StyleCopAnalyzers
.NET Runtime
StyleCopAnalyzers | .NET Runtime | |
---|---|---|
30 | 612 | |
2,588 | 14,231 | |
1.0% | 2.2% | |
8.7 | 10.0 | |
4 days ago | 5 days ago | |
C# | C# | |
MIT License | MIT License |
Stars - the number of stars that a project has on GitHub. Growth - month over month growth in stars.
Activity is a relative number indicating how actively a project is being developed. Recent commits have higher weight than older ones.
For example, an activity of 9.0 indicates that a project is amongst the top 10% of the most actively developed projects that we are tracking.
StyleCopAnalyzers
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Configure Renovate to update preview versions of NuGet packages
By default, Renovate ignores preview versions of dependencies. For NuGet, a preview version is a package whose version contains a semantic suffix such as -alpha, -beta, -rc. There are some well-known NuGet packages that are only available in preview versions. For example, Aspire.Hosting will likely remain in preview until the release of .NET 9, StyleCop.Analyzers has been in beta for already 5 years, while OpenTelemetry.Instrumentation.GrpcNetClient and Azure.AI.OpenAI have never had a stable version.
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StyleCopAnalyzers VS Metalama - a user suggested alternative
2 projects | 7 Dec 2023
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Optimizing C# code analysis for quicker .NET compilation
Several well-known NuGet packages such as xUnit.net, FluentAssertions, StyleCop, Entity Framework Core, and others include by default a significant number of Roslyn analyzers. They help you adhere to the conventions and best practices of these libraries.
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Enhancing Your Open-Source Project with Static Analysis Tools
I created a StyleCopAnalysers.ruleset file at the root of my project, which contains the ruleset for analysis. The tool not only identifies issues but also attempts to fix them, providing a log of any unresolved problems. In addition to running the analyzer upon build, the dotnet format command also runs any external analyzers that it detects by default as well.
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What C# feature blew your mind when you learned it?
https://github.com/DotNetAnalyzers/StyleCopAnalyzers the successor to stylecop - most of the rules ported over
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Code Styling should be enforced by default
I'm a C# guy, so that is what I care about. For .NET we do have StyleCop analyzers. And EditorConfig exists to help at the IDE level across all languages. And git itself can be configured with such things as eol and autoclrf.
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Dotnet Format
I'd also like to know how to clean up based on rules like SA1507 - never more than one blank line in a row, and related rules to remove blank likes after { and before }
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C# finding wasted instantiations
StyleCop is from Microsoft: https://github.com/DotNetAnalyzers/StyleCopAnalyzers
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Using Roslyn Analyzers for static code analysis
Using their own APIs, Roslyn Analyzers verifies certain conditions about the source code and, if necessary, feeds back into the compiler in the form of compilation warnings and errors. An example would be StyleCop.
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What NuGet packages do you automatically add
StyleCop.Analyzers
.NET Runtime
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The search for easier safe systems programming
.NET has explicit tailcalls - they are heavily used by and were made for F#.
https://learn.microsoft.com/en-us/dotnet/api/system.reflecti...
https://github.com/dotnet/runtime/blob/main/docs/design/feat...
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Arena-Based Parsers
The description indicates it is not production ready, and is archived at the same time.
If you pull all stops in each respective language, C# will always end up winning at parsing text as it offers C structs, pointers, zero-cost interop, Rust-style struct generics, cross-platform SIMD API and simply has better compiler. You can win back some performance in Go by writing hot parts in Go's ASM dialect at much greater effort for a specific platform.
For example, Go has to resort to this https://github.com/golang/go/blob/4ed358b57efdad9ed710be7f4f... in order to efficiently scan memory, while in C# you write the following once and it compiles to all supported ISAs with their respective SIMD instructions for a given vector width: https://github.com/dotnet/runtime/blob/56e67a7aacb8a644cc6b8... (there is a lot of code because C# covers much wider range of scenarios and does not accept sacrificing performance in odd lengths and edge cases, which Go does).
Another example is computing CRC32: you have to write ASM for Go https://github.com/golang/go/blob/4ed358b57efdad9ed710be7f4f..., in C# you simply write standard vectorized routine once https://github.com/dotnet/runtime/blob/56e67a7aacb8a644cc6b8... (its codegen is competitive with hand-intrinsified C++ code).
There is a lot more of this. Performance and low-level primitives to achieve it have been an area of focus of .NET for a long time, so it is disheartening to see one tenth of effort in Go to receive so much spotlight.
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Airline keeps mistaking 101-year-old woman for baby
It's an interesting "time is a circle" problem given that a century only has 100 years and then we loop around again. 2-digit years is convenient for people in many situations but they are very lossy, and horrible for machines.
It reminds me of this breaking change to .Net from last year.[1][2] Maybe AA just needs to update .Net which would pad them out until the 2050's when someone born in the 1950s would be having...exactly the same problem in the article. (It is configurable now so you could just keep pushing it each decade, until it wraps again).
Or they could use 4-digit years.
[1] https://github.com/dotnet/runtime/issues/75148
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The software industry rapidly convergng on 3 languages: Go, Rust, and JavaScript
These can also be passed as arguments to `dotnet publish` if necessary.
Reference:
- https://learn.microsoft.com/en-us/dotnet/core/deploying/nati...
- https://github.com/dotnet/runtime/blob/main/src/coreclr/nati...
- https://github.com/dotnet/runtime/blob/5b4e770daa190ce69f402... (full list of recognized keys for IlcInstructionSet)
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The Performance Impact of C++'s `final` Keyword
Yes, that is true. I'm not sure about JVM implementation details but the reason the comment says "virtual and interface" calls is to outline the difference. Virtual calls in .NET are sufficiently close[0] to virtual calls in C++. Interface calls, however, are coded differently[1].
Also you are correct - virtual calls are not terribly expensive, but they encroach on ever limited* CPU resources like indirect jump and load predictors and, as noted in parent comments, block inlining, which is highly undesirable for small and frequently called methods, particularly when they are in a loop.
* through great effort of our industry to take back whatever performance wins each generation brings with even more abstractions that fail to improve our productivity
[0] https://github.com/dotnet/coreclr/blob/4895a06c/src/vm/amd64...
[1] https://github.com/dotnet/runtime/blob/main/docs/design/core... (mind you, the text was initially written 18 ago, wow)
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Java 23: The New Features Are Officially Announced
If you care about portable SIMD and performance, you may want to save yourself trouble and skip to C# instead, it also has an extensive guide to using it: https://github.com/dotnet/runtime/blob/69110bfdcf5590db1d32c...
CoreLib and many new libraries are using it heavily to match performance of manually intensified C++ code.
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Locally test and validate your Renovate configuration files
DEBUG: packageFiles with updates (repository=local) "config": { "nuget": [ { "deps": [ { "datasource": "nuget", "depType": "nuget", "depName": "Microsoft.Extensions.Hosting", "currentValue": "7.0.0", "updates": [ { "bucket": "non-major", "newVersion": "7.0.1", "newValue": "7.0.1", "releaseTimestamp": "2023-02-14T13:21:52.713Z", "newMajor": 7, "newMinor": 0, "updateType": "patch", "branchName": "renovate/dotnet-monorepo" }, { "bucket": "major", "newVersion": "8.0.0", "newValue": "8.0.0", "releaseTimestamp": "2023-11-14T13:23:17.653Z", "newMajor": 8, "newMinor": 0, "updateType": "major", "branchName": "renovate/major-dotnet-monorepo" } ], "packageName": "Microsoft.Extensions.Hosting", "versioning": "nuget", "warnings": [], "sourceUrl": "https://github.com/dotnet/runtime", "registryUrl": "https://api.nuget.org/v3/index.json", "homepage": "https://dot.net/", "currentVersion": "7.0.0", "isSingleVersion": true, "fixedVersion": "7.0.0" } ], "packageFile": "RenovateDemo.csproj" } ] }
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Chrome Feature: ZSTD Content-Encoding
https://github.com/dotnet/runtime/issues/59591
Support zstd Content-Encoding:
- Writing x86 SIMD using x86inc.asm (2017)
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Why choose async/await over threads?
We might not be that far away already. There is this issue[1] on Github, where Microsoft and the community discuss some significant changes.
There is still a lot of questions unanswered, but initial tests look promising.
Ref: https://github.com/dotnet/runtime/issues/94620
What are some alternatives?
Roslynator - Roslynator is a set of code analysis tools for C#, powered by Roslyn.
Ryujinx - Experimental Nintendo Switch Emulator written in C#
csharpier - CSharpier is an opinionated code formatter for c#.
ASP.NET Core - ASP.NET Core is a cross-platform .NET framework for building modern cloud-based web applications on Windows, Mac, or Linux.
omnisharp-roslyn - OmniSharp server (HTTP, STDIO) based on Roslyn workspaces
actix-web - Actix Web is a powerful, pragmatic, and extremely fast web framework for Rust.
Roslyn - The Roslyn .NET compiler provides C# and Visual Basic languages with rich code analysis APIs.
WASI - WebAssembly System Interface
format - Home for the dotnet-format command
CoreCLR - CoreCLR is the runtime for .NET Core. It includes the garbage collector, JIT compiler, primitive data types and low-level classes.
codeformatter - Tool that uses Roslyn to automatically rewrite the source to follow our coding styles
vgpu_unlock - Unlock vGPU functionality for consumer grade GPUs.