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14 Commits
v0.4.8 ... v0.7.7

Author SHA1 Message Date
Your Name
00a8f16262 v0.7.6 - Delete more old debugging prints 2025-10-10 13:38:18 -04:00
Your Name
00d16f8615 v0.7.5 - Complete debug logging cleanup - remove all remaining DEBUG messages from websockets.c, config.c, and dm_admin.c 2025-10-10 10:52:14 -04:00
Your Name
c90676d2b2 v0.7.4 - Remove excessive debug logging from entire codebase - preserve user-facing error logging 2025-10-10 10:21:30 -04:00
Your Name
b89c011ad5 v0.7.2 - -m 2025-10-10 06:53:30 -04:00
Your Name
c3de31aa88 v0.7.1 - Implemented static binary build system for cross-distribution compatibility 2025-10-09 14:36:32 -04:00
Your Name
b6df0be865 v0.6.0 - Fixed binary upload in release script - now shows upload errors and handles failures properly 2025-10-09 12:59:23 -04:00
Your Name
a89f84f76e v0.5.0 - New release 2025-10-09 12:51:53 -04:00
Your Name
5a916cc221 Reupload 2025-10-09 10:43:42 -04:00
Your Name
dcf421ff93 v0.4.13 - DM system appears fully functional 2025-10-08 07:11:22 -04:00
Your Name
d655258311 v0.4.12 - Refactor NIP-17 admin commands: eliminate ~400 lines of duplicated code with unified helper functions, fix SQL query bugs, and remove unused parameters 2025-10-06 18:49:25 -04:00
Your Name
f6d13d4318 v0.4.11 - Fixed nasty DM bug 2025-10-06 10:06:24 -04:00
Your Name
d5350d7c30 v0.4.10 - api 2025-10-05 14:35:09 -04:00
Your Name
c63fd04c92 v0.4.9 - Working on dm admin 2025-10-04 19:04:12 -04:00
Your Name
64b418a551 v0.4.8 - Implement web server functionality for embedded admin interface - serve HTML/CSS/JS from /api/ endpoint with proper MIME types, CORS headers, and performance optimizations 2025-10-04 12:45:35 -04:00
837 changed files with 128644 additions and 6040 deletions
Expand all files Collapse all files

4
.gitignore vendored
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@@ -9,4 +9,6 @@ dev-config/
db/
copy_executable_local.sh
nostr_login_lite/
style_guide/
style_guide/
nostr-tools

4
.roo/commands/push.md
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@@ -2,4 +2,6 @@
description: "Brief description of what this command does"
---
Run build_and_push.sh, and supply a good git commit message.
Run build_and_push.sh, and supply a good git commit message. For example:
./build_and_push.sh "Fixed the bug with nip05 implementation"

1
.rooignore Normal file
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@@ -0,0 +1 @@
src/embedded_web_content.c

19
Makefile
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@@ -9,7 +9,7 @@ LIBS = -lsqlite3 -lwebsockets -lz -ldl -lpthread -lm -L/usr/local/lib -lsecp256k
BUILD_DIR = build
# Source files
MAIN_SRC = src/main.c src/config.c src/request_validator.c src/nip009.c src/nip011.c src/nip013.c src/nip040.c src/nip042.c src/websockets.c src/subscriptions.c
MAIN_SRC = src/main.c src/config.c src/dm_admin.c src/request_validator.c src/nip009.c src/nip011.c src/nip013.c src/nip040.c src/nip042.c src/websockets.c src/subscriptions.c src/api.c src/embedded_web_content.c
NOSTR_CORE_LIB = nostr_core_lib/libnostr_core_x64.a
# Architecture detection
@@ -197,4 +197,21 @@ help:
@echo " make init-db # Set up database"
@echo " make force-version # Force regenerate main.h from git"
# Build fully static MUSL binaries using Docker
static-musl-x86_64:
@echo "Building fully static MUSL binary for x86_64..."
docker buildx build --platform linux/amd64 -f examples/deployment/static-builder.Dockerfile -t c-relay-static-builder-x86_64 --load .
docker run --rm -v $(PWD)/build:/output c-relay-static-builder-x86_64 sh -c "cp /c_relay_static_musl_x86_64 /output/"
@echo "Static binary created: build/c_relay_static_musl_x86_64"
static-musl-arm64:
@echo "Building fully static MUSL binary for ARM64..."
docker buildx build --platform linux/arm64 -f examples/deployment/static-builder.Dockerfile -t c-relay-static-builder-arm64 --load .
docker run --rm -v $(PWD)/build:/output c-relay-static-builder-arm64 sh -c "cp /c_relay_static_musl_x86_64 /output/c_relay_static_musl_arm64"
@echo "Static binary created: build/c_relay_static_musl_arm64"
static-musl: static-musl-x86_64 static-musl-arm64
@echo "Built static MUSL binaries for both architectures"
.PHONY: static-musl-x86_64 static-musl-arm64 static-musl
.PHONY: all x86 arm64 test init-db clean clean-all install-deps install-cross-tools install-arm64-deps check-toolchain help force-version

124
README.md
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@@ -1,8 +1,8 @@
# C Nostr Relay - Event-Based Configuration System
# C-Nostr Relay
A high-performance Nostr relay implemented in C with SQLite backend, featuring a revolutionary **zero-configuration** approach using event-based configuration management.
A high-performance Nostr relay implemented in C with SQLite backend, featuring nostr event-based management.
## 📜 Supported NIPs
## Supported NIPs
<!--
NOTE FOR ASSISTANTS: When updating the NIPs checklist below, ONLY change [ ] to [x] to mark as complete.
@@ -22,7 +22,83 @@ Do NOT modify the formatting, add emojis, or change the text. Keep the simple fo
- [x] NIP-50: Keywords filter
- [x] NIP-70: Protected Events
## 🔧 Administrator API
## Quick Start
Get your C-Relay up and running in minutes with a static binary (no dependencies required):
### 1. Download Static Binary
Download the latest static release from the [releases page](https://git.laantungir.net/laantungir/c-relay/releases):
```bash
# Static binary - works on all Linux distributions (no dependencies)
wget https://git.laantungir.net/laantungir/c-relay/releases/download/v0.6.0/c-relay-v0.6.0-linux-x86_64-static
chmod +x c-relay-v0.6.0-linux-x86_64-static
mv c-relay-v0.6.0-linux-x86_64-static c-relay
```
### 2. Start the Relay
Simply run the binary - no configuration files needed:
```bash
./c-relay
```
On first startup, you'll see:
- **Admin Private Key**: Save this securely! You'll need it for administration
- **Relay Public Key**: Your relay's identity on the Nostr network
- **Port Information**: Default is 8888, or the next available port
### 3. Access the Web Interface
Open your browser and navigate to:
```
http://localhost:8888/api/
```
The web interface provides:
- Real-time configuration management
- Database statistics dashboard
- Auth rules management
- Secure admin authentication with your Nostr identity
### 4. Test Your Relay
Test basic connectivity:
```bash
# Test WebSocket connection
curl -H "Accept: application/nostr+json" http://localhost:8888
# Test with a Nostr client
# Add ws://localhost:8888 to your client's relay list
```
### 5. Configure Your Relay (Optional)
Use the web interface or send admin commands to customize:
- Relay name and description
- Authentication rules (whitelist/blacklist)
- Connection limits
- Proof-of-work requirements
**That's it!** Your relay is now running with zero configuration required. The event-based configuration system means you can adjust all settings through the web interface or admin API without editing config files.
## Web Admin Interface
C-Relay includes a **built-in web-based administration interface** accessible at `http://localhost:8888/api/`. The interface provides:
- **Real-time Configuration Management**: View and edit all relay settings through a web UI
- **Database Statistics Dashboard**: Monitor event counts, storage usage, and performance metrics
- **Auth Rules Management**: Configure whitelist/blacklist rules for pubkeys
- **NIP-42 Authentication**: Secure access using your Nostr identity
- **Event-Based Updates**: All changes are applied as cryptographically signed Nostr events
The web interface serves embedded static files with no external dependencies and includes proper CORS headers for browser compatibility.
## Administrator API
C-Relay uses an innovative **event-based administration system** where all configuration and management commands are sent as signed Nostr events using the admin private key generated during first startup. All admin commands use **NIP-44 encrypted command arrays** for security and compatibility.
@@ -87,6 +163,7 @@ All commands are sent as NIP-44 encrypted JSON arrays in the event content. The
| **System Commands** |
| `system_clear_auth` | `["system_command", "clear_all_auth_rules"]` | Clear all auth rules |
| `system_status` | `["system_command", "system_status"]` | Get system status |
| `stats_query` | `["stats_query"]` | Get comprehensive database statistics |
### Available Configuration Keys
@@ -229,3 +306,42 @@ All admin commands return **signed EVENT responses** via WebSocket following sta
"sig": "response_event_signature"
}]
```
**Database Statistics Query Response:**
```json
["EVENT", "temp_sub_id", {
"id": "response_event_id",
"pubkey": "relay_public_key",
"created_at": 1234567890,
"kind": 23457,
"content": "nip44 encrypted:{\"query_type\": \"stats_query\", \"timestamp\": 1234567890, \"database_size_bytes\": 1048576, \"total_events\": 15432, \"database_created_at\": 1234567800, \"latest_event_at\": 1234567890, \"event_kinds\": [{\"kind\": 1, \"count\": 12000, \"percentage\": 77.8}, {\"kind\": 0, \"count\": 2500, \"percentage\": 16.2}], \"time_stats\": {\"total\": 15432, \"last_24h\": 234, \"last_7d\": 1456, \"last_30d\": 5432}, \"top_pubkeys\": [{\"pubkey\": \"abc123...\", \"event_count\": 1234, \"percentage\": 8.0}, {\"pubkey\": \"def456...\", \"event_count\": 987, \"percentage\": 6.4}]}",
"tags": [
["p", "admin_public_key"]
],
"sig": "response_event_signature"
}]
```
## Direct Messaging Admin System
In addition to the above admin API, c-relay allows the administrator to direct message the relay to get information or control some settings. As long as the administrator is signed in with any nostr client that allows sending nip-17 direct messages (DMs), they can control the relay.
The is possible because the relay is a full nostr citizen with it's own private and public key, and it knows the administrator's public key.
**Available DM commands**
The intent is not to be strict in the formatting of the DM. So for example if the relay receives any DM from the administrator with the words "stats" or "statistics" in it, it will respond to the administrator with a reply DM with the current relay statistics.
- `stats`|`statistics`: Relay statistics
- `config`|`configuration`: Relay configuration

490
api/index.css Normal file
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@@ -0,0 +1,490 @@
:root {
/* Core Variables (7) */
--primary-color: #000000;
--secondary-color: #ffffff;
--accent-color: #ff0000;
--muted-color: #dddddd;
--border-color: var(--muted-color);
--font-family: "Courier New", Courier, monospace;
--border-radius: 15px;
--border-width: 1px;
/* Floating Tab Variables (8) */
--tab-bg-logged-out: #ffffff;
--tab-bg-logged-in: #ffffff;
--tab-bg-opacity-logged-out: 0.9;
--tab-bg-opacity-logged-in: 0.2;
--tab-color-logged-out: #000000;
--tab-color-logged-in: #ffffff;
--tab-border-logged-out: #000000;
--tab-border-logged-in: #ff0000;
--tab-border-opacity-logged-out: 1.0;
--tab-border-opacity-logged-in: 0.1;
}
* {
margin: 0;
padding: 0;
box-sizing: border-box;
}
body {
font-family: var(--font-family);
background-color: var(--secondary-color);
color: var(--primary-color);
/* line-height: 1.4; */
padding: 20px;
max-width: 1200px;
margin: 0 auto;
}
h1 {
border-bottom: var(--border-width) solid var(--border-color);
padding-bottom: 10px;
margin-bottom: 30px;
font-weight: normal;
font-size: 24px;
font-family: var(--font-family);
color: var(--primary-color);
}
h2 {
font-weight: normal;
padding-left: 10px;
font-size: 16px;
font-family: var(--font-family);
color: var(--primary-color);
}
.section {
background: var(--secondary-color);
border: var(--border-width) solid var(--border-color);
border-radius: var(--border-radius);
padding: 20px;
margin-bottom: 20px;
}
.input-group {
margin-bottom: 15px;
}
label {
display: block;
margin-bottom: 5px;
font-weight: bold;
font-size: 14px;
font-family: var(--font-family);
color: var(--primary-color);
}
input,
textarea,
select {
width: 100%;
padding: 8px;
background: var(--secondary-color);
color: var(--primary-color);
border: var(--border-width) solid var(--border-color);
border-radius: var(--border-radius);
font-family: var(--font-family);
font-size: 14px;
box-sizing: border-box;
transition: all 0.2s ease;
}
input:focus,
textarea:focus,
select:focus {
border-color: var(--accent-color);
outline: none;
}
button {
width: 100%;
padding: 8px;
background: var(--secondary-color);
color: var(--primary-color);
border: var(--border-width) solid var(--border-color);
border-radius: var(--border-radius);
font-family: var(--font-family);
font-size: 14px;
cursor: pointer;
margin: 5px 0;
font-weight: bold;
transition: all 0.2s ease;
}
button:hover {
border-color: var(--accent-color);
}
button:active {
background: var(--accent-color);
color: var(--secondary-color);
}
button:disabled {
background-color: #ccc;
color: var(--muted-color);
cursor: not-allowed;
border-color: #ccc;
}
.status {
padding: 10px;
margin: 10px 0;
border: var(--border-width) solid var(--border-color);
border-radius: var(--border-radius);
font-weight: bold;
font-family: var(--font-family);
transition: all 0.2s ease;
}
.status.connected {
background-color: var(--primary-color);
color: var(--secondary-color);
}
.status.disconnected {
background-color: var(--secondary-color);
color: var(--primary-color);
}
.status.authenticated {
background-color: var(--primary-color);
color: var(--secondary-color);
}
.status.error {
background-color: var(--secondary-color);
color: var(--primary-color);
border-color: var(--accent-color);
}
.config-table {
border: 1px solid var(--border-color);
border-radius: var(--border-radius);
width: 100%;
border-collapse: separate;
border-spacing: 0;
margin: 10px 0;
overflow: hidden;
}
.config-table th,
.config-table td {
border: 0.1px solid var(--muted-color);
padding: 4px;
text-align: left;
font-family: var(--font-family);
font-size: 10px;
}
.config-table-container {
overflow-x: auto;
max-width: 100%;
}
.config-table th {
font-weight: bold;
height: 40px; /* Double the default height */
line-height: 40px; /* Center text vertically */
}
.config-table tr:hover {
background-color: var(--muted-color);
}
/* Inline config value inputs - remove borders and padding to fit seamlessly in table cells */
.config-value-input {
border: none;
padding: 2px 4px;
background: transparent;
width: 100%;
min-height: auto;
font-family: inherit;
font-size: inherit;
color: inherit;
border-radius: 0;
}
.config-value-input:focus {
border: 1px solid var(--accent-color);
background: var(--secondary-color);
outline: none;
}
/* Config actions cell - clickable for saving */
.config-actions-cell {
cursor: pointer;
transition: all 0.2s ease;
text-align: center;
font-weight: bold;
vertical-align: middle;
}
.config-actions-cell:hover {
border: 1px solid var(--accent-color);
background-color: var(--muted-color);
}
.json-display {
background-color: var(--secondary-color);
border: var(--border-width) solid var(--border-color);
border-radius: var(--border-radius);
padding: 10px;
font-family: var(--font-family);
font-size: 12px;
white-space: pre-wrap;
max-height: 300px;
overflow-y: auto;
margin: 10px 0;
}
.log-panel {
height: 200px;
overflow-y: auto;
border: var(--border-width) solid var(--border-color);
border-radius: var(--border-radius);
padding: 10px;
font-size: 12px;
background-color: var(--secondary-color);
font-family: var(--font-family);
}
.log-entry {
margin-bottom: 5px;
border-bottom: 1px solid var(--muted-color);
padding-bottom: 5px;
}
.log-timestamp {
font-weight: bold;
font-family: var(--font-family);
}
.inline-buttons {
display: flex;
gap: 10px;
}
.inline-buttons button {
flex: 1;
}
.user-info {
padding: 10px;
border: var(--border-width) solid var(--border-color);
border-radius: var(--border-radius);
margin: 10px 0;
background-color: var(--secondary-color);
}
.user-info-container {
display: flex;
align-items: flex-start;
gap: 20px;
}
.user-details {
flex: 1;
}
.login-logout-btn {
width: auto;
min-width: 120px;
padding: 12px 16px;
background: var(--secondary-color);
color: var(--primary-color);
border: var(--border-width) solid var(--border-color);
border-radius: var(--border-radius);
font-family: var(--font-family);
font-size: 14px;
font-weight: bold;
cursor: pointer;
transition: all 0.2s ease;
margin: 0;
flex-shrink: 0;
}
.login-logout-btn:hover {
border-color: var(--accent-color);
}
.login-logout-btn:active {
background: var(--accent-color);
color: var(--secondary-color);
}
.login-logout-btn.logout-state {
background: var(--accent-color);
color: var(--secondary-color);
border-color: var(--accent-color);
}
.login-logout-btn.logout-state:hover {
background: var(--primary-color);
border-color: var(--border-color);
}
.user-pubkey {
font-family: var(--font-family);
font-size: 12px;
word-break: break-all;
margin: 5px 0;
}
.hidden {
display: none;
}
.section-header {
display: flex;
justify-content: space-between;
align-items: center;
margin-bottom: 15px;
border-bottom: var(--border-width) solid var(--border-color);
padding-bottom: 10px;
}
.auth-rules-controls {
margin-bottom: 15px;
}
.section-header .status {
margin: 0;
padding: 5px 10px;
min-width: auto;
font-size: 12px;
}
/* Auth Rule Input Sections Styling */
.auth-rule-section {
border: var(--border-width) solid var(--border-color);
border-radius: var(--border-radius);
padding: 15px;
margin: 15px 0;
background-color: var(--secondary-color);
}
.auth-rule-section h3 {
margin: 0 0 10px 0;
font-size: 14px;
font-weight: bold;
border-left: 4px solid var(--border-color);
padding-left: 8px;
font-family: var(--font-family);
color: var(--primary-color);
}
.auth-rule-section p {
margin: 0 0 15px 0;
font-size: 13px;
color: var(--muted-color);
font-family: var(--font-family);
}
.rule-status {
margin-top: 10px;
padding: 8px;
border: var(--border-width) solid var(--muted-color);
border-radius: var(--border-radius);
font-size: 12px;
min-height: 20px;
background-color: var(--secondary-color);
font-family: var(--font-family);
transition: all 0.2s ease;
}
.rule-status.success {
border-color: #4CAF50;
background-color: #E8F5E8;
color: #2E7D32;
}
.rule-status.error {
border-color: var(--accent-color);
background-color: #FFEBEE;
color: #C62828