Concurrency is having two tasks run in parallel on separate threads. However, asynchronous methods run in parallel but on the same 1 thread. How is this achieved? Also, what about parallelism?
What are the differences between these 3 concepts?
Concurrent and parallel are effectively the same principle as you correctly surmise, both are related to tasks being executed simultaneously although I would say that parallel tasks should be truly multitasking, executed "at the same time" whereas concurrent could mean that the tasks are sharing the execution thread while still appearing to be executing in parallel.
Asynchronous methods aren't directly related to the previous two concepts, asynchrony is used to present the impression of concurrent or parallel tasking but effectively an asynchronous method call is normally used for a process that needs to do work away from the current application and we don't want to wait and block our application awaiting the response.
For example, getting data from a database could take time but we don't want to block our UI waiting for the data. The async call takes a call-back reference and returns execution back to your code as soon as the request has been placed with the remote system. Your UI can continue to respond to the user while the remote system does whatever processing is required, once it returns the data to your call-back method then that method can update the UI (or handoff that update) as appropriate.
From the User perspective, it appears like multitasking but it may not be.
It's probably worth adding that in many implementations an asynchronous method call will cause a thread to be spun up but it's not essential, it really depends on the operation being executed and how the response can be notified back to the system.
Concurrency means multiple tasks which start, run, and complete in overlapping time periods, in no specific order. Parallelism is when multiple tasks OR several part of a unique task literally run at the same time, e.g. on a multi-core processor.
Remember that Concurrency and parallelism are NOT the same thing.
Differences between concurrency vs. parallelism
Now let’s list down remarkable differences between concurrency and parallelism.
Concurrency is when two tasks can start, run, and complete in overlapping time periods. Parallelism is when tasks literally run at the same time, eg. on a multi-core processor.
Concurrency is the composition of independently executing processes, while parallelism is the simultaneous execution of (possibly related) computations.
Concurrency is about dealing with lots of things at once. Parallelism is about doing lots of things at once.
An application can be concurrent – but not parallel, which means that it processes more than one task at the same time, but no two tasks are executing at same time instant.
An application can be parallel – but not concurrent, which means that it processes multiple sub-tasks of a task in multi-core CPU at same time.
An application can be neither parallel – nor concurrent, which means that it processes all tasks one at a time, sequentially.
An application can be both parallel – and concurrent, which means that it processes multiple tasks concurrently in multi-core CPU at same time.
Concurrency is essentially applicable when we talk about minimum two tasks or more. When an application is capable of executing two tasks virtually at same time, we call it concurrent application. Though here tasks run looks like simultaneously, but essentially they MAY not. They take advantage of CPU time-slicing feature of operating system where each task run part of its task and then go to waiting state. When first task is in waiting state, CPU is assigned to second task to complete it’s part of task.
Operating system based on priority of tasks, thus, assigns CPU and other computing resources e.g. memory; turn by turn to all tasks and give them chance to complete. To end user, it seems that all tasks are running in parallel. This is called concurrency.
Parallelism does not require two tasks to exist. It literally physically run parts of tasks OR multiple tasks, at the same time using multi-core infrastructure of CPU, by assigning one core to each task or sub-task.
Parallelism requires hardware with multiple processing units, essentially. In single core CPU, you may get concurrency but NOT parallelism.
This is not related to Concurrency and parallelism, asynchrony is used to present the impression of concurrent or parallel tasking but effectively an asynchronous method call is normally used for a process that needs to do work away from the current application and we don't want to wait and block our application awaiting the response.
Concurrency is when the execution of multiple tasks is interleaved, instead of each task being executed sequentially one after another.
Parallelism is when these tasks are actually being executed in parallel.
Asynchrony is a separate concept (even though related in some contexts). It refers to the fact that one event might be happening at a different time (not in synchrony) to another event. The below diagrams illustrate what's the difference between a synchronous and an asynchronous execution, where the actors can correspond to different threads, processes or even servers.
Everyone is having trouble associating asynchronous to either parallelism or concurrency because asynchronous is not an antonym to either parallel or concurrent. It is an antonym of Synchronous. Which just indicates if something, in this case threads, will be synched with something else, in this case another thread.
There are several scenarios in which concurrency can occur:
Asynchrony— This means that your program performs non-blocking operations. For example, it can initiate a request for a remote resource via HTTP and then go on to do some other task while it waits for the response to be received. It’s a bit like when you send an email and then go on with your life without waiting for a response.
Parallelism— This means that your program leverages the hardware of multi-core machines to execute tasks at the same time by breaking up work into tasks, each of which is executed on a separate core. It’s a bit like singing in the shower: you’re actually doing two things at exactly the same time.
Multithreading— This is a software implementation allowing different threads to be executed concurrently. A multithreaded program appears to be doing several things at the same time even when it’s running on a single-core machine. This is a bit like chatting with different people through various IM windows; although you’re actually switching back and forth, the net result is that you’re having multiple conversations at the same time.
Concurrency means that an application is making progress on more than one task at the same time (concurrently). Well, if the computer only has one CPU the application may not make progress on more than one task at exactly the same time, but more than one task is being processed at a time inside the application. It does not completely finish one task before it begins the next.
