packages/shade-transport/tests/kt-split-view-e2e.test.ts

/**
 * Acceptance test for V3.12 §"End-to-end test: split-view detection".
 *
 * Scenario:
 *   - One legitimate STH-signing key (the operator's pinned key).
 *   - Two divergent log views A and B, both signed by the same key
 *     (simulating a malicious server that hands different responses to
 *     different clients).
 *   - Two clients (Bob, Charlie) each fetch alice's bundle, but each is
 *     served from a different view.
 *   - A `LightWitness` cross-pollinates the two clients' STHs.
 *   - The witness must reject the second STH at the same tree_size with
 *     a `KTSplitViewError`.
 *
 * Also asserts the *positive* path: when both clients see the same view,
 * no error is raised.
 */

import { describe, expect, test } from 'bun:test';
import { SubtleCryptoProvider } from '@shade/crypto-web';
import {
  KTLogManager,
  KTSplitViewError,
  LightWitness,
  MemoryKTLogStore,
  computeBundleHash,
  computeLogId,
} from '@shade/key-transparency';

const crypto = new SubtleCryptoProvider();

function fakeBundle(seed: number) {
  return {
    identitySigningKey: new Uint8Array(32).fill(seed),
    identityDHKey: new Uint8Array(32).fill(seed + 1),
    signedPreKey: {
      keyId: 1,
      publicKey: new Uint8Array(32).fill(seed + 2),
      signature: new Uint8Array(64).fill(seed + 3),
    },
  };
}

describe('Split-view E2E', () => {
  test('two divergent views at the same tree_size are caught by witness', async () => {
    const operator = await crypto.generateEd25519KeyPair();

    // View A — alice has the *real* identity (seed 0x10)
    const viewA = await KTLogManager.create({
      crypto,
      store: new MemoryKTLogStore(),
      signingPrivateKey: operator.privateKey,
      signingPublicKey: operator.publicKey,
    });
    await viewA.recordRegister('alice', computeBundleHash(fakeBundle(0x10)));
    const sthA = await viewA.publishSTH();

    // View B — alice has a *malicious* identity (seed 0xff)
    const viewB = await KTLogManager.create({
      crypto,
      store: new MemoryKTLogStore(),
      signingPrivateKey: operator.privateKey,
      signingPublicKey: operator.publicKey,
    });
    await viewB.recordRegister('alice', computeBundleHash(fakeBundle(0xff)));
    const sthB = await viewB.publishSTH();

    // Both STHs claim tree_size = 1 with the same logId, but with
    // different rootHash + indexRoot. This is what a split-view attack
    // looks like on the wire.
    expect(sthA.treeSize).toBe(sthB.treeSize);
    expect(Buffer.from(sthA.logId).toString('hex')).toBe(
      Buffer.from(sthB.logId).toString('hex'),
    );
    expect(Buffer.from(sthA.rootHash).toString('hex')).not.toBe(
      Buffer.from(sthB.rootHash).toString('hex'),
    );

    // Bob has been served STH A; Charlie has been served STH B.
    // They share a witness (gossip-style):
    const witness = new LightWitness({
      crypto,
      logPublicKey: operator.publicKey,
      fetcher: {
        async fetchLatestSTH() {
          throw new Error('not used in this test');
        },
        async fetchConsistencyProof() {
          return { proof: [] };
        },
      },
    });

    await witness.observe(sthA);
    expect(witness.compare(sthA)).toBe('agree');
    expect(witness.compare(sthB)).toBe('split-view');
    await expect(witness.observe(sthB)).rejects.toBeInstanceOf(KTSplitViewError);
  });

  test('positive path: same view → no false alarm', async () => {
    const operator = await crypto.generateEd25519KeyPair();
    const view = await KTLogManager.create({
      crypto,
      store: new MemoryKTLogStore(),
      signingPrivateKey: operator.privateKey,
      signingPublicKey: operator.publicKey,
    });
    await view.recordRegister('alice', computeBundleHash(fakeBundle(0x10)));
    const sth1 = await view.publishSTH();
    await view.recordRegister('bob', computeBundleHash(fakeBundle(0x20)));
    const sth2 = await view.publishSTH();

    const witness = new LightWitness({
      crypto,
      logPublicKey: operator.publicKey,
      fetcher: {
        async fetchLatestSTH() {
          throw new Error('not used');
        },
        async fetchConsistencyProof(from, to) {
          const result = await view.buildHistoricalConsistencyProof(from, to);
          return { proof: result.map((b) => Buffer.from(b).toString('base64')) };
        },
      },
    });
    await witness.observe(sth1);
    await witness.observe(sth2);
    expect(witness.compare(sth2)).toBe('agree');
  });

  test('rewriting history (forked log at tree_size 1) fails consistency from sth1 → sth2', async () => {
    const operator = await crypto.generateEd25519KeyPair();
    const real = await KTLogManager.create({
      crypto,
      store: new MemoryKTLogStore(),
      signingPrivateKey: operator.privateKey,
      signingPublicKey: operator.publicKey,
    });
    await real.recordRegister('alice', computeBundleHash(fakeBundle(0x10)));
    const sth1 = await real.publishSTH();

