548 lines
26 KiB
Markdown
548 lines
26 KiB
Markdown
## PREALPHA
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## AuroraRuntime
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The Aurora Runtime is a low level platform abstraction layer for modern cross-platform C++
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development targeting powerful embedded and PC systems. Simply fetch a binary package for
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your toolchain or integrate the self-contained buildscripts into your applications build
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pipeline to get started.
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![console](https://gitea.reece.sx/AuroraSupport/AuroraRuntime/raw/branch/master/Media/wxHello.png)
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![picture](https://gitea.reece.sx/AuroraSupport/AuroraRuntime/raw/branch/master/Media/Hello%20Aurora.png)
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![picture](https://gitea.reece.sx/AuroraSupport/AuroraRuntime/raw/branch/master/Media/Hello%20Linux.png)
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## Features
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- Reduced C++ standard template library dependence despite requiring a modern-ish driver (^1) (portable when?)
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- Logging; UTF-8 logger, common sink backends, formating interface
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- Debug and Telementry; asserts, panics, exception logging, demangling of symbols, more
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- Crypto ECC/[25519, P-384, P-256], [AES, RSA, X509], CBC[AES, Stinky3DES], HMAC, HashCash, BCrypt, [common digests]
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- Basic cmdline parsing from any module
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- Exit and fatal save condition callbacks
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- Random; secure, user-seeded, and fast
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- Hardware Info; memory and cpu info (including cpu feature bits, core topology, e-core awareness, and basic cache size)
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- Software stack information for retrieving kernel, version, brand, family, build string, etc
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- Compression (deflate, gzip, zstd, LZ4, bzip2, TODO: lzma, brotli)
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- Locale and encoding
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- High performance threading and synchronization primitives (os userland sched optimized)
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- Async subsystem backed by high performance sync primitives (cv loop) and hybrid switching into IO polling (think userland cv-backed promises + waitmultipleobjects)
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- IO subsystem for standard cross-platform IO loop queues, IPC (mutex with auto-unlock, semaphores, full-duplex single-connection pipes, and shared memory), file (direct uncached access), and network
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- Abstract kernel IO transactions, IPC objects, timers, semaphores, and others in the form of ILoopSources
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- Common IO transaction interface for network, file, and handle async access (with workarounds for platform querks)
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- IO processor for common network, pipe processing, and general work on any given thread (think of it as an io context)
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- IO pipe processor for the processing of data when invoked by io transactions and other signalable interfaces
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- Protocol stack concept, for implementing low-overhead IO stream processors, where data is streamed through layers of interceptors
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- Builtin support for TLS and compression in the form of protocol stack interceptors
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- Non-locking file system watchers with IO subsystem interoperability
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- Process spawning with stream redirection backed by the IO subsystem
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- Process memory management with IPC and file mapping
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- FIO settings registry
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- C++ utility templates and macros
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- Follows all strings are UTF-8 convention
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^1 bring your own types [auROXTL](https://git.reece.sx/AuroraSupport/auROXTL)
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## Links
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API:
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* [Runtime](https://gitea.reece.sx/AuroraSupport/AuroraRuntime/src/branch/master/Include/Aurora)
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* [auROXTL](https://gitea.reece.sx/AuroraSupport/auROXTL/src/branch/master/Include)
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API Docs: \
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Tests and Examples: [Hello Aurora](https://gitea.reece.sx/AuroraSupport/HelloAurora) \
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Build Pipeline: [Aurora Build](https://git.reece.sx/AuroraPipeline/Build) (Lua/Premake) \
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Donate / Other Links: [Reece.SX](https://reece.sx/#contact) \
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Discord: [Invite](https://discord.gg/XYjCGWWa4J)
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## Support
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| Platform | Support |
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| ----------- | ------- |
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| NT/XP | ❌ |
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| NT/Win7 | ⚠️ |
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| NT/Win8.1+ | ⚠️ |
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| NT/Win10 RS4+ | ✅ |
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| NT/Win11 | ✅ |
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| NT/UWP | 🕖 |
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| NT/GameOS| ❌ |
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| Linux | ✅ |
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| FreeBSD 9 | ❌ |
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| FreeBSD 11 | ❌ |
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| OpenBSD | ❌ |
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| XNU/NS-like | ❌ |
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Win7/8: memory management (AuProcess) is limited. \
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Applications that don't need ::mmap-like functionality **with pre-reserved address allocations** should put your minimum requirements into the Vista era of NTs. \
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See: [Windows 7 defects](https://gitea.reece.sx/AuroraSupport/AuroraRuntime/src/branch/master/Media/Windows%207%20Defects.txt)
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## Performance
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Performance of each system should ideally be that of the best implementation on the platform,
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and no worse than the STL. Due to heavyweight requirements and spiral model defined objectives,
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a handful of unknown good industry standard libraries have been brought into achieve compression,
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crypto, alloc, and formatting objectives. Footprint is expected to be on the heavier side for optimal
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performance (incl toll for C++ tradeoffs), usability, and flexibility.
