aitbc
816e258d4c
Development Artifact Cleanup: ✅ BROTHER_NODE REORGANIZATION: Moved development test node to appropriate location - dev/test-nodes/brother_node/: Moved from root directory for better organization - Contains development configuration, test logs, and test chain data - No impact on production systems - purely development/testing artifact ✅ DEVELOPMENT ARTIFACTS IDENTIFIED: - Chain ID: aitbc-brother-chain (test/development chain) - Ports: 8010 (P2P) and 8011 (RPC) - different from production - Environment: .env file with test configuration - Logs: rpc.log and node.log from development testing session (March 15, 2026) ✅ ROOT DIRECTORY CLEANUP: Removed development clutter from production directory - brother_node/ moved to dev/test-nodes/brother_node/ - Root directory now contains only production-ready components - Development artifacts properly organized in dev/ subdirectory DIRECTORY STRUCTURE IMPROVEMENT: 📁 dev/test-nodes/: Development and testing node configurations 🏗️ Root Directory: Clean production structure with only essential components 🧪 Development Isolation: Test environments separated from production BENEFITS: ✅ Clean Production Directory: No development artifacts in root ✅ Better Organization: Development nodes grouped in dev/ subdirectory ✅ Clear Separation: Production vs development environments clearly distinguished ✅ Maintainability: Easier to identify and manage development components RESULT: Successfully moved brother_node development artifact to dev/test-nodes/ subdirectory, cleaning up the root directory while preserving development testing environment for future use.
156 lines
6.8 KiB
JavaScript
Executable File
156 lines
6.8 KiB
JavaScript
Executable File
/*! noble-curves - MIT License (c) 2022 Paul Miller (paulmillr.com) */
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// Abelian group utilities
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import { validateField, nLength } from './modular.js';
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import { validateObject } from './utils.js';
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const _0n = BigInt(0);
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const _1n = BigInt(1);
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// Elliptic curve multiplication of Point by scalar. Fragile.
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// Scalars should always be less than curve order: this should be checked inside of a curve itself.
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// Creates precomputation tables for fast multiplication:
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// - private scalar is split by fixed size windows of W bits
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// - every window point is collected from window's table & added to accumulator
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// - since windows are different, same point inside tables won't be accessed more than once per calc
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// - each multiplication is 'Math.ceil(CURVE_ORDER / 𝑊) + 1' point additions (fixed for any scalar)
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// - +1 window is neccessary for wNAF
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// - wNAF reduces table size: 2x less memory + 2x faster generation, but 10% slower multiplication
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// TODO: Research returning 2d JS array of windows, instead of a single window. This would allow
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// windows to be in different memory locations
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export function wNAF(c, bits) {
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const constTimeNegate = (condition, item) => {
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const neg = item.negate();
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return condition ? neg : item;
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};
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const opts = (W) => {
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const windows = Math.ceil(bits / W) + 1; // +1, because
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const windowSize = 2 ** (W - 1); // -1 because we skip zero
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return { windows, windowSize };
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};
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return {
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constTimeNegate,
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// non-const time multiplication ladder
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unsafeLadder(elm, n) {
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let p = c.ZERO;
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let d = elm;
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while (n > _0n) {
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if (n & _1n)
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p = p.add(d);
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d = d.double();
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n >>= _1n;
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}
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return p;
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},
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/**
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* Creates a wNAF precomputation window. Used for caching.
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* Default window size is set by `utils.precompute()` and is equal to 8.
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* Number of precomputed points depends on the curve size:
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* 2^(𝑊−1) * (Math.ceil(𝑛 / 𝑊) + 1), where:
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* - 𝑊 is the window size
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* - 𝑛 is the bitlength of the curve order.
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* For a 256-bit curve and window size 8, the number of precomputed points is 128 * 33 = 4224.
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* @returns precomputed point tables flattened to a single array
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*/
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precomputeWindow(elm, W) {
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const { windows, windowSize } = opts(W);
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const points = [];
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let p = elm;
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let base = p;
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for (let window = 0; window < windows; window++) {
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base = p;
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points.push(base);
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// =1, because we skip zero
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for (let i = 1; i < windowSize; i++) {
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base = base.add(p);
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points.push(base);
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}
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p = base.double();
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}
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return points;
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},
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/**
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* Implements ec multiplication using precomputed tables and w-ary non-adjacent form.
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* @param W window size
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* @param precomputes precomputed tables
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* @param n scalar (we don't check here, but should be less than curve order)
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* @returns real and fake (for const-time) points
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*/
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wNAF(W, precomputes, n) {
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// TODO: maybe check that scalar is less than group order? wNAF behavious is undefined otherwise
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// But need to carefully remove other checks before wNAF. ORDER == bits here
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const { windows, windowSize } = opts(W);
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let p = c.ZERO;
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let f = c.BASE;
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const mask = BigInt(2 ** W - 1); // Create mask with W ones: 0b1111 for W=4 etc.
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const maxNumber = 2 ** W;
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const shiftBy = BigInt(W);
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for (let window = 0; window < windows; window++) {
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const offset = window * windowSize;
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// Extract W bits.
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let wbits = Number(n & mask);
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// Shift number by W bits.
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n >>= shiftBy;
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// If the bits are bigger than max size, we'll split those.
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// +224 => 256 - 32
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if (wbits > windowSize) {
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wbits -= maxNumber;
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n += _1n;
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}
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// This code was first written with assumption that 'f' and 'p' will never be infinity point:
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// since each addition is multiplied by 2 ** W, it cannot cancel each other. However,
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// there is negate now: it is possible that negated element from low value
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// would be the same as high element, which will create carry into next window.
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// It's not obvious how this can fail, but still worth investigating later.
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// Check if we're onto Zero point.
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// Add random point inside current window to f.
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const offset1 = offset;
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const offset2 = offset + Math.abs(wbits) - 1; // -1 because we skip zero
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const cond1 = window % 2 !== 0;
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const cond2 = wbits < 0;
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if (wbits === 0) {
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// The most important part for const-time getPublicKey
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f = f.add(constTimeNegate(cond1, precomputes[offset1]));
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}
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else {
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p = p.add(constTimeNegate(cond2, precomputes[offset2]));
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}
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}
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// JIT-compiler should not eliminate f here, since it will later be used in normalizeZ()
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// Even if the variable is still unused, there are some checks which will
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// throw an exception, so compiler needs to prove they won't happen, which is hard.
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// At this point there is a way to F be infinity-point even if p is not,
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// which makes it less const-time: around 1 bigint multiply.
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return { p, f };
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},
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wNAFCached(P, precomputesMap, n, transform) {
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// @ts-ignore
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const W = P._WINDOW_SIZE || 1;
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// Calculate precomputes on a first run, reuse them after
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let comp = precomputesMap.get(P);
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if (!comp) {
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comp = this.precomputeWindow(P, W);
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if (W !== 1) {
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precomputesMap.set(P, transform(comp));
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}
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}
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return this.wNAF(W, comp, n);
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},
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};
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}
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export function validateBasic(curve) {
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validateField(curve.Fp);
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validateObject(curve, {
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n: 'bigint',
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h: 'bigint',
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Gx: 'field',
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Gy: 'field',
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}, {
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nBitLength: 'isSafeInteger',
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nByteLength: 'isSafeInteger',
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});
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// Set defaults
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return Object.freeze({
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...nLength(curve.n, curve.nBitLength),
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...curve,
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...{ p: curve.Fp.ORDER },
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});
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}
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//# sourceMappingURL=curve.js.map
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