    // Build a divergent log that pretends 'mallory' was the first leaf,
    // not 'alice'. The forked tree's STH at size 2 must NOT pass a
    // consistency proof against sth1.
    const fork = await KTLogManager.create({
      crypto,
      store: new MemoryKTLogStore(),
      signingPrivateKey: operator.privateKey,
      signingPublicKey: operator.publicKey,
    });
    await fork.recordRegister('mallory', computeBundleHash(fakeBundle(0xee)));
    await fork.recordRegister('bob', computeBundleHash(fakeBundle(0x20)));
    const forkedSth2 = await fork.publishSTH();
    const forkedConsistency = await fork.buildConsistencyProof(sth1.treeSize);

    const witness = new LightWitness({
      crypto,
      logPublicKey: operator.publicKey,
      fetcher: {
        async fetchLatestSTH() {
          throw new Error('not used');
        },
        async fetchConsistencyProof() {
          return { proof: forkedConsistency.proof.map((b) => Buffer.from(b).toString('base64')) };
        },
      },
    });
    await witness.observe(sth1);
    await expect(witness.observe(forkedSth2)).rejects.toThrow();

    // sanity: logId pinning still valid
    expect(Buffer.from(forkedSth2.logId).toString('hex')).toBe(
      Buffer.from(computeLogId(operator.publicKey)).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			`/**`
			`* Acceptance test for V3.12 §"End-to-end test: split-view detection".`
			`*`
			`* Scenario:`
			`* - One legitimate STH-signing key (the operator's pinned key).`
			`* - Two divergent log views A and B, both signed by the same key`
			`* (simulating a malicious server that hands different responses to`
			`* different clients).`
			`* - Two clients (Bob, Charlie) each fetch alice's bundle, but each is`
			`* served from a different view.`
			* - A `LightWitness` cross-pollinates the two clients' STHs.
			`* - The witness must reject the second STH at the same tree_size with`
			* a `KTSplitViewError`.
			`*`
			`* Also asserts the positive path: when both clients see the same view,`
			`* no error is raised.`
			`*/`

			`import { describe, expect, test } from 'bun:test';`
			`import { SubtleCryptoProvider } from '@shade/crypto-web';`
			`import {`
			`KTLogManager,`
			`KTSplitViewError,`
			`LightWitness,`
			`MemoryKTLogStore,`
			`computeBundleHash,`
			`computeLogId,`
			`} from '@shade/key-transparency';`

			`const crypto = new SubtleCryptoProvider();`

			`function fakeBundle(seed: number) {`
			`return {`
			`identitySigningKey: new Uint8Array(32).fill(seed),`
			`identityDHKey: new Uint8Array(32).fill(seed + 1),`
			`signedPreKey: {`
			`keyId: 1,`
			`publicKey: new Uint8Array(32).fill(seed + 2),`
			`signature: new Uint8Array(64).fill(seed + 3),`
			`},`
			`};`
			`}`

			`describe('Split-view E2E', () => {`
			`test('two divergent views at the same tree_size are caught by witness', async () => {`
			`const operator = await crypto.generateEd25519KeyPair();`

			`// View A — alice has the real identity (seed 0x10)`
			`const viewA = await KTLogManager.create({`
			`crypto,`
			`store: new MemoryKTLogStore(),`
			`signingPrivateKey: operator.privateKey,`
			`signingPublicKey: operator.publicKey,`
			`});`
			`await viewA.recordRegister('alice', computeBundleHash(fakeBundle(0x10)));`
			`const sthA = await viewA.publishSTH();`

			`// View B — alice has a malicious identity (seed 0xff)`
			`const viewB = await KTLogManager.create({`
			`crypto,`
			`store: new MemoryKTLogStore(),`
			`signingPrivateKey: operator.privateKey,`
			`signingPublicKey: operator.publicKey,`
			`});`
			`await viewB.recordRegister('alice', computeBundleHash(fakeBundle(0xff)));`
			`const sthB = await viewB.publishSTH();`