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Defer to benchmarks
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## Utilities
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Aurora Sugar: [Main Header](https://git.reece.sx/AuroraSupport/auROXTL/src/branch/master/Include/auROXTLUtils.hpp), [(*.)Utils.hpp](https://gitea.reece.sx/AuroraSupport/auROXTL/src/branch/master/Include/auROXTL) \
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Aurora Macro Sugar: [Main Header](https://git.reece.sx/AuroraSupport/auROXTL/src/branch/master/Include/auROXTL/AU_MACROS.hpp) \
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Aurora Overloadable Type Declerations: [Main Header](https://gitea.reece.sx/AuroraSupport/auROXTL/src/branch/master/Include/auROXTLTypes.hpp)
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## Logging
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Logging is implemented through 2 subsystems, console and logging. Console provides IO abstraction
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to the logger subsystem sinks. Sinks are user implementable interfaces that can be either synchronous
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or asynchronous. Loggers are defined as an internal object the takes logger messages and dumps
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them to the relevant subscriber.
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Flushing occurs at a fixed rate on a low prio background thread without any configuration requirement.
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The resources spent on the background thread is shared with the telemetry and debug subsystems to
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reduce the overall thread count of the runtime. Flushes also occur during panic events and other
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relevant problematic points.
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Asynchronous logger sinks may double buffer log lines between the asynchronous callback and
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OnFlush callback, where the latter call is guaranteed after one or more delegated dispatch. The
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Windows Event Log backend takes advantage of this to multi-line group messages by approx time
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and log level.
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Additionally, in the console subsystem, consoles that provide an input stream can be used in
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conjunction with the parse subsystem to provide basic command-based deserialization, tokenization,
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and dispatch of UTF-8 translated strings regardless of the system locale. Command processing
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comes under the namespace of consoles, not logging.
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## Exceptions
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![ICanHasStackTraces](https://gitea.reece.sx/AuroraSupport/AuroraRuntime/raw/branch/master/Media/ICanHasStackTraces.png)
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Through the use of compiler internal overloads, ELF hooking, and Win32
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`AddVectoredExceptionHandler`, Aurora Runtime hooks exceptions at the time of throw, including
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*some* out of ecosystem exceptions, providing detailed telemetry of the object type, object
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string, and backtrace. In addition, the `AuDebug` namespace provides TLS based last-error and
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last-backtrace methods. <br>
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EXCEPTIONS ARE NOT CONTROL FLOW...<br>
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- Aurora Runtime WILL attempt to mitigate exceptions in internal logic
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- Aurora Runtime WILL NOT abuse exceptions to communicate failure
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- Aurora Runtime WILL try to decouple internal exceptions from the API
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- Aurora Runtime WILL NOT use anything that automatically crashes on exception catch (no-noexcept)
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- Aurora Runtime WILL provide extended exception information to telemetry backends and through
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the `AuDebug` namespace
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- Aurora Runtime WILL NOT make any guarantees of being globally-noexcept; however, it should be a
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safe assumption in non-critical environments
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`SysPanic` can be used to format a `std::terminate`-like exit condition, complete with telemetry
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data and safe cleanup.
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## Thread Primitives
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The Aurora Runtime provides platform optimized threading primitives inheriting from a featureful
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IWaitable interface. Each method is guaranteed. Each primitive is user-land scheduler optimized.
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```
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struct IWaitable
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{
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virtual bool TryLock() = 0;
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virtual void Lock(relativeTimeoutInMilliseconds) = 0;
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virtual void Lock() = 0;
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virtual void Unlock() = 0;
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}
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```
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Included high performance primitives
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- arbitrary condition variable ^1
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- condition mutex
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- condition variable
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- critical section ^2
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- event
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- mutex
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- semaphore
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- rwlock ^3
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- spinlocks
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^1 Accepts __any__ IWaitable as the mutex \
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^2 Reentrant Mutex \
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^3 Includes extended read to write upgrades and permits write-entrant read-routines to prevent
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writer deadlocks.
