packages/shade-streams/tests/coordinator.test.ts

import { describe, test, expect } from 'bun:test';
import { SubtleCryptoProvider } from '@shade/crypto-web';
import { ValidationError } from '@shade/core';
import {
  MultiLaneSender,
  MultiLaneReceiver,
  StreamProtocolError,
  generateStreamId,
  generateStreamSecret,
  planRangePartition,
  planRoundRobinPartition,
  chunkRange,
  sha256Once,
} from '../src/index.js';

const crypto = new SubtleCryptoProvider();

function hex(b: Uint8Array): string {
  return Array.from(b, (x) => x.toString(16).padStart(2, '0')).join('');
}

/**
 * Roundtrip a fixed input through `laneCount` lanes using range partitioning.
 * Returns the per-side overall sha256 + the reconstructed plaintext.
 */
async function roundtripRange(input: Uint8Array, laneCount: number, chunkSize: number) {
  const streamId = generateStreamId(crypto);
  const streamSecret = generateStreamSecret(crypto);
  const lanes = planRangePartition(input.length, laneCount);

  const sender = await MultiLaneSender.create({ crypto, streamId, streamSecret, lanes });
  const receiver = await MultiLaneReceiver.create({ crypto, streamId, streamSecret, lanes });

  // Append the entire input to the sender's overall hasher in original order
  // (range mode: lane i's slice is contiguous in original order).
  sender.appendOverall(input);

  // Encrypt all chunks for all lanes (interleaved as a real consumer would).
  const wireChunks: Array<{ laneId: number; bytes: Uint8Array }> = [];
  for (const lane of lanes) {
    if (lane.partition.kind !== 'range') throw new Error('expected range');
    const slices = chunkRange(lane.partition.startByte, lane.partition.endByte, chunkSize);
    for (let i = 0; i < slices.length; i++) {
      const s = slices[i]!;
      const isLast = i === slices.length - 1;
      const plaintext = input.subarray(s.start, s.end);
      const { bytes } = await sender.encryptForLane(lane.laneId, plaintext, isLast);
      wireChunks.push({ laneId: lane.laneId, bytes });
    }
  }

  // Receiver decrypts. Range mode: gather lane outputs in laneId order.
  const laneBuffers = new Map<number, Uint8Array[]>();
  for (const { bytes } of wireChunks) {
    const dec = await receiver.decryptChunk(bytes);
    if (!laneBuffers.has(dec.laneId)) laneBuffers.set(dec.laneId, []);
    laneBuffers.get(dec.laneId)!.push(dec.plaintext);
  }
  // Concatenate lane outputs in laneId order to rebuild original byte order.
  const reconstructed: Uint8Array[] = [];
  for (let i = 0; i < laneCount; i++) {
    for (const piece of laneBuffers.get(i) ?? []) reconstructed.push(piece);
  }
  // Feed receiver's overall hasher in original byte order.
  for (const piece of reconstructed) receiver.appendOverall(piece);

  return {
    sender,
    receiver,
    senderOverall: sender.getOverallSha256(),
    receiverOverall: receiver.getOverallSha256(),
    reconstructed: concat(reconstructed),
  };
}

/** Roundtrip via round-robin partitioning. Chunk i goes to lane (i mod L). */
async function roundtripRoundRobin(
  input: Uint8Array,
  laneCount: number,
  chunkSize: number,
) {
  const streamId = generateStreamId(crypto);
  const streamSecret = generateStreamSecret(crypto);
  const lanes = planRoundRobinPartition(laneCount);

  const sender = await MultiLaneSender.create({ crypto, streamId, streamSecret, lanes });
  const receiver = await MultiLaneReceiver.create({ crypto, streamId, streamSecret, lanes });

  // Append in original order.
  sender.appendOverall(input);

