packages/shade-key-transparency/tests/hashes.test.ts

import { describe, expect, test } from 'bun:test';
import {
  DOMAIN_BUNDLE,
  computeBundleHash,
  encodeLeafData,
  leafHash,
  nodeHash,
  OP_REGISTER,
} from '../src/hashes.js';
import { sha256Sync } from '../src/sha256.js';

describe('RFC 6962 hash primitives', () => {
  test('leafHash applies 0x00 prefix', () => {
    const data = new Uint8Array([1, 2, 3]);
    const expected = sha256Sync(new Uint8Array([0x00, 1, 2, 3]));
    expect(leafHash(data)).toEqual(expected);
  });

  test('nodeHash applies 0x01 prefix', () => {
    const left = new Uint8Array(32).fill(0xaa);
    const right = new Uint8Array(32).fill(0xbb);
    const concat = new Uint8Array(1 + 32 + 32);
    concat[0] = 0x01;
    concat.set(left, 1);
    concat.set(right, 33);
    const expected = sha256Sync(concat);
    expect(nodeHash(left, right)).toEqual(expected);
  });

  test('leafHash and nodeHash never collide', () => {
    // Same content but different domain → different hash
    const x = new Uint8Array(32).fill(0x42);
    const lh = leafHash(x);
    const concat = new Uint8Array(64).fill(0x42);
    const nh = nodeHash(concat.slice(0, 32), concat.slice(32));
    expect(Buffer.from(lh).toString('hex')).not.toBe(Buffer.from(nh).toString('hex'));
  });
});

describe('encodeLeafData', () => {
  test('encodes timestamp + operation + address + bundleHash', () => {
    const buf = encodeLeafData(
      0x010203040506,
      OP_REGISTER,
      'alice',
      new Uint8Array([0xde, 0xad, 0xbe, 0xef]),
    );
    // 8 + 1 + 2 + 5 + 2 + 4 = 22
    expect(buf.length).toBe(22);
    // last 4 bytes = bundleHash
    expect(buf[buf.length - 4]).toBe(0xde);
    expect(buf[buf.length - 1]).toBe(0xef);
  });

  test('rejects address > 65535 bytes', () => {
    const huge = 'a'.repeat(0x10000);
    expect(() => encodeLeafData(0, OP_REGISTER, huge, new Uint8Array(0))).toThrow();
  });
});

describe('computeBundleHash', () => {
  test('deterministic over equal input', () => {
    const sk = new Uint8Array(32).fill(0x11);
    const dk = new Uint8Array(32).fill(0x22);
    const pk = new Uint8Array(32).fill(0x33);
    const sig = new Uint8Array(64).fill(0x44);
    const a = computeBundleHash({
      identitySigningKey: sk,
      identityDHKey: dk,
      signedPreKey: { keyId: 7, publicKey: pk, signature: sig },
    });
    const b = computeBundleHash({
      identitySigningKey: sk,
      identityDHKey: dk,
      signedPreKey: { keyId: 7, publicKey: pk, signature: sig },
    });
    expect(a).toEqual(b);
  });

  test('changing keyId changes hash', () => {
    const sk = new Uint8Array(32).fill(0x11);
    const dk = new Uint8Array(32).fill(0x22);
    const pk = new Uint8Array(32).fill(0x33);
    const sig = new Uint8Array(64).fill(0x44);
    const a = computeBundleHash({
      identitySigningKey: sk,
      identityDHKey: dk,
      signedPreKey: { keyId: 1, publicKey: pk, signature: sig },
    });
    const b = computeBundleHash({
      identitySigningKey: sk,
      identityDHKey: dk,
      signedPreKey: { keyId: 2, publicKey: pk, signature: sig },
    });
    expect(a).not.toEqual(b);
  });