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### Fixing problems in other scheduler apis
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Problem one (1): \
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Most STL implementations have generally awful to unnecessarily inefficient abstraction.
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Defer to libc++'s abuse of spin while (cond) yield loops and msvc/stl's painfully slow
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std::mutex and semaphore primitives.
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Problem Two (2): \
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Moving to or from linux, macos, bsd, and win32 under varous kernels, there is no one
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standard (even in posix land) for the key thread primitives.
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Bonus point NT (3): \
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The userland CriticalSection/CV set of APIs suck, lacking timeouts and try lock
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Bonus point UNIX (4): \
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No wait multiple mechanism
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1, 2, 3: Use the high performance AuThreadPrimitives objects
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4: Consider using loop sources, perhaps with the async subsystem, in your async application.
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Performance of loop sources will vary wildly between platforms, always being generally worse
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than the high performance primitives. They should be used to observe kernel-level signalable
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resources.
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4 ex: Windows developers could use loop sources as a replacement to WaitMultipleObjects with
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more overhead
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## IO
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The Aurora Runtime implements loop, file io, network io, and other sub-subsystems with
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various adapters and connectors.
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An important note about texting encoding. Stdin, file encoding, text decoders, and other IO
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resources work with codepage UTF-8 as the internal encoding scheme. String overloads and
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dedicated string APIs in the IO subsystem will always write BOM prefixed UTF-8, and attempt
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to read a BOM to translate any other arbitrary user generated text input to UTF-8.
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### Loop
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The Aurora Runtime implements a kernel-scheduler optimized IO loop subsystem for managing GUIs;
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network, file, ipc AIO; and thread synchronization objects for when these waitables converse.
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ILoopSource is an interface defined by the loop subsystem for IO objects with a signalable state.
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Attached to an ILoopQueue, the ILoopQueue will provide wait-any/wait-all/is-signaled polling with
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optional subscription functionality. Furthermore, ILoopQueues are thread-safe allowing for cross-thread
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or mid-wait work scheduling (as in, the addition of new subscribers during sleep or callback).
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It is possible to run loop queues like a poll object or with an arbitrary amount of optional
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subscribers per loop source.
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Subscription notifications allow for optimized loop source removal or no-action/non-removal replies
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from subscription implementer. If you and all other subscribers want to evict the ILoopSource,
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the source will be automatically removed from the ILoopQueue. If just you vote to evict, you will
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no longer receive updates for the object, but the ILoopSource and other subscribers will remain.
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### IPC
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Included in the IPC subsystem are pipes, as used by AuProcesses; events; mutexes; semaphores;
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and shared memory views. IPC objects are exported by an internally generated non-standard string
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which contains platform specific information to import such object in a compatible application.
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Aurora IPC is not bound by processes bound by a common worker, instead, UNIX sockets and procfs
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are used to implement IPC within the applications namespace/sandbox.
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### FIO
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A simple blocking file stream is provided by an open function given an Aurora path string and a
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file advisory lock level. This object can be used with AuProcess to map regions of the file into
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the address map. However, everything about this object is blocking.
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An alternative asynchronous IAsyncFileStream interface is available which supplies IO transaction
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objects for scheduling direct disk reads. One should be careful to note each platform has file AIO
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querks. For instance...
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- Linux will block on most file systems if metadata has to be poked
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- FS support is limited (NT/NTFS > Linux/XFS > NT/xxxx (w/ caching) > Linux/EXT4 > unsupported)
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- Read/Writes musts be made with respect to sector alignment
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- Removing caching on Linux will mitigate blocking behaviour (~O_DIRECT blocking io_submit)
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- ...but caching on Win32 is sometimes desirable
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- Linux reads might be limited by max_sectors_kb or max_segments
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For large block reads: \
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bDirectIO = true; read directly from fs (recommend) \
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offsets -> must align
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When data is small enough for file caches to be useful: \
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bDirectIO = !AuBuild::kIsNtDerived (recommend) \
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offsets -> align for the highest denominator
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Additional utility functions exist outside of the two file interfaces for: stat, directory iteration,
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UTF-8 string reading and writing, blocking binary read/writes, and more.
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### Paths
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We assume all paths are messy. Incorrect splitters, double splitters, relative paths, and keywords are resolved internally.
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No URL or path builder, data structure to hold a tokenized URI expression, or similar concept exists in the codebase.
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All string paths are simply expanded, similar to MSCRT's `fullpath` or UNIX's `realpath`, at time of usage.
