg of concrete reasons would be: The strong side of CPU is random memory access, branch prediction, etc. GPU excels when there's a high amount of computation with high data locality, so that your implementation can achieve a nice ratio of compute-to-memory-access. SIMD makes GPU implementations slower than CPU where there's a lot of unpredictable braching to many code paths, for example.

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The real reason is that a GPU not only has several cores, but it has many cores, typically hundreds of them! Each GPU core however is much slower than a low-end CPU.

But the programming mode is not at all like multi-cores CPUs. So most programs cannot be ported to or take benefit from GPUs.

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why was this downvoted? –  IanNorton Feb 11 '12 at 9:27

While some answers have already been given here and this is an old thread, I just thought I'd add this for posterity and what not:

The main reason that CPU's and GPU's differ in performance so much for certain problems is design decisions made on how to allocate the chip's resources. CPU's devote much of their chip space to large caches, instruction decoders, peripheral and system management, etc. Their cores are much more complicated and run at much higher clock rates (which produces more heat per core that must be dissipated.) By contrast, GPU's devote their chip space to packing as many floating-point ALU's on the chip as they can possibly get away with. The original purpose of GPU's was to multiply matricies as fast as possible (because that is the primary type of computation involved in graphics rendering.) Since matrix multiplication is an embarrasingly parallel problem (e.g. each output value is computed completely independently of every other output value) and the code path for each of those computations is identical, chip space can be saved by having several ALU's follow the instructions decoded by a single instruction decoder, since they're all performing the same operations at the same time. By contrast, each of a CPU's cores must have its own separate instruction decoder since the cores are not following identical code paths, which makes each of a CPU's cores much larger on the die than a GPU's cores. Since the primary computations performed in matrix multiplication are floating-point multiplication and floating-point addition, GPU's are implemented such that each of these are single-cycle operations and, in fact, even contain a fused multiply-and-add instruction that multiplies two numbers and adds the result to a third number in a single cycle. This is much faster than a typical CPU, where floating-point multiplication is often a many-cycle operation. Again, the trade-off here is that the chip space is devoted to the floating-point math hardware and other instructions (such as control flow) are often much slower per core than on a CPU or sometimes even just don't exist on a GPU at all.

Also, since GPU cores run at much lower clock rates than typical CPU cores and don't contain as much complicated circuitry, they don't produce as much heat per core (or use as much power per core.) This allows more of them to be packed into the same space without overheating the chip and also allows a GPU with 1,000+ cores to have similar power and cooling requirements to a CPU with only 4 or 8 cores.

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