What do the terms "CPU bound" and "I/O bound" mean?
It's pretty intuitive:
A program is CPU bound if it would go faster if the CPU were faster, i.e. it spends the majority of its time simply using the CPU (doing calculations). A program that computes new digits of π will typically be CPU-bound, it's just crunching numbers.
A program is I/O bound if it would go faster if the I/O subsystem was faster. Which exact I/O system is meant can vary; I typically associate it with disk. A program that looks through a huge file for some data will often be I/O bound, since the bottleneck is then the reading of the data from disk.
CPU Bound means the rate at which process progresses is limited by the speed of the CPU. A task that performs calculations on a small set of numbers, for example multiplying small matrices, is likely to be CPU bound.
I/O Bound means the rate at which a process progresses is limited by the speed of the I/O subsystem. A task that processes data from disk, for example, counting the number of lines in a file is likely to be I/O bound.
Memory bound means the rate at which a process progresses is limited by the amount memory available and the speed of that memory access. A task that processes large amounts of in memory data, for example multiplying large matrices, is likely to be Memory Bound.
Cache bound means the rate at which a process progress is limited by the amount and speed of the cache available. A task that simply processes more data than fits in the cache will be cache bound.
I/O Bound would be slower than Memory Bound would be slower than Cache Bound would be slower than CPU Bound.
The solution to being I/O bound isn't necessarily to get more Memory. In some situations, the access algorithm could be designed around the I/O, Memory or Cache limitations. See Cache Oblivious Algorithms.
CPU bound means the program is bottlenecked by the CPU, or central processing unit, while I/O bound means the program is bottlenecked by I/O, or input/output, such as reading or writing to disk, network, etc.
In general, when optimizing computer programs, one tries to seek out the bottleneck and eliminate it. Knowing that your program is CPU bound helps, so that one doesn't unnecessarily optimize something else.
[And by "bottleneck", I mean the thing that makes your program go slower than it otherwise would have.]
Another way to phrase the same idea:
(I used "may be" because you need to take other resources into account. Memory is one example.)
When your program is waiting for I/O (ie. a disk read/write or network read/write etc), the CPU is free to do other tasks even if your program is stopped. The speed of your program will mostly depend on how fast that IO can happen, and if you want to speed it up you will need to speed up the I/O.
If your program is running lots of program instructions and not waiting for I/O, then it is said to be CPU bound. Speeding up the CPU will make the program run faster.
In either case, the key to speeding up the program might not be to speed up the hardware, but to optimize the program to reduce the amount of IO or CPU it needs, or to have it do I/O while it also does CPU intensive stuff.
I/O bound refers to a condition in which the time it takes to complete a computation is determined principally by the period spent waiting for input/output operations to be completed.
This is the opposite of a task being CPU bound. This circumstance arises when the rate at which data is requested is slower than the rate it is consumed or, in other words, more time is spent requesting data than processing it.
IO bound processes: spend more time doing IO than computations, have many short CPU bursts. CPU bound processes: spend more time doing computations, few very long CPU bursts
multi-threading is a case where the distinction matters as explained on the examples below.
RAM I/O bound example
If your input is large and the calculation small, you are going to memory bound, which is one type of I/O bottleneck
Parallelizing your program is useless here if you are on a mainstream desktop computer where all processors sit behind a single bus linking to RAM: the bus is the bottleneck.
A simple example is summing up an array of integers from memory:
Parallelizing that by splitting the big array for each of your cores does not lead to a significant speedup.
Also, the cache is not going to help, since we are just reading each value once.
CPU bound example
If the input is small, but you do a lot of operations on it, then we are CPU bound, and multi-threading can actually divide the runtime by the number of processors.
A real life example, would be solving an ordinary differential equation with the Euler method for a few different initial conditions and an analytic function.
The only input taken from memory is the initial condition, and the rest is just number crunching the steps in the CPU registers and cache. It would look something like:
If we run one initial condition case in each processor, the time will be divided by the number of processors.
I have created two simple C++ benchmarks to test points mentioned in this answer:
Tested on GCC 5.2.1, Ubuntu 15.10 with a 4 core Intel i5-3210M.
Have an idea of real latencies
You should keep in mind the relative operation latencies: http://www.eecs.berkeley.edu/~rcs/research/interactive_latency.html
I/O Bound process:- If most part of the lifetime of a process is spent in i/o state, then the process is a i/o bound process.example:-calculator,internet explorer
CPU Bound process:- If most part of the process life is spent in cpu,then it is cpu bound process.