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| Expression | Meaning |
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|------------------|-------------------------------------|
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| `Path[0] == '.'` | Current Working Directory |
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| `Path[0] == '^'` | Executable module's Directory |
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| `Path[0] == '~'` | User Profile Storage + SDK brand |
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| `Path[0] == '!'` | All User Shared Storage + SDK brand |
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| `..` | Go up a directory |
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| `/` | Agnostic Directory Splitter |
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| `\` | Agnostic Directory Splitter |
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| `.` [SPLITTER] | Nothing |
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### TLS
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TLS client and partial server support is provided by protocol stack interceptors meaning that our implementation is no-socket.
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It's possible to write into a buffered protocol stack using the provided stream writer, simulating data coming through a socket channel;
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and to fetch the response/translated message using an end protocol piece to be supplied with the data, or using the provided stream reader to read the end
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to read the end interceptors buffer once the protocol stack has been ticked.
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### Resources
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The Aurora Runtime provides system, application, and user specific paths under the `Aurora::IO::FS` subsystem.
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These include the users home directory, a per vendor sandboxed application user directory, a per vendor sandboxed application
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all users directory, the user-installable program directory, the user's real home directory, and other such relevant paths.
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### Networking
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### Character IO
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## Proccesses
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The Aurora Runtime provides child process monitoring, asynchronous child stdin/out/err transactions, child synchronization
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(via a primitive threading event and an io event), process spawning, file opening, and url opening functionality.
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## Locale
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Encoding and decoding of UTF-8, UTF-16, UTF-32, GBK, GB-2312, and SJIS is supported through OS provided decoders.
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System localization information, including system codepage, country, and system language, is provided by the available
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envrionment variables, OS specific interfaces, or the overload mechanism.
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## Memory
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### Allocator
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Objects are allocated across API/module boundaries using an ABI defined by Aurora Runtime.
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Such OOP design in contrast to header-everything is contingent on well-defined interface boundaries which make sense from a
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perspective of optimizaton (primarily allocation and indirect branching) and usability.
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Allocations are optimized by using a known good third party library, mimalloc. In the future, it should be possible to replace the
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standard allocator; however, for now all allocations are routed through Aurora::Memory which is backed by mi_xxxx calls.
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Mimalloc and/or other such slab and zone based allocators can and must be explored as an optimization for C++'s tendency to
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arbitrary allocate memory. This should improve the performance of reasonbly written modules with OOP in mind.
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Indirect branches are optimized by simply trying to design APIs that arent complete ass for humans and systems to work with.
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### Memory Heap
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Aurora provides a heap allocator for dividing up a large preallocated region of memory.
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Currently, we use a modified version of O(1) heap that provides a constant worst case allocation and deallocation
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of any given request. Memory is provided by AuProcess for the requested allocation, but AuMemory might be unfortunately
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hit during the initialization of a heap.
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### Shared Pointers
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Memory objects, including shared pointers, and the object allocation model is defined by AuROXTL. The `AuSPtr` class template
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is backed by the standard `std::shared_ptr`, extended by `#include <auROXTL/auMemoryModel.hpp>,` in the default configuration.
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The reason we wrap shared pointers is two folds
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1) in code that doesn't need to be fast, we can simply hack in is valid checks on assignment or use an interface with panic branches
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to handle null access conditions.
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2) in the future, it may be desirable to use established AuEnableSharedOnThis, AuSharedFromThis, etc idoms to migrate existing code
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to an alternative non-std::shared_ptr backed system.
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AuSPtr and friends are reducable and constructible from and from their std::shared_ptr/unique counterparts.
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```
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Types:
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AuSPtr<Type_t>
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AuWPtr<Type_t>
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AuUPtr<Type_t, Deleter_t>
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Functions:
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AuSPtr<T> AuMakeShared<T>(Args&& ...)
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AuSPtr<T> AuUnsafeRaiiToShared<T>(T *)
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AuSPtr<T> AuUnsafeRaiiToShared<T>(AuUPtr<T>)
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Macros:
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_new (pseudo no-throw new operator)
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AuSPtr<This_T> AuSharedFromThis()
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AuWPtr<This_T> AuWeakFromThis()
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AuFunction<...> AuBindThis(This_t *::?, ...)
