GPU uses the SIMD paradigm, that is, the same portion of code will be executed in parallel, and applied to various elements of a data set.

However, CPU also uses SIMD, and provide instruction-level parallelism. For example, as far as I know, SSE-like instructions will process data elements with parallelism.

While the SIMD paradigm seems to be used differently in GPU and CPU, does GPUs have more SIMD power than CPUs?

In which way the parallel computational capabilities in a CPU are 'weaker' than the ones in a GPU?

  • 1
    Instruction-level parallelism is when two instructions are independent, so a CPU can run them both in the same clock cycle. That's orthogonal to SIMD data parallelism. You want to write code that can take advantage of both, e.g. to execute vector FMA instructions at 2 per clock cycle, with each instruction doing 8 float FMAs, for a total throughput of 16 float FMA ops per clock. Data parallelism can be exposed to a CPU via SIMD x ILP x threads. Commented May 26, 2020 at 18:28

2 Answers 2


Both CPUs & GPUs provide SIMD with the most standard conceptual unit being 16 bytes/128 bits; for example a Vector of 4 floats (x,y,z,w).


CPUs then parallelize more through pipelining future instructions so they proceed faster through a program. Then next step is multiple cores which run independent programs.

GPUs on the other hand parallelize by continuing the SIMD approach and executing the same program multiple times; both by pure SIMD where a set of programs execute in lock step (which is why branching is bad on a GPU, as both sides of an if statement must execute; and one result be thrown away so that the lock step programs proceed at the same rate); and also by single program, multiple data (SPMD) where groups of the sets of identical programs proceed in parallel but not necessarily in lock step.

The GPU approach is great where the exact same processing needs be applied to large volumes of data; for example a million vertices than need to be transformed in the same way, or many million pixels that need the processing to produce their colour. Assuming they don't become data block/pipeline stalled, GPUs programs general offer more predictable time bound execution due to its restrictions; which again is good for temporal parallelism e.g. the programs need to repeat their cycle at a certain rate for example 60 times a second (16ms) for 60 fps.

The CPU approach however is better for decisioning and performing multiple different tasks at the same time and dealing with changing inputs and requests.

Apart from its many other uses and purposes, the CPU is used to orchestrate work for the GPU to perform.


It's a similar idea, it goes kind of like this (very informally speaking):

  • The CPU has a set amount of functions that can run on packed values. Depending on your brand and version of your CPU, you might have access to SSE2, 3, 4, 3dnow, etc, and each of them gives you access to more and more functions. You're limited by the register size and the larger data types you work with the less values you can use in parallel. You can freely mix and match SIMD instructions with traditional x86/x64 instructions.
  • The GPU lets you write your entire pipeline for each pixel of a texture. The texture size doesn't depend on your pipeline length, ie the number of values you can affect in one cycle isn't dependant on anything but your GPU, and the functions you can chain (your pixel shader) can be pretty much anything. It's somewhat more rigid though in that the setup and readback of your values is somewhat slower, and it's a one shot process (load values, run shader, read values), you can't massage them at all besides that, so you actually need to use a lot of values for it to be worth it.
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    Underlying hardware is quite similar between CPUs and GPUs. GPUs hide the underlying SIMD design better via masking the inactive threads out. With CPUs, you have to explicitly manage which lanes are active. Btw, AVX-512 adds mask registers which makes it more GPU-like.
    – void_ptr
    Commented Dec 9, 2014 at 0:19
  • 2
    The shape of it is similar, but the sheer number of cores and "register sizes" (ie, texture sizes) GPUs have make them pretty different beasts altogether.
    – Blindy
    Commented Dec 9, 2014 at 5:51

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