			`// Both STHs claim tree_size = 1 with the same logId, but with`
			`// different rootHash + indexRoot. This is what a split-view attack`
			`// looks like on the wire.`
			`expect(sthA.treeSize).toBe(sthB.treeSize);`
			`expect(Buffer.from(sthA.logId).toString('hex')).toBe(`
			`Buffer.from(sthB.logId).toString('hex'),`
			`);`
			`expect(Buffer.from(sthA.rootHash).toString('hex')).not.toBe(`
			`Buffer.from(sthB.rootHash).toString('hex'),`
			`);`

			`// Bob has been served STH A; Charlie has been served STH B.`
			`// They share a witness (gossip-style):`
			`const witness = new LightWitness({`
			`crypto,`
			`logPublicKey: operator.publicKey,`
			`fetcher: {`
			`async fetchLatestSTH() {`
			`throw new Error('not used in this test');`
			`},`
			`async fetchConsistencyProof() {`
			`return { proof: [] };`
			`},`
			`},`
			`});`

			`await witness.observe(sthA);`
			`expect(witness.compare(sthA)).toBe('agree');`
			`expect(witness.compare(sthB)).toBe('split-view');`
			`await expect(witness.observe(sthB)).rejects.toBeInstanceOf(KTSplitViewError);`
			`});`

			`test('positive path: same view → no false alarm', async () => {`
			`const operator = await crypto.generateEd25519KeyPair();`
			`const view = await KTLogManager.create({`
			`crypto,`
			`store: new MemoryKTLogStore(),`
			`signingPrivateKey: operator.privateKey,`
			`signingPublicKey: operator.publicKey,`
			`});`
			`await view.recordRegister('alice', computeBundleHash(fakeBundle(0x10)));`
			`const sth1 = await view.publishSTH();`
			`await view.recordRegister('bob', computeBundleHash(fakeBundle(0x20)));`
			`const sth2 = await view.publishSTH();`

			`const witness = new LightWitness({`
			`crypto,`
			`logPublicKey: operator.publicKey,`
			`fetcher: {`
			`async fetchLatestSTH() {`
			`throw new Error('not used');`
			`},`
			`async fetchConsistencyProof(from, to) {`
			`const result = await view.buildHistoricalConsistencyProof(from, to);`
			`return { proof: result.map((b) => Buffer.from(b).toString('base64')) };`
			`},`
			`},`
			`});`
			`await witness.observe(sth1);`
			`await witness.observe(sth2);`
			`expect(witness.compare(sth2)).toBe('agree');`
			`});`

			`test('rewriting history (forked log at tree_size 1) fails consistency from sth1 → sth2', async () => {`
			`const operator = await crypto.generateEd25519KeyPair();`
			`const real = await KTLogManager.create({`
			`crypto,`
			`store: new MemoryKTLogStore(),`
			`signingPrivateKey: operator.privateKey,`
			`signingPublicKey: operator.publicKey,`
			`});`
			`await real.recordRegister('alice', computeBundleHash(fakeBundle(0x10)));`
			`const sth1 = await real.publishSTH();`

			`// Build a divergent log that pretends 'mallory' was the first leaf,`
			`// not 'alice'. The forked tree's STH at size 2 must NOT pass a`
			`// consistency proof against sth1.`
			`const fork = await KTLogManager.create({`
			`crypto,`
			`store: new MemoryKTLogStore(),`
			`signingPrivateKey: operator.privateKey,`
			`signingPublicKey: operator.publicKey,`
			`});`
			`await fork.recordRegister('mallory', computeBundleHash(fakeBundle(0xee)));`
			`await fork.recordRegister('bob', computeBundleHash(fakeBundle(0x20)));`
			`const forkedSth2 = await fork.publishSTH();`
			`const forkedConsistency = await fork.buildConsistencyProof(sth1.treeSize);`

			`const witness = new LightWitness({`
			`crypto,`
			`logPublicKey: operator.publicKey,`
			`fetcher: {`
			`async fetchLatestSTH() {`
			`throw new Error('not used');`
			`},`
			`async fetchConsistencyProof() {`
			`return { proof: forkedConsistency.proof.map((b) => Buffer.from(b).toString('base64')) };`
			`},`
			`},`
			`});`
			`await witness.observe(sth1);`
			`await expect(witness.observe(forkedSth2)).rejects.toThrow();`

			`// sanity: logId pinning still valid`
			`expect(Buffer.from(forkedSth2.logId).toString('hex')).toBe(`
			`Buffer.from(computeLogId(operator.publicKey)).toString('hex'),`
			`);`
			`});`
			`});`