  test('rejects wrong-length keys', () => {
    expect(() =>
      computeBundleHash({
        identitySigningKey: new Uint8Array(31),
        identityDHKey: new Uint8Array(32),
        signedPreKey: {
          keyId: 0,
          publicKey: new Uint8Array(32),
          signature: new Uint8Array(64),
        },
      }),
    ).toThrow();
  });

  test('uses domain prefix 0x01', () => {
    const sk = new Uint8Array(32);
    const dk = new Uint8Array(32);
    const pk = new Uint8Array(32);
    const sig = new Uint8Array(64);
    const expected = sha256Sync(
      Buffer.concat([Buffer.from([DOMAIN_BUNDLE]), sk, dk, Buffer.alloc(4), pk, sig]),
    );
    const got = computeBundleHash({
      identitySigningKey: sk,
      identityDHKey: dk,
      signedPreKey: { keyId: 0, publicKey: pk, signature: sig },
    });
    expect(Buffer.from(got).toString('hex')).toBe(Buffer.from(expected).toString('hex'));
  });
});
release(v4.0.0): Shade GA — V3.x consolidation + audit prep V3.1 → V3.12 consolidated and tagged for the first GA release. Wire format unchanged from 0.4.x — 4.0 peers interoperate with 0.4.x peers byte-for-byte. The version bump is semantic: audit-cycle complete, opt-in surface fully exposed, threat model refreshed for every new surface. Highlights: - All 24 @shade/* packages bumped to 4.0.0 in lockstep. - CHANGELOG 4.0.0 section is the canonical manifest of what landed. - THREAT-MODEL extended (§10 fingerprint gates, §11 WebRTC P2P, §12 Web-Worker boundary) + residual-risks table refreshed. - OpenAPI now covers all 27 routes: prekey, transfer, KT, inbox, bridge, observer, /metrics, /healthz, /ready. - MIGRATION 0.3.x → 4.0 documented + smoke-tested against shade migrate-storage on a real SQLite DB. - docs/audit/REVIEW-BUNDLE.md + SCOPE.md ready for external reviewer. - scripts/soak.ts harness for the GA-stable 2-week soak window. - All V*.md plans archived under docs/archive/ with Status: Done. - Voice/Video carved out into V5.0; 4.0 audit focuses on the frozen non-realtime stack. Tests: TS 1000/1000 + Kotlin 11/11 cross-platform vectors green. Docker: gt.zyon.no/stian/shade-prekey:4.0.0 builds and reports version 4.0.0 on /health. Co-Authored-By: Claude Opus 4.7 (1M context) <noreply@anthropic.com> 2026-05-03 18:35:35 +02:00			`import { describe, expect, test } from 'bun:test';`
			`import {`
			`DOMAIN_BUNDLE,`
			`computeBundleHash,`
			`encodeLeafData,`
			`leafHash,`
			`nodeHash,`
			`OP_REGISTER,`
			`} from '../src/hashes.js';`
			`import { sha256Sync } from '../src/sha256.js';`

			`describe('RFC 6962 hash primitives', () => {`
			`test('leafHash applies 0x00 prefix', () => {`
			`const data = new Uint8Array([1, 2, 3]);`
			`const expected = sha256Sync(new Uint8Array([0x00, 1, 2, 3]));`
			`expect(leafHash(data)).toEqual(expected);`
			`});`

			`test('nodeHash applies 0x01 prefix', () => {`
			`const left = new Uint8Array(32).fill(0xaa);`
			`const right = new Uint8Array(32).fill(0xbb);`
			`const concat = new Uint8Array(1 + 32 + 32);`
			`concat[0] = 0x01;`
			`concat.set(left, 1);`
			`concat.set(right, 33);`
			`const expected = sha256Sync(concat);`
			`expect(nodeHash(left, right)).toEqual(expected);`
			`});`

			`test('leafHash and nodeHash never collide', () => {`
			`// Same content but different domain → different hash`
			`const x = new Uint8Array(32).fill(0x42);`
			`const lh = leafHash(x);`
			`const concat = new Uint8Array(64).fill(0x42);`
			`const nh = nodeHash(concat.slice(0, 32), concat.slice(32));`
			`expect(Buffer.from(lh).toString('hex')).not.toBe(Buffer.from(nh).toString('hex'));`
			`});`
			`});`

