8839075805
Implements Phases 1-8 of the TFTSR implementation plan. Rust backend (Tauri 2.x, src-tauri/): - Multi-provider AI: OpenAI-compatible, Anthropic, Gemini, Mistral, Ollama - PII detection engine: 11 regex patterns with overlap resolution - SQLCipher AES-256 encrypted database with 10 versioned migrations - 28 Tauri IPC commands for triage, analysis, document, and system ops - Ollama: hardware probe, model recommendations, pull/delete with events - RCA and blameless post-mortem Markdown document generators - PDF export via printpdf - Audit log: SHA-256 hash of every external data send - Integration stubs for Confluence, ServiceNow, Azure DevOps (v0.2) Frontend (React 18 + TypeScript + Vite, src/): - 9 pages: full triage workflow NewIssue→LogUpload→Triage→Resolution→RCA→Postmortem→History+Settings - 7 components: ChatWindow, TriageProgress, PiiDiffViewer, DocEditor, HardwareReport, ModelSelector, UI primitives - 3 Zustand stores: session, settings (persisted), history - Type-safe tauriCommands.ts matching Rust backend types exactly - 8 IT domain system prompts (Linux, Windows, Network, K8s, DB, Virt, HW, Obs) DevOps: - .woodpecker/test.yml: rustfmt, clippy, cargo test, tsc, vitest on every push - .woodpecker/release.yml: linux/amd64 + linux/arm64 builds, Gogs release upload Verified: - cargo check: zero errors - tsc --noEmit: zero errors - vitest run: 13/13 unit tests passing Co-Authored-By: Claude Sonnet 4.6 (1M context) <noreply@anthropic.com> |
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foreground-child
Run a child as if it's the foreground process. Give it stdio. Exit when it exits.
Mostly this module is here to support some use cases around
wrapping child processes for test coverage and such. But it's
also generally useful any time you want one program to execute
another as if it's the "main" process, for example, if a program
takes a --cmd argument to execute in some way.
USAGE
import { foregroundChild } from 'foreground-child'
// hybrid module, this also works:
// const { foregroundChild } = require('foreground-child')
// cats out this file
const child = foregroundChild('cat', [__filename])
// At this point, it's best to just do nothing else.
// return or whatever.
// If the child gets a signal, or just exits, then this
// parent process will exit in the same way.
You can provide custom spawn options by passing an object after the program and arguments:
const child = foregroundChild(`cat ${__filename}`, { shell: true })
A callback can optionally be provided, if you want to perform an action before your foreground-child exits:
const child = foregroundChild('cat', [__filename], spawnOptions, () => {
doSomeActions()
})
The callback can return a Promise in order to perform asynchronous actions. If the callback does not return a promise, then it must complete its actions within a single JavaScript tick.
const child = foregroundChild('cat', [__filename], async () => {
await doSomeAsyncActions()
})
If the callback throws or rejects, then it will be unhandled, and node will exit in error.
If the callback returns a string value, then that will be used as
the signal to exit the parent process. If it returns a number,
then that number will be used as the parent exit status code. If
it returns boolean false, then the parent process will not be
terminated. If it returns undefined, then it will exit with the
same signal/code as the child process.
Caveats
The "normal" standard IO file descriptors (0, 1, and 2 for stdin, stdout, and stderr respectively) are shared with the child process. Additionally, if there is an IPC channel set up in the parent, then messages are proxied to the child on file descriptor 3.
In Node, it's possible to also map arbitrary file descriptors into a child process. In these cases, foreground-child will not map the file descriptors into the child. If file descriptors 0, 1, or 2 are used for the IPC channel, then strange behavior may happen (like printing IPC messages to stderr, for example).
Note that a SIGKILL will always kill the parent process, but will not proxy the signal to the child process, because SIGKILL cannot be caught. In order to address this, a special "watchdog" child process is spawned which will send a SIGKILL to the child process if it does not terminate within half a second after the watchdog receives a SIGHUP due to its parent terminating.
On Windows, issuing a process.kill(process.pid, signal) with a
fatal termination signal may cause the process to exit with a 1
status code rather than reporting the signal properly. This
module tries to do the right thing, but on Windows systems, you
may see that incorrect result. There is as far as I'm aware no
workaround for this.
util: foreground-child/proxy-signals
If you just want to proxy the signals to a child process that the
main process receives, you can use the proxy-signals export
from this package.
import { proxySignals } from 'foreground-child/proxy-signals'
const childProcess = spawn('command', ['some', 'args'])
proxySignals(childProcess)
Now, any fatal signal received by the current process will be proxied to the child process.
It doesn't go in the other direction; ie, signals sent to the
child process will not affect the parent. For that, listen to the
child exit or close events, and handle them appropriately.
util: foreground-child/watchdog
If you are spawning a child process, and want to ensure that it isn't left dangling if the parent process exits, you can use the watchdog utility exported by this module.
import { watchdog } from 'foreground-child/watchdog'
const childProcess = spawn('command', ['some', 'args'])
const watchdogProcess = watchdog(childProcess)
// watchdogProcess is a reference to the process monitoring the
// parent and child. There's usually no reason to do anything
// with it, as it's silent and will terminate
// automatically when it's no longer needed.