The ranges library of C 20 makes processing containers and data streams more intuitive and concise, and at the core is the range and view mechanisms. 1. It supports chain calls, which connects filtering, conversion and other operations to reduce boilerplate code; 2. The view does not copy data, but transforms or filters as needed, such as filter, transform, take, etc.; 3. Common views include views::filter, views::transform, views::take, views::iota, views::reverse, views::join; 4. Note when using: the view results are not saved, the type derivation is complex, the performance varies according to the access frequency, and confirms the compiler support.
What is the use of the ranges library of C 20? Simply put, it makes processing containers and data streams more intuitive and concise. In the past, we used algorithms to write code with iterators. Now we can call it directly in a chain, stringing up operations such as filtering and conversion like writing pipelines. The logic is clear and there is less writing a lot of boilerplate code.
What are ranges?
ranges is a new feature introduced by the C 20 standard library, and its full name is Range-based algorithms. Its core is a concept called "range", which can be understood as an object that supports begin() and end(), such as vector, array, and even strings.
But what makes ranges really great is the view (view) mechanism it provides. The view does not copy the data, but transforms or filters the original data and calculates it as needed. For example, you can filter out even numbers first and then take the first 5. The whole process is like a pipeline operation in functional programming.
For example:
auto result = views::iota(1, 10)
| views::filter([](int i){ return i % 2 == 0; })
| views::take(3);This code generates integers from 1 to 9, filters even numbers, and then takes only the first three. The result is {2,4,6}.
What are the common views?
C 20 provides many out-of-the-box views, and the following are the most commonly used:
-
views::filter: filter elements by conditional -
views::transform: Convert each element -
views::take(n)/views::drop(n): take/skip the first n elements -
views::iota(a, b): generates a sequence from a to b-1 -
views::reverse: invert range -
views::join: Connect multiple subranges
These views can be put together like building blocks, for example:
for (int i : myvec | views::filter(pred) | views::transform(func)) {
// deal with}Note that view is lazy to evaluate and will only actually perform operations during traversal.
What should you pay attention to when using it in actual use?
Although ranges are convenient, some details are easy to get stuck:
- Do not save the result of the view : the view is a reference semantic. Once the original data is released, the view will be invalid.
- Type derivation is complex : Each view combination will produce different anonymous types, and the specific types may not be visible during debugging.
- Performance impact varies by case : Although data is not copied, it may be a little slower than traditional loops if accessed frequently.
- Compiler support needs to be confirmed : Not all compilers fully support ranges, MSVC supports it early, and GCC and Clang are also supported in newer versions.
If you are writing performance-sensitive code or need to be cross-platform compatible with older compilers, then use it with caution. Otherwise, ranges are a good choice in terms of logical clarity and development efficiency.
Basically that's it. By mastering a few common views, you can write clearer data processing logic.
The above is the detailed content of C 20 ranges library explained. For more information, please follow other related articles on the PHP Chinese website!
Hot AI Tools
Undress AI Tool
Undress images for free
Undresser.AI Undress
AI-powered app for creating realistic nude photos
AI Clothes Remover
Online AI tool for removing clothes from photos.
Clothoff.io
AI clothes remover
Video Face Swap
Swap faces in any video effortlessly with our completely free AI face swap tool!
Hot Article
Hot Tools
Notepad++7.3.1
Easy-to-use and free code editor
SublimeText3 Chinese version
Chinese version, very easy to use
Zend Studio 13.0.1
Powerful PHP integrated development environment
Dreamweaver CS6
Visual web development tools
SublimeText3 Mac version
God-level code editing software (SublimeText3)
Using std::chrono in C
Jul 15, 2025 am 01:30 AM
std::chrono is used in C to process time, including obtaining the current time, measuring execution time, operation time point and duration, and formatting analysis time. 1. Use std::chrono::system_clock::now() to obtain the current time, which can be converted into a readable string, but the system clock may not be monotonous; 2. Use std::chrono::steady_clock to measure the execution time to ensure monotony, and convert it into milliseconds, seconds and other units through duration_cast; 3. Time point (time_point) and duration (duration) can be interoperable, but attention should be paid to unit compatibility and clock epoch (epoch)
How to get a stack trace in C ?
