What is interprocess communication (IPC)?

This is a recommends products dialog
Top Suggestions
Starting at
View All >
Language
French
English
ไทย
German
繁體中文
Hi
All
Register & Shop at Lenovo Pro
Register at Education Store
Delete icon Remove icon Add icon Reload icon
TEMPORARILY UNAVAILABLE
DISCONTINUED
Temporary Unavailable
Cooming Soon!
. Additional units will be charged at the non-eCoupon price. Purchase additional now
We're sorry, the maximum quantity you are able to buy at this amazing eCoupon price is
Sign in or Create an Account to Save Your Cart!
Sign in or Create an Account to Join Rewards
View Cart
Your cart is empty! Don’t miss out on the latest products and savings — find your next favorite laptop, PC, or accessory today.
Remove
item(s) in cart
Some items in your cart are no longer available. Please visit cart for more details.
has been deleted
Please review your cart as items have changed.
of
Contains Add-ons
Subtotal
Proceed to Checkout
Yes
No
Popular Searches
Hamburger Menu
Outlet
skip to main content
All


What is interprocess communication (IPC)?

IPC refers to the mechanisms and techniques used by programs running on a computer to communicate and share data with each other. IPC enables different processes or applications to exchange information, coordinate their activities, and work together to accomplish a specific task.

Why is IPC important in computing?

IPC is essential in computing because it allows different programs to collaborate and interact with each other. Without IPC, programs would run in isolation and wouldn't be able to communicate, limiting their functionality. IPC enables processes to share data, synchronize their actions, and coordinate their operations, leading to more powerful and interconnected software systems.

How does IPC work?

IPC works by providing a set of communication mechanisms and protocols that processes can use to exchange information. These mechanisms can be categorized into various types, including shared memory, message passing, pipes, sockets, and remote procedure calls (RPC). Each IPC mechanism has its own characteristics and usage patterns, but they all serve the purpose of facilitating communication between processes.

What is shared memory in IPC?

Shared memory is an IPC mechanism where multiple processes can access and modify a common region of memory. This shared memory region allows processes to share data efficiently and communicate with each other by reading from and writing to the same memory area. By using shared memory, processes can avoid the overhead of copying data between different address spaces and achieve faster communication.

What is an example of shared memory usage in IPC?

Imagine you have two processes, Process A and Process B, that need to share a large data structure. Instead of copying the data back and forth between the processes, you can allocate a shared memory region that both processes can access. Process A can write data to the shared memory, and Process B can read and process that data directly from the shared memory, eliminating the need for data duplication and improving performance.

What is message passing in IPC?

Message passing is an IPC mechanism where processes communicate by sending and receiving messages. In this approach, processes explicitly send messages to each other, which can contain data or control information. The receiving process then processes the message and takes appropriate actions based on its content. Message passing allows processes to communicate in a more controlled and structured manner.

How does message passing work in IPC?

In message passing, processes typically use a messaging interface, or a messaging library provided by the operating system or programming language to send and receive messages. The sender constructs a message, specifies the destination process or endpoint, and sends the message. The receiving process waits for incoming messages and retrieves them from a message queue or mailbox. The message content can be processed, and the receiving process can respond accordingly.

What are pipes in IPC?

Pipes are a type of IPC mechanism that enables communication between processes by connecting the output of one process to the input of another process. Pipes can be either anonymous or named. Anonymous pipes are created dynamically by the operating system, while named pipes have a persistent name and can be used for communication between unrelated processes.

Can I provide an example of pipe usage in IPC?

Sure, let's say you have two programs, Program A and Program B. Program A generates a stream of data that needs to be processed by Program B. You can create an anonymous pipe, where the output of Program A is connected to the input of Program B. Program A writes the data into the pipe, and Program B reads the data from the pipe, processing it as needed. The pipe acts as a conduit for the data flow between the two programs.

What are sockets in IPC?

Sockets are a networking-oriented IPC mechanism that enables communication between processes running on different computers connected over a network. Sockets provide a standardized interface for processes to establish connections, send and receive data, and close connections. They are widely used for communication in client-server architectures and distributed systems.

What is an example of socket usage in IPC?

Let's say you are building a client-server application. The server program listens for incoming connections on a specific network port, using a socket. When a client wants to communicate with the server, it establishes a connection to the server's socket. The client and server can then exchange data bidirectionally through the established connection, allowing them to communicate and collaborate over the network.

