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>
73 lines
2.2 KiB
JavaScript
73 lines
2.2 KiB
JavaScript
import isPlainObject from 'is-plain-obj';
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import {normalizePipeArguments} from './pipe-arguments.js';
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import {handlePipeArgumentsError} from './throw.js';
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import {waitForBothSubprocesses} from './sequence.js';
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import {pipeSubprocessStream} from './streaming.js';
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import {unpipeOnAbort} from './abort.js';
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// Pipe a subprocess' `stdout`/`stderr`/`stdio` into another subprocess' `stdin`
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export const pipeToSubprocess = (sourceInfo, ...pipeArguments) => {
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if (isPlainObject(pipeArguments[0])) {
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return pipeToSubprocess.bind(undefined, {
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...sourceInfo,
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boundOptions: {...sourceInfo.boundOptions, ...pipeArguments[0]},
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});
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}
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const {destination, ...normalizedInfo} = normalizePipeArguments(sourceInfo, ...pipeArguments);
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const promise = handlePipePromise({...normalizedInfo, destination});
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promise.pipe = pipeToSubprocess.bind(undefined, {
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...sourceInfo,
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source: destination,
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sourcePromise: promise,
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boundOptions: {},
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});
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return promise;
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};
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// Asynchronous logic when piping subprocesses
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const handlePipePromise = async ({
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sourcePromise,
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sourceStream,
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sourceOptions,
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sourceError,
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destination,
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destinationStream,
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destinationError,
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unpipeSignal,
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fileDescriptors,
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startTime,
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}) => {
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const subprocessPromises = getSubprocessPromises(sourcePromise, destination);
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handlePipeArgumentsError({
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sourceStream,
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sourceError,
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destinationStream,
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destinationError,
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fileDescriptors,
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sourceOptions,
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startTime,
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});
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const maxListenersController = new AbortController();
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try {
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const mergedStream = pipeSubprocessStream(sourceStream, destinationStream, maxListenersController);
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return await Promise.race([
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waitForBothSubprocesses(subprocessPromises),
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...unpipeOnAbort(unpipeSignal, {
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sourceStream,
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mergedStream,
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sourceOptions,
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fileDescriptors,
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startTime,
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}),
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]);
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} finally {
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maxListenersController.abort();
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}
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};
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// `.pipe()` awaits the subprocess promises.
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// When invalid arguments are passed to `.pipe()`, we throw an error, which prevents awaiting them.
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// We need to ensure this does not create unhandled rejections.
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const getSubprocessPromises = (sourcePromise, destination) => Promise.allSettled([sourcePromise, destination]);
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