Jul 07, 2025 am 01:41 AM
There are mainly the following methods to obtain stack traces in C: 1. Use backtrace and backtrace_symbols functions on Linux platform. By including obtaining the call stack and printing symbol information, the -rdynamic parameter needs to be added when compiling; 2. Use CaptureStackBackTrace function on Windows platform, and you need to link DbgHelp.lib and rely on PDB file to parse the function name; 3. Use third-party libraries such as GoogleBreakpad or Boost.Stacktrace to cross-platform and simplify stack capture operations; 4. In exception handling, combine the above methods to automatically output stack information in catch blocks
What is a POD (Plain Old Data) type in C ?
Jul 12, 2025 am 02:15 AM
In C, the POD (PlainOldData) type refers to a type with a simple structure and compatible with C language data processing. It needs to meet two conditions: it has ordinary copy semantics, which can be copied by memcpy; it has a standard layout and the memory structure is predictable. Specific requirements include: all non-static members are public, no user-defined constructors or destructors, no virtual functions or base classes, and all non-static members themselves are PODs. For example structPoint{intx;inty;} is POD. Its uses include binary I/O, C interoperability, performance optimization, etc. You can check whether the type is POD through std::is_pod, but it is recommended to use std::is_trivia after C 11.
How to call Python from C ?
Jul 08, 2025 am 12:40 AM
To call Python code in C, you must first initialize the interpreter, and then you can achieve interaction by executing strings, files, or calling specific functions. 1. Initialize the interpreter with Py_Initialize() and close it with Py_Finalize(); 2. Execute string code or PyRun_SimpleFile with PyRun_SimpleFile; 3. Import modules through PyImport_ImportModule, get the function through PyObject_GetAttrString, construct parameters of Py_BuildValue, call the function and process return
What is function hiding in C ?
Jul 05, 2025 am 01:44 AM
FunctionhidinginC occurswhenaderivedclassdefinesafunctionwiththesamenameasabaseclassfunction,makingthebaseversioninaccessiblethroughthederivedclass.Thishappenswhenthebasefunctionisn’tvirtualorsignaturesdon’tmatchforoverriding,andnousingdeclarationis
How to pass a function as a parameter in C ?
Jul 12, 2025 am 01:34 AM
In C, there are three main ways to pass functions as parameters: using function pointers, std::function and Lambda expressions, and template generics. 1. Function pointers are the most basic method, suitable for simple scenarios or C interface compatible, but poor readability; 2. Std::function combined with Lambda expressions is a recommended method in modern C, supporting a variety of callable objects and being type-safe; 3. Template generic methods are the most flexible, suitable for library code or general logic, but may increase the compilation time and code volume. Lambdas that capture the context must be passed through std::function or template and cannot be converted directly into function pointers.
What is a null pointer in C ?
Jul 09, 2025 am 02:38 AM
AnullpointerinC isaspecialvalueindicatingthatapointerdoesnotpointtoanyvalidmemorylocation,anditisusedtosafelymanageandcheckpointersbeforedereferencing.1.BeforeC 11,0orNULLwasused,butnownullptrispreferredforclarityandtypesafety.2.Usingnullpointershe
How does std::move work in C ?
Jul 07, 2025 am 01:27 AM
std::move does not actually move anything, it just converts the object to an rvalue reference, telling the compiler that the object can be used for a move operation. For example, when string assignment, if the class supports moving semantics, the target object can take over the source object resource without copying. Should be used in scenarios where resources need to be transferred and performance-sensitive, such as returning local objects, inserting containers, or exchanging ownership. However, it should not be abused, because it will degenerate into a copy without a moving structure, and the original object status is not specified after the movement. Appropriate use when passing or returning an object can avoid unnecessary copies, but if the function returns a local variable, RVO optimization may already occur, adding std::move may affect the optimization. Prone to errors include misuse on objects that still need to be used, unnecessary movements, and non-movable types