  // Slice into chunks; round-robin assignment.
  const slices = chunkRange(0, input.length, chunkSize);
  // Determine `isLast` for each lane (last chunk this lane sees).
  const lastChunkByLane = new Map<number, number>();
  for (let i = 0; i < slices.length; i++) {
    lastChunkByLane.set(i % laneCount, i);
  }
  const wireChunks: Array<{ chunkIndex: number; bytes: Uint8Array }> = [];
  for (let i = 0; i < slices.length; i++) {
    const s = slices[i]!;
    const laneId = i % laneCount;
    const isLast = lastChunkByLane.get(laneId) === i;
    const plaintext = input.subarray(s.start, s.end);
    const { bytes } = await sender.encryptForLane(laneId, plaintext, isLast);
    wireChunks.push({ chunkIndex: i, bytes });
  }

  // Receiver: collect chunks; reorder by chunkIndex (the original-order index).
  const decoded = new Map<number, Uint8Array>();
  for (const { chunkIndex, bytes } of wireChunks) {
    const dec = await receiver.decryptChunk(bytes);
    decoded.set(chunkIndex, dec.plaintext);
  }
  const reconstructed: Uint8Array[] = [];
  for (let i = 0; i < slices.length; i++) {
    reconstructed.push(decoded.get(i)!);
  }
  for (const piece of reconstructed) receiver.appendOverall(piece);

  return {
    sender,
    receiver,
    senderOverall: sender.getOverallSha256(),
    receiverOverall: receiver.getOverallSha256(),
    reconstructed: concat(reconstructed),
  };
}

function concat(parts: Uint8Array[]): Uint8Array {
  const total = parts.reduce((s, p) => s + p.length, 0);
  const out = new Uint8Array(total);
  let off = 0;
  for (const p of parts) {
    out.set(p, off);
    off += p.length;
  }
  return out;
}

describe('MultiLaneSender / MultiLaneReceiver — basic shape', () => {
  test('rejects empty lanes array', async () => {
    const streamId = generateStreamId(crypto);
    const streamSecret = generateStreamSecret(crypto);
    await expect(
      MultiLaneSender.create({ crypto, streamId, streamSecret, lanes: [] }),
    ).rejects.toThrow(ValidationError);
  });

  test('rejects duplicate laneIds', async () => {
    const streamId = generateStreamId(crypto);
    const streamSecret = generateStreamSecret(crypto);
    await expect(
      MultiLaneSender.create({
        crypto,
        streamId,
        streamSecret,
        lanes: [
          { laneId: 0, partition: { kind: 'round-robin', lane: 0, count: 2 } },
          { laneId: 0, partition: { kind: 'round-robin', lane: 1, count: 2 } },
        ],
      }),
    ).rejects.toThrow(ValidationError);
  });

  test('encryptForLane on unknown laneId throws StreamProtocolError', async () => {
    const sender = await MultiLaneSender.create({
      crypto,
      streamId: generateStreamId(crypto),
      streamSecret: generateStreamSecret(crypto),
      lanes: planRoundRobinPartition(2),
    });
    await expect(sender.encryptForLane(99, new Uint8Array(0), false)).rejects.toThrow(
      StreamProtocolError,
    );
  });
});

describe('Range-partition roundtrip', () => {
  test('1 KB / 4 lanes / 256 B chunk', async () => {
    const input = crypto.randomBytes(1024);
    const r = await roundtripRange(input, 4, 256);
    expect(r.reconstructed).toEqual(input);
    expect(hex(r.senderOverall)).toBe(hex(r.receiverOverall));
    expect(hex(r.senderOverall)).toBe(hex(sha256Once(input)));
  });

  test('exactly chunkSize-aligned input', async () => {
    const input = crypto.randomBytes(8 * 256);
    const r = await roundtripRange(input, 4, 256);
    expect(r.reconstructed).toEqual(input);
    expect(hex(r.senderOverall)).toBe(hex(r.receiverOverall));
  });

  test('input smaller than chunkSize × laneCount', async () => {
    const input = crypto.randomBytes(50);
    const r = await roundtripRange(input, 4, 64);
    expect(r.reconstructed).toEqual(input);
    expect(hex(r.senderOverall)).toBe(hex(r.receiverOverall));
  });
});

describe('Round-robin partition roundtrip', () => {
  test('4 lanes, 1 KB / 128 B chunks', async () => {
    const input = crypto.randomBytes(1024);
    const r = await roundtripRoundRobin(input, 4, 128);
    expect(r.reconstructed).toEqual(input);
    expect(hex(r.senderOverall)).toBe(hex(r.receiverOverall));
  });
});