What are remote procedure calls (RPC) in IPC?

RPC are a high-level IPC mechanism that enables processes or programs to invoke procedures or functions in remote processes as if they were local. RPC hides the complexities of low-level communication and enables transparent communication between processes running on different machines. It allows developers to write distributed applications as if they were writing programs that run locally.

How do remote procedure calls (RPC) work?

In RPC, the client program makes a procedure call to a remote server program, as if it were calling a local function. The RPC system takes care of packaging the procedure parameters, sending them over the network to the server, and executing the remote procedure. The server processes the request and returns the results, which are then returned to the client program. The communication details are abstracted away, providing a seamless interface for remote procedure invocation.

What are some common use cases for IPC?

IPC is used in a wide range of scenarios. Some common use cases include:

  • Process coordination: Processes can use IPC to synchronize their actions and coordinate their activities. For example, a producer-consumer pattern can be implemented using IPC, where one process produces data, and another process consumes it.
  • Interacting with external processes: IPC allows programs to communicate with external processes or services. This is often seen in client-server architectures, where clients communicate with servers to request services or exchange data.
  • Parallel computing: IPC enables communication and data sharing between parallel processes or threads. This is particularly important in multi-core or distributed systems, where parallel execution is used to improve performance.
  • Interprocess synchronization: IPC mechanisms like semaphores, mutexes, and condition variables are used to coordinate access to shared resources among multiple processes.
{"pageComponentDataId":"e857fdeft7e51-4b61-84dc-bccec6e68e00","pageComponentId":"e857fdeft7e51-4b61-84dc-bccec6e68e00","isAssociatedRelease":"true","pageComponentDataLangCode":"en_au","configData":{"jumpType":"currentTab","headlineColor":"black","displayNumber":"","styleMode":"vertical","miniCardHoMode":"2","headline":"","products":[{"number":{"t_id":"21kccto1wwau5","language":{"en_nz":"21kccto1wwau5","en_au":"21kccto1wwau5","en":""},"id":"Pageb33ce4b8-4839-4ba3-b993-7296d68a91b8"}},{"number":{"t_id":"21mccto1wwau3","language":{"en_nz":"21mccto1wwau3","en_au":"21mccto1wwau3","en":""},"id":"Page1fa61927-074c-4fe0-a8df-5c94362fb75c"}},{"number":{"t_id":"21lkcto1wwau3","language":{"en_nz":"21lkcto1wwau3","en_au":"21lkcto1wwau3","en":""},"id":"Pageca014688-410e-439a-a4c6-bba2ef6d4715"}},{"number":{"t_id":"21g2cto1wwau3","language":{"en_nz":"21g2cto1wwau3","en_au":"21g2cto1wwau3","en":""},"id":"Page79cd32c8-d467-4d68-b955-d273bb24eda7"}}]},"urlPrefix":"AAAAAAAH","title":"glossary-right-blue-boxes-fragment","pageId":"65b55929-de05-417a-a92a-ccb888d329b0","urlEdit":0,"uri":"/FragmentDirectory/glossary/glossary-right-blue-boxes-fragment.frag","pageComponentUuid":"e857fdeft7e51-4b61-84dc-bccec6e68e00"}
coming coming
Starting at
List Price
Web Price
Web Price:
List Price
Web Price
List Price is Lenovo’s estimate of product value based on the industry data, including the prices at which first and third-party retailers and etailers have offered or valued the same or comparable products. Third-party reseller data may not be based on actual sales.
Web Price is Lenovo’s estimate of product value based on industry data, including the prices at which Lenovo and/or third-party retailers and e-tailers have offered or valued the same or comparable products. Third-party data may not be based on actual sales.
Learn More
See More
See Less
View {0} Model
View {0} Models
Part Number:
Features
See More
See Less
compare
Added!
Great choice!
You may compare up to 4 products per product category (laptops, desktops, etc). Please de-select one to add another.
View Your Comparisons
Add To Cart
Add To Cart
We're sorry,
Products are temporarily unavailable.
Continue shopping
Learn More
Coming Soon
Featured Product
Top Deals of the Day
Oops! No results found. Visit the categories above to find your product.
Save
open in new tab
© 2024 Lenovo. All rights reserved.
© {year} Lenovo. All rights reserved.
Compare  ()
x