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```
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Defer to [auROXTL](https://git.reece.sx/AuroraSupport/auROXTL) for more information
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## Debug
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### Asserts
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[TODO]
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#### Example:
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Debug, Release, and Ship (all) assertions:
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```cpp
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SysAssert(AuFunction{}, "unexpected default function")
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```
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Debug and Release (debug and optimized ship-with-debug) assertions:
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```cpp
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SysAssertDbg(AuFunction{}, "unexpected default function")
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```
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### Error stack
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```cpp
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TEST(ErrorStack, A)
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{
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AuErrorStack errors;
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SysPushErrorIO("Something something IO error");
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SysPushErrorIO("Something something IO error 1");
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SysPushErrorIO("Something something IO error 2 {}", "hello worlds");
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ASSERT_TRUE(errors.HasCaptured());
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ASSERT_TRUE(errors.HasMultipleOccurred());
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ASSERT_TRUE(errors.FirstMessage()->pNextThreadMesage);
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ASSERT_TRUE(errors.FirstMessage()->pNextThreadMesage->pNextThreadMesage);
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AuLogDbg("{}, {}, {}",
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*errors.ToString(),
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errors.FirstMessage()->pNextThreadMesage->ToString(),
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errors.FirstMessage()->pNextThreadMesage->pNextThreadMesage->ToString());
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}
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TEST(ErrorStack, B)
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{
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AuErrorStack errors;
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try
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{
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AU_THROW_FORMATTED("hello people {}", 23423423);
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//throw "hello modern platforms";
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}
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catch (...)
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{
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}
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ASSERT_TRUE(errors.HasCaptured());
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AuLogDbg("{}", *errors.ToString());
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}
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```
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[More](https://gitea.reece.sx/AuroraSupport/HelloAurora/src/branch/master/Tests/Public/19.%20Hello%20Debug/Main.cpp)
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## Binding
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Aurora Runtime provides C++ APIs; however, it should be noted that two libraries are used to extend interfaces and enums
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to help with porting and internal utility access. One, AuroraEnums, wraps basic enumerations and provides value vectors;
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value strings; look up; iteration; and more. The other, AuroraInterfaces, provides *TWO* class types for each virtual interface.
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Each interface can be backed by a; C++ class method overriding a superclass's `virtual ...(...) = 0;` method, or a `AuFunctional`
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-based structure.
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It should be noted that most language bindings and generator libraries (^swig, v8pp, nbind, luabind) work with shared pointers.
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Other user code may wish to stuff pointers into a machineword-sized space, whether its a C library, a FFI, or a size constraint.
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One handle or abstraction layer will be required to integrate the C++ API into the destination platform, and assuming we have a
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C++ language frontend parsing our API, we can use `AuSPtr` for all caller-to-method constant reference scanerios.
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Furthermore, `AuSPtrs` can be created, without a deletor, using `AuUnsafeRaiiToShared(unique/raw pointer)`. To solve the raw
|
|
pointer issue, `AuSPtrs` are created in the public headers with the help of exported/default visibility interface create and
|
|
destroy functions. These APIs provide raw pointers to public C++ interfaces, and as such, can be binded using virtually any
|
|
shim generator. Method and API mapping will likely involve manual work from the library developer to reimplement AU concepts
|
|
under their language runtime instead of using the C++ platform, or at least require manual effort to shim or map each runtime
|
|
prototype into something more sane across the language barrier.
|
|
|
|
Memory is generally viewed through a `std::span` like concept called MemoryViews. `MemoryViewRead` and `MemoryViewWrite`
|
|
provide windows into a defined address range. `MemoryViewStreamRead` and `MemoryViewStreamWrite` expand upon this concept by
|
|
accepting an additional offset (`AuUInt &: reference`) that is used by internal APIs to indicate how many bytes were written
|
|
or read from a given input region. Such requirement came about from so many APIs, networking, compression, encoding, doing the
|
|
exact same thing in different not-so-portable ways. Unifying memory access to 4 class types should aid with SWIG prototyping.
|
|
|
|
Unrelated note, structure interfacing with questionable C++ ABI reimplementations is somewhat sketchy in FFI projects (^ CppSharp)
|
|
can lead to some memory leaks.