describe('Lane-parity ship-gate (1 / 4 / 16 lanes → same overallSha256)', () => {
  const sizes = [
    { label: '1 KiB', bytes: 1024 },
    { label: '256 KiB', bytes: 256 * 1024 },
    { label: '2 MiB', bytes: 2 * 1024 * 1024 },
  ];

  for (const { label, bytes } of sizes) {
    test(`${label} input — same sha256 across {1, 4, 16} lanes (range)`, async () => {
      const input = crypto.randomBytes(bytes);
      const expected = hex(sha256Once(input));
      for (const laneCount of [1, 4, 16]) {
        const r = await roundtripRange(input, laneCount, 64 * 1024);
        expect(r.reconstructed).toEqual(input);
        expect(hex(r.senderOverall)).toBe(expected);
        expect(hex(r.receiverOverall)).toBe(expected);
      }
    });
  }

  test('1 MiB input — same sha256 across {1, 4, 16} lanes (round-robin)', async () => {
    const input = crypto.randomBytes(1024 * 1024);
    const expected = hex(sha256Once(input));
    for (const laneCount of [1, 4, 16]) {
      const r = await roundtripRoundRobin(input, laneCount, 32 * 1024);
      expect(r.reconstructed).toEqual(input);
      expect(hex(r.senderOverall)).toBe(expected);
      expect(hex(r.receiverOverall)).toBe(expected);
    }
  });

  test('range and round-robin produce the same overall sha256 for the same input', async () => {
    const input = crypto.randomBytes(128 * 1024);
    const a = await roundtripRange(input, 4, 16 * 1024);
    const b = await roundtripRoundRobin(input, 4, 16 * 1024);
    expect(hex(a.senderOverall)).toBe(hex(b.senderOverall));
    expect(hex(a.receiverOverall)).toBe(hex(b.receiverOverall));
  });
});

describe('Per-lane fingerprints', () => {
  test('match between sender and receiver after roundtrip', async () => {
    const input = crypto.randomBytes(64 * 1024);
    const r = await roundtripRange(input, 4, 8 * 1024);
    const senderFps = r.sender.getLaneFingerprints();
    const receiverFps = r.receiver.getLaneFingerprints();
    expect(senderFps.length).toBe(4);
    for (let i = 0; i < 4; i++) {
      expect(hex(senderFps[i]!.sha256)).toBe(hex(receiverFps[i]!.sha256));
      expect(senderFps[i]!.byteCount).toBe(receiverFps[i]!.byteCount);
      expect(senderFps[i]!.chunkCount).toBe(receiverFps[i]!.chunkCount);
    }
  });

  test('byteCount across all lanes equals total input', async () => {
    const input = crypto.randomBytes(99 * 1024); // intentionally non-divisible
    const r = await roundtripRange(input, 4, 8 * 1024);
    const total = r.sender
      .getLaneFingerprints()
      .reduce((s, l) => s + l.byteCount, 0);
    expect(total).toBe(input.length);
  });

  test('allLanesFinished reflects per-lane completion', async () => {
    const input = crypto.randomBytes(1024);
    const r = await roundtripRange(input, 2, 256);
    expect(r.sender.allLanesFinished).toBe(true);
    expect(r.receiver.allLanesFinished).toBe(true);
  });
});
-												feat(files): @shade/files 0.3.0 — E2EE filesystem RPC primitive

M-Files-1..6 land the full files-RPC layer + everything 0.3.0 needs to
ship. Apps keep their own UI; this layer ships the typed RPC, the
streams bridge for content I/O, and production hooks (rate limit,
retention, fingerprint gate, metrics).