Parallelism means that an application splits its tasks up into smaller subtasks which can be processed in parallel, for instance on multiple CPUs at the exact same time.
Concurrency vs. Parallelism In Detail
As you can see, concurrency is related to how an application handles multiple tasks it works on. An application may process one task at at time (sequentially) or work on multiple tasks at the same time (concurrently).
Parallelism on the other hand, is related to how an application handles each individual task. An application may process the task serially from start to end, or split the task up into subtasks which can be completed in parallel.
As you can see, an application can be concurrent, but not parallel. This means that it processes more than one task at the same time, but the tasks are not broken down into subtasks.
An application can also be parallel but not concurrent. This means that the application only works on one task at a time, and this task is broken down into subtasks which can be processed in parallel.
Additionally, an application can be neither concurrent nor parallel. This means that it works on only one task at a time, and the task is never broken down into subtasks for parallel execution.
Finally, an application can also be both concurrent and parallel, in that it both works on multiple tasks at the same time, and also breaks each task down into subtasks for parallel execution. However, some of the benefits of concurrency and parallelism may be lost in this scenario, as the CPUs in the computer are already kept reasonably busy with either concurrency or parallelism alone. Combining it may lead to only a small performance gain or even performance loss. Make sure you analyze and measure before you adopt a concurrent parallel model blindly.
Parallel : It's a broad term that means that two pieces of code execute that "at the same time" to the point where the parallel execution becomes "real". Sounds vague and simplistic? Yes. I'm trying to help you focus on the differences between those concepts rather than providing each individual technical definition.
So I wrote "real" because parallelism can be simulated to a certain degree. Many systems, for example games, implement "parallel" subsystems that perform lots of task during each execution loop (for example: some of them make extensive use of agents), but most of the time they're only parallel in the sense that they each do their little thing in no predictible order, access data seemingly randomly, and even if you implemented some sort of primitive software-based cooperative multitasking to organize the whole thing, it's still not really parallel. It's just a very complicated sequential system.
You might say that parallelism becomes real when there's a third-party system (whether be an underlying preemptive OS offering threads, or CPU cores) specifically designed to run code in black boxes that you can't control (except for the time at which they start and the result they produce, plus any mutex or semaphores you might throw in)
Concurrent : there can't be concurrency without parallelism (whether simulated or real, as I explained above), but this term focuses specifically on the fact that the two systems will try to access the same resource at the same time at some point. It puts the emphasis on the fact that you're going to have to deal with that.
Asynchronous : everyone is right by saying that asynchronous is unrelated with parallelism, but it paves the way to it (the burden is on you to make things parallel or not -- keep reading).
You might see this concept as a way to represent parallelism by formalizing the three basic things usually involved in parallelism : 1) define the task's initialization (say when it starts and what parameters it gets), 2) what must be done after it finishes and 3) What the code should continue doing inbetween.
But it's still only syntax (usually it's represented as callback methods). Behind the scene, the underlying system might simply decide that these so-called "tasks" are just fragments of code to pile up until it finishes the code it's currently executing. And then it unpiles them one by one and executes them sequentially. Or not. It might also create a thread per task and run them in parallel. Who cares? That part is not included in the concept ;)
CONCURRENCY VS PARALLELISM: concurrency at one point of time only one task can be done. example: single cpu processor parallelism at one point we can do multiple tasks. example: dual core or multi core processor
Here I explain with some examples
A web service receives many small requests in real-time and it needs to handle each of these requests differently as well as independent of other requests.
with different execution sequences (there can be multiple tasks or one task can be run differently in each call)
essentially reduces the response time
A GPU uses parallel processing to process the same block of code (AKA kernel) on thousands of physical and logical threads. Each kernel call sometimes uses a different block of memory for its read/write operations. Ideally, the process starts and ends for all threads at the same time. A single CPU core without hyperthreading cannot do parallel processing.
One heavy process (like an I/O operation) can easily block GUI if it's run on the GUI thread. In order to guarantee UI responsiveness, a heavy process can be executed asynchronously. It is better to run similar async operations one at a time. e.g. multiple IO-bound operations can be significantly slower if run at the same time, so it's better to queue them finish to start
Note: an async operation which is executed concurrently (i.e. more than once at a time) is a concurrent operation.
There's a bit of semantics to clear up here:
Concurrency or Parallelism is a question of resource contention, whereas Asynchronous is about control flow.
Different procedures (or their constituent operations) are termed Asynchronous, when there's no deterministic implementation of the the order of their processing; in other words, there's a probability that any of them could be processed at any given time T. By definition, multiple processors (e.g. CPUs or Persons) make it possible for several of them to be processed at the same time; on a single processor, their processing is interleaved (e.g. Threads).
Asynchronous procedures or operations are termed Concurrent, when they share resources; Concurrency is the definite possibility of contention at any given time T. Parallelism is trivially guaranteed when no resources are shared (e.g. different processor and storage); otherwise Concurrency control must be addressed.
Hence an Asynchronous procedure or operation may be processed in Parallel or Concurrently with others.