|
|
|
|
|
|
## Aurora Async
|
|
|
|
[TODO]
|
|
- Promises
|
|
- Thread Pool
|
|
- Optional shutdown on work exhaustion
|
|
- Wait for task[s] completion builtin to work objects
|
|
- IO subsystem interop
|
|
|
|
Example:
|
|
|
|
## Strings
|
|
|
|
The auROXTL header only library defines an `AuString` type as an `std::string`; however, it should be assumed this type represents
|
|
a binary blob of UTF-8. Further locale processing is delegated to `Aurora::Locale[::Encoding]`
|
|
|
|
## Dependencies
|
|
|
|
Aurora
|
|
- [AuroraPipeline Include](https://git.reece.sx/AuroraPipeline/Include) ^2
|
|
- [auROXTL](https://git.reece.sx/AuroraSupport/auROXTL) ^2
|
|
- [AuroraEnum](https://git.reece.sx/AuroraSupport/AuroraEnum) ^1
|
|
- [AuroraInterfaces](https://git.reece.sx/AuroraSupport/AuroraInterfaces) ^1
|
|
- [AuroraForEach](https://git.reece.sx/AuroraSupport/AuroraForEach) ^1
|
|
|
|
Crypto (third party)
|
|
- [LibTomCrypt](https://git.reece.sx/AuroraMiddleware/libtomcrypt) / [LibTomMath](https://git.reece.sx/AuroraMiddleware/libtommath) ^5
|
|
- [mbedTLS](https://git.reece.sx/AuroraMiddleware/mbedtls)
|
|
|
|
Compression (third party)
|
|
- [zstd](https://git.reece.sx/AuroraMiddleware/zstd)
|
|
- [zlib](https://git.reece.sx/AuroraMiddleware/zlib)
|
|
- [bzip2](https://git.reece.sx/AuroraMiddleware/bzip2)
|
|
|
|
Utility (third party)
|
|
- [stduuid](https://git.reece.sx/AuroraMiddleware/stduuid) ^6
|
|
- [fmtlib](https://git.reece.sx/AuroraMiddleware/fmt) ^4 ^6
|
|
- [nl. json](https://git.reece.sx/AuroraMiddleware/nlohmannjson) ^6
|
|
|
|
|
|
^1 Include-only macro library \
|
|
^2 Provides core utilities and stl decoupling \
|
|
^3 Provides platform information, included by default by the Aurora build pipeline \
|
|
^4 C++ 20 saw another pathetic adoption attempt of an open source library, this one actually passed, but hardly \
|
|
anyone implements std::format. Not to mention such is only a subset of the original library. \
|
|
^5 Public Domain \
|
|
^6 Potentially STL heavy, still potentially portable w/ a modern-ish toolchain
|
|
|
|
|
|
## Philosophies
|
|
|
|
- Assume C++17 language support in the language driver
|
|
|
|
- Use AuXXX type bindings for std types, allow customers to overload the std namespace \
|
|
We assume *some* containers and utility APIs exist, but where they come from is up to you
|
|
|
|
- Keep the code and build chain simple such that any C++ developer could maintain
|
|
their own software stack built around aurora components.
|
|
|
|
- Dependencies and concepts should be cross-platform, cross-architecture, cross-ring friendly
|
|
|
|
It is recommended to fork and replace any legacy OS specific code with equivalent
|
|
AuroraRuntime concepts, introducing a circular dependency with the Aurora Runtime
|
|
|
|
APIs shouldn't be designed around userland, mobile computing, or desktop computing;
|
|
AuroraRuntime must provide a common backbone for all applications.
|
|
|
|
Locale and user-info APIs will be limited due to the assumption userland is not a
|
|
concept
|
|
|
|
- Dependencies, excluding core reference algorithms (eg compression), must be rewritten
|
|
and phased out over time.
|
|
|
|
- Dependencies should not be added if most platforms provide some degree of native support<br>
|
|
Examples:<br>
|
|
-> Don't depend on a pthread shim for windows; implement the best thread <br>
|
|
primitives that lie on the best possible api for them <br>
|
|
-> Don't depend on ICU when POSIX's iconv and Win32's multibyte apis cover<br>
|
|
everything a conservative developer cares about; chinese, utf-16, utf-8,<br>
|
|
utf-32 conversion, on top of all the ancient windows codepages
|
|
|
|
- Dependencies should only be added conservatively when it saves development time and
|
|
provides production hardening <br>
|
|
Examples:<br>
|
|
-> Use embedded crypto libraries; libtomcrypt, libtommath<br>
|
|
->> While there are some bugs in libtomcrypt and others, none appear to <br>
|
|
cryptographically cripple the library. Could you do better?<br>
|
|
-> Use portable libraries like mbedtls, O(1) heap, mimalloc<br>
|
|
->> Writing a [D]TLS/allocator stack would take too much time<br>
|
|
->> Linking against external allocators, small cross-platform utilities, and <br>
|
|
so on is probably fine <br>
|
|
-> Shim libcurl instead of inventing yet another http stack <br> |