			`describe('encodeLeafData', () => {`
			`test('encodes timestamp + operation + address + bundleHash', () => {`
			`const buf = encodeLeafData(`
			`0x010203040506,`
			`OP_REGISTER,`
			`'alice',`
			`new Uint8Array([0xde, 0xad, 0xbe, 0xef]),`
			`);`
			`// 8 + 1 + 2 + 5 + 2 + 4 = 22`
			`expect(buf.length).toBe(22);`
			`// last 4 bytes = bundleHash`
			`expect(buf[buf.length - 4]).toBe(0xde);`
			`expect(buf[buf.length - 1]).toBe(0xef);`
			`});`

			`test('rejects address > 65535 bytes', () => {`
			`const huge = 'a'.repeat(0x10000);`
			`expect(() => encodeLeafData(0, OP_REGISTER, huge, new Uint8Array(0))).toThrow();`
			`});`
			`});`

			`describe('computeBundleHash', () => {`
			`test('deterministic over equal input', () => {`
			`const sk = new Uint8Array(32).fill(0x11);`
			`const dk = new Uint8Array(32).fill(0x22);`
			`const pk = new Uint8Array(32).fill(0x33);`
			`const sig = new Uint8Array(64).fill(0x44);`
			`const a = computeBundleHash({`
			`identitySigningKey: sk,`
			`identityDHKey: dk,`
			`signedPreKey: { keyId: 7, publicKey: pk, signature: sig },`
			`});`
			`const b = computeBundleHash({`
			`identitySigningKey: sk,`
			`identityDHKey: dk,`
			`signedPreKey: { keyId: 7, publicKey: pk, signature: sig },`
			`});`
			`expect(a).toEqual(b);`
			`});`

			`test('changing keyId changes hash', () => {`
			`const sk = new Uint8Array(32).fill(0x11);`
			`const dk = new Uint8Array(32).fill(0x22);`
			`const pk = new Uint8Array(32).fill(0x33);`
			`const sig = new Uint8Array(64).fill(0x44);`
			`const a = computeBundleHash({`
			`identitySigningKey: sk,`
			`identityDHKey: dk,`
			`signedPreKey: { keyId: 1, publicKey: pk, signature: sig },`
			`});`
			`const b = computeBundleHash({`
			`identitySigningKey: sk,`
			`identityDHKey: dk,`
			`signedPreKey: { keyId: 2, publicKey: pk, signature: sig },`
			`});`
			`expect(a).not.toEqual(b);`
			`});`

			`test('rejects wrong-length keys', () => {`
			`expect(() =>`
			`computeBundleHash({`
			`identitySigningKey: new Uint8Array(31),`
			`identityDHKey: new Uint8Array(32),`
			`signedPreKey: {`
			`keyId: 0,`
			`publicKey: new Uint8Array(32),`
			`signature: new Uint8Array(64),`
			`},`
			`}),`
			`).toThrow();`
			`});`

			`test('uses domain prefix 0x01', () => {`
			`const sk = new Uint8Array(32);`
			`const dk = new Uint8Array(32);`
			`const pk = new Uint8Array(32);`
			`const sig = new Uint8Array(64);`
			`const expected = sha256Sync(`
			`Buffer.concat([Buffer.from([DOMAIN_BUNDLE]), sk, dk, Buffer.alloc(4), pk, sig]),`
			`);`
			`const got = computeBundleHash({`
			`identitySigningKey: sk,`
			`identityDHKey: dk,`
			`signedPreKey: { keyId: 0, publicKey: pk, signature: sig },`
			`});`
			`expect(Buffer.from(got).toString('hex')).toBe(Buffer.from(expected).toString('hex'));`
			`});`
			`});`