@shade/files (NEW)
- Standard ops: list/stat/mkdir/delete/move/read/write/getThumbnail with
  Zod-validated wire schemas + clean user-handler types.
- Custom ops: typed via TypeScript declaration merging on CustomOpsMap
  + per-op Zod schemas; client.custom('app.foo', {...}) is fully typed.
- Content I/O: inline (≤ 256 KiB plaintext) base64-in-RPC; streams
  (> 256 KiB) ride @shade/transfer via userMetadata.shadeFilesWriteId
  / shadeFilesReadStreamId correlation. Server-side TransformStream
  bridges accept inbound transfers immediately (engine rejects chunks
  that arrive before accept) and park the readable for the matching
  RPC.
- Directory ops: walk(path, opts) async-iterable depth-first walker;
  uploadDirectory()/downloadDirectory() with bounded concurrency pool
  (default 4, cap 16), aggregated progress, abort.
- Production hooks (callback-based, vendor-neutral): rate-limit (op +
  byte), idempotency cache (LRU + TTL + in-flight de-dupe), path
  policy (traversal + percent-decode hardening), fingerprint gate
  (required/optional/reject), pluggable Ed25519 sig verification with
  ±5 min replay window, onMetric sink (standard names).
- React hooks (subpath @shade/files/react): ShadeFilesProvider,
  useShadeFiles, useFileList, useFileTransfer/Upload/Download.
- Shade.files.serve(handler) + Shade.files.client(peer) high-level
  entrypoint in @shade/sdk; lazy + memoized; one handler per Shade.

Wire format bump
- @shade/proto wire VERSION 0x01 → 0x02. Length prefixes changed from
  u16 to u32. The previous u16 silently truncated payloads above
  64 KiB — a hard correctness ceiling that blocked inline file ops
  up to 256 KiB. Wire-incompatible with 0.2.x peers; new sessions
  only. Cross-platform Kotlin port (android/shade-android) updated to
  match; test-vectors/wire-format.json regenerated.

Concurrency safety
- ShadeSessionManager.encrypt/.decrypt now run under per-peer mutex.
  Concurrent decryptions of the same peer raced ratchet state
  (manifested as sporadic "Failed to decrypt — wrong key or tampered
  data" under load — surfaced once concurrent uploadDirectory pumped
  many writes in flight). Encrypt was already serialized via
  Shade.send's encryptChains; decrypt is now serialized at the
  manager layer too.

@shade/streams extension
- StreamMetadata.userMetadata?: Record<string, string> for
  application-level key/value pairs that round-trip verbatim through
  stream-init plaintext. Used by @shade/files for write/read
  correlation; available to any consumer.

@shade/sdk extension
- Shade.files getter (lazy + memoized).
- BackgroundHooks.onPruneFiles + periodic timer (default 5 min) +
  BackgroundTasks.setHook(name, fn) for runtime hook registration.

Bundles in-flight 0.2.0 work
- packages/shade-streams/, packages/shade-transfer/, related
  shade-sdk streams-bridge + shade-widgets transfer hooks were
  uncommitted prior to this session. Including them keeps the
  workspace consistent at 0.3.0 since @shade/files depends on them.

Tests
- 74 new tests in @shade/files (572 → 646 workspace pass; 0 fail;
  3× stable). Coverage spans unit (inline-threshold + concurrency),
  integration (read-write inline + streams up to 1 MiB, walk +
  upload/download directory, custom-op, metrics, SDK namespace
  end-to-end), and security (tampered-envelope sig verification,
  replay window, fingerprint gate, rate-limit + quota).

Release artifacts
- All packages bumped to 0.3.0 via scripts/bump-version.ts.
- scripts/publish-all.ts PACKAGES updated with shade-files in
  topological order (after shade-transfer, before shade-sdk).
- bun run publish:dry clean (14 packed, 0 failed).
- examples/08-files-browser/ — three-process CLI demo (prekey + Bob
  server + Alice CLI) covering list/stat/mkdir/delete/upload/download.
- docs/files.md — full API + design doc.
- CHANGELOG.md 0.3.0 entry.

Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com>

											
										
										
											2026-05-02 14:00:01 +02:00
+								import { describe, test, expect } from 'bun:test';
 								import { SubtleCryptoProvider } from '@shade/crypto-web';
 								import { ValidationError } from '@shade/core';
 								import {
 								  MultiLaneSender,
 								  MultiLaneReceiver,
 								  StreamProtocolError,
 								  generateStreamId,
 								  generateStreamSecret,
 								  planRangePartition,
 								  planRoundRobinPartition,
 								  chunkRange,
 								  sha256Once,
 								} from '../src/index.js';
 								const crypto = new SubtleCryptoProvider();
 								function hex(b: Uint8Array): string {
 								  return Array.from(b, (x) => x.toString(16).padStart(2, '0')).join('');
 								}
 								/**
 								 * Roundtrip a fixed input through `laneCount` lanes using range partitioning.
 								 * Returns the per-side overall sha256 + the reconstructed plaintext.
 								 */
 								async function roundtripRange(input: Uint8Array, laneCount: number, chunkSize: number) {
 								  const streamId = generateStreamId(crypto);
 								  const streamSecret = generateStreamSecret(crypto);
 								  const lanes = planRangePartition(input.length, laneCount);
 								  const sender = await MultiLaneSender.create({ crypto, streamId, streamSecret, lanes });
 								  const receiver = await MultiLaneReceiver.create({ crypto, streamId, streamSecret, lanes });
 								  // Append the entire input to the sender's overall hasher in original order
 								  // (range mode: lane i's slice is contiguous in original order).
 								  sender.appendOverall(input);
 								  // Encrypt all chunks for all lanes (interleaved as a real consumer would).
 								  const wireChunks: Array<{ laneId: number; bytes: Uint8Array }> = [];
 								  for (const lane of lanes) {
 								    if (lane.partition.kind !== 'range') throw new Error('expected range');
 								    const slices = chunkRange(lane.partition.startByte, lane.partition.endByte, chunkSize);
 								    for (let i = 0; i < slices.length; i++) {
 								      const s = slices[i]!;
 								      const isLast = i === slices.length - 1;
 								      const plaintext = input.subarray(s.start, s.end);
 								      const { bytes } = await sender.encryptForLane(lane.laneId, plaintext, isLast);
 								      wireChunks.push({ laneId: lane.laneId, bytes });
 								    }
 								  }
 								  // Receiver decrypts. Range mode: gather lane outputs in laneId order.
 								  const laneBuffers = new Map<number, Uint8Array[]>();
 								  for (const { bytes } of wireChunks) {
 								    const dec = await receiver.decryptChunk(bytes);
 								    if (!laneBuffers.has(dec.laneId)) laneBuffers.set(dec.laneId, []);
 								    laneBuffers.get(dec.laneId)!.push(dec.plaintext);
 								  }
 								  // Concatenate lane outputs in laneId order to rebuild original byte order.
 								  const reconstructed: Uint8Array[] = [];
 								  for (let i = 0; i < laneCount; i++) {
 								    for (const piece of laneBuffers.get(i) ?? []) reconstructed.push(piece);
 								  }
 								  // Feed receiver's overall hasher in original byte order.
 								  for (const piece of reconstructed) receiver.appendOverall(piece);
 								  return {
 								    sender,
 								    receiver,
 								    senderOverall: sender.getOverallSha256(),
 								    receiverOverall: receiver.getOverallSha256(),
 								    reconstructed: concat(reconstructed),
 								  };
 								}
 								/** Roundtrip via round-robin partitioning. Chunk i goes to lane (i mod L). */
 								async function roundtripRoundRobin(
 								  input: Uint8Array,
 								  laneCount: number,
 								  chunkSize: number,
 								) {
 								  const streamId = generateStreamId(crypto);
 								  const streamSecret = generateStreamSecret(crypto);
 								  const lanes = planRoundRobinPartition(laneCount);
 								  const sender = await MultiLaneSender.create({ crypto, streamId, streamSecret, lanes });
 								  const receiver = await MultiLaneReceiver.create({ crypto, streamId, streamSecret, lanes });
 								  // Append in original order.
 								  sender.appendOverall(input);
