C# is quite a bit more than just enhanced C if you remove GC-reliant features as the generics and interface constraints enable a huge subset of features, alongside SIMD API, stack-allocated buffers and all sorts of memory wrappable in Span<T>s, which almost every method in the standard library that works on some sort of buffer accepts nowadays instead of plain arrays.
You can also manually allocate objects - there are multiple ways to go about it and even with the presence of GC, there is a "hidden" but supported API to register a NonGC heap that GC understands when scanning object references.
Though effective targeting is limited to much fewer count of platforms. Mono can target as low as ARMv6 but CoreCLR/NativeAOT mainly work with x86, x86_64, ARM and ARM64. For microcontrollers you are better off using Rust in my opinion. But for anything bigger .NET can be a surprisingly capable choice.
C# is quite a bit more than just enhanced C if you remove GC-reliant features as the generics and interface constraints enable a huge subset of features, alongside SIMD API, stack-allocated buffers and all sorts of memory wrappable in Span<T>s, which almost every method in the standard library that works on some sort of buffer accepts nowadays instead of plain arrays.
You can also manually allocate objects - there are multiple ways to go about it and even with the presence of GC, there is a "hidden" but supported API to register a NonGC heap that GC understands when scanning object references.
Though effective targeting is limited to much fewer count of platforms. Mono can target as low as ARMv6 but CoreCLR/NativeAOT mainly work with x86, x86_64, ARM and ARM64. For microcontrollers you are better off using Rust in my opinion. But for anything bigger .NET can be a surprisingly capable choice.