 								  // Slice into chunks; round-robin assignment.
 								  const slices = chunkRange(0, input.length, chunkSize);
 								  // Determine `isLast` for each lane (last chunk this lane sees).
 								  const lastChunkByLane = new Map<number, number>();
 								  for (let i = 0; i < slices.length; i++) {
 								    lastChunkByLane.set(i % laneCount, i);
 								  }
 								  const wireChunks: Array<{ chunkIndex: number; bytes: Uint8Array }> = [];
 								  for (let i = 0; i < slices.length; i++) {
 								    const s = slices[i]!;
 								    const laneId = i % laneCount;
 								    const isLast = lastChunkByLane.get(laneId) === i;
 								    const plaintext = input.subarray(s.start, s.end);
 								    const { bytes } = await sender.encryptForLane(laneId, plaintext, isLast);
 								    wireChunks.push({ chunkIndex: i, bytes });
 								  }
 								  // Receiver: collect chunks; reorder by chunkIndex (the original-order index).
 								  const decoded = new Map<number, Uint8Array>();
 								  for (const { chunkIndex, bytes } of wireChunks) {
 								    const dec = await receiver.decryptChunk(bytes);
 								    decoded.set(chunkIndex, dec.plaintext);
 								  }
 								  const reconstructed: Uint8Array[] = [];
 								  for (let i = 0; i < slices.length; i++) {
 								    reconstructed.push(decoded.get(i)!);
 								  }
 								  for (const piece of reconstructed) receiver.appendOverall(piece);
 								  return {
 								    sender,
 								    receiver,
 								    senderOverall: sender.getOverallSha256(),
 								    receiverOverall: receiver.getOverallSha256(),
 								    reconstructed: concat(reconstructed),
 								  };
 								}
 								function concat(parts: Uint8Array[]): Uint8Array {
 								  const total = parts.reduce((s, p) => s + p.length, 0);
 								  const out = new Uint8Array(total);
 								  let off = 0;
 								  for (const p of parts) {
 								    out.set(p, off);
 								    off += p.length;
 								  }
 								  return out;
 								}
 								describe('MultiLaneSender / MultiLaneReceiver — basic shape', () => {
 								  test('rejects empty lanes array', async () => {
 								    const streamId = generateStreamId(crypto);
 								    const streamSecret = generateStreamSecret(crypto);
 								    await expect(
 								      MultiLaneSender.create({ crypto, streamId, streamSecret, lanes: [] }),
 								    ).rejects.toThrow(ValidationError);
 								  });
 								  test('rejects duplicate laneIds', async () => {
 								    const streamId = generateStreamId(crypto);
 								    const streamSecret = generateStreamSecret(crypto);
 								    await expect(
 								      MultiLaneSender.create({
 								        crypto,
 								        streamId,
 								        streamSecret,
 								        lanes: [
 								          { laneId: 0, partition: { kind: 'round-robin', lane: 0, count: 2 } },
 								          { laneId: 0, partition: { kind: 'round-robin', lane: 1, count: 2 } },
 								        ],
 								      }),
 								    ).rejects.toThrow(ValidationError);
 								  });
 								  test('encryptForLane on unknown laneId throws StreamProtocolError', async () => {
 								    const sender = await MultiLaneSender.create({
 								      crypto,
 								      streamId: generateStreamId(crypto),
 								      streamSecret: generateStreamSecret(crypto),
 								      lanes: planRoundRobinPartition(2),
 								    });
 								    await expect(sender.encryptForLane(99, new Uint8Array(0), false)).rejects.toThrow(
 								      StreamProtocolError,
 								    );
 								  });
 								});
 								describe('Range-partition roundtrip', () => {
 								  test('1 KB / 4 lanes / 256 B chunk', async () => {
 								    const input = crypto.randomBytes(1024);
 								    const r = await roundtripRange(input, 4, 256);
 								    expect(r.reconstructed).toEqual(input);
 								    expect(hex(r.senderOverall)).toBe(hex(r.receiverOverall));
 								    expect(hex(r.senderOverall)).toBe(hex(sha256Once(input)));
 								  });
 								  test('exactly chunkSize-aligned input', async () => {
 								    const input = crypto.randomBytes(8 * 256);
 								    const r = await roundtripRange(input, 4, 256);
 								    expect(r.reconstructed).toEqual(input);
 								    expect(hex(r.senderOverall)).toBe(hex(r.receiverOverall));
 								  });
 								  test('input smaller than chunkSize × laneCount', async () => {
 								    const input = crypto.randomBytes(50);
 								    const r = await roundtripRange(input, 4, 64);
 								    expect(r.reconstructed).toEqual(input);
 								    expect(hex(r.senderOverall)).toBe(hex(r.receiverOverall));
 								  });
 								});
 								describe('Round-robin partition roundtrip', () => {
 								  test('4 lanes, 1 KB / 128 B chunks', async () => {
 								    const input = crypto.randomBytes(1024);
 								    const r = await roundtripRoundRobin(input, 4, 128);
 								    expect(r.reconstructed).toEqual(input);
 								    expect(hex(r.senderOverall)).toBe(hex(r.receiverOverall));
 								  });
 								});
 								describe('Lane-parity ship-gate (1 / 4 / 16 lanes → same overallSha256)', () => {
 								  const sizes = [
 								    { label: '1 KiB', bytes: 1024 },
 								    { label: '256 KiB', bytes: 256 * 1024 },
 								    { label: '2 MiB', bytes: 2 * 1024 * 1024 },
 								  ];
 								  for (const { label, bytes } of sizes) {
 								    test(`${label} input — same sha256 across {1, 4, 16} lanes (range)`, async () => {
 								      const input = crypto.randomBytes(bytes);
 								      const expected = hex(sha256Once(input));
 								      for (const laneCount of [1, 4, 16]) {
 								        const r = await roundtripRange(input, laneCount, 64 * 1024);
 								        expect(r.reconstructed).toEqual(input);
 								        expect(hex(r.senderOverall)).toBe(expected);
 								        expect(hex(r.receiverOverall)).toBe(expected);
 								      }
 								    });
 								  }
 								  test('1 MiB input — same sha256 across {1, 4, 16} lanes (round-robin)', async () => {
 								    const input = crypto.randomBytes(1024 * 1024);
 								    const expected = hex(sha256Once(input));
 								    for (const laneCount of [1, 4, 16]) {
 								      const r = await roundtripRoundRobin(input, laneCount, 32 * 1024);
 								      expect(r.reconstructed).toEqual(input);
 								      expect(hex(r.senderOverall)).toBe(expected);
 								      expect(hex(r.receiverOverall)).toBe(expected);
 								    }
 								  });
 								  test('range and round-robin produce the same overall sha256 for the same input', async () => {
 								    const input = crypto.randomBytes(128 * 1024);
 								    const a = await roundtripRange(input, 4, 16 * 1024);
 								    const b = await roundtripRoundRobin(input, 4, 16 * 1024);
 								    expect(hex(a.senderOverall)).toBe(hex(b.senderOverall));
 								    expect(hex(a.receiverOverall)).toBe(hex(b.receiverOverall));
 								  });
 								});
 								describe('Per-lane fingerprints', () => {
 								  test('match between sender and receiver after roundtrip', async () => {
 								    const input = crypto.randomBytes(64 * 1024);
 								    const r = await roundtripRange(input, 4, 8 * 1024);
 								    const senderFps = r.sender.getLaneFingerprints();
 								    const receiverFps = r.receiver.getLaneFingerprints();
 								    expect(senderFps.length).toBe(4);
 								    for (let i = 0; i < 4; i++) {
 								      expect(hex(senderFps[i]!.sha256)).toBe(hex(receiverFps[i]!.sha256));
 								      expect(senderFps[i]!.byteCount).toBe(receiverFps[i]!.byteCount);
 								      expect(senderFps[i]!.chunkCount).toBe(receiverFps[i]!.chunkCount);
 								    }
 								  });
 								  test('byteCount across all lanes equals total input', async () => {
 								    const input = crypto.randomBytes(99 * 1024); // intentionally non-divisible
 								    const r = await roundtripRange(input, 4, 8 * 1024);
 								    const total = r.sender
 								      .getLaneFingerprints()
 								      .reduce((s, l) => s + l.byteCount, 0);
 								    expect(total).toBe(input.length);
 								  });
 								  test('allLanesFinished reflects per-lane completion', async () => {
 								    const input = crypto.randomBytes(1024);
 								    const r = await roundtripRange(input, 2, 256);
 								    expect(r.sender.allLanesFinished).toBe(true);
 								    expect(r.receiver.allLanesFinished).toBe(true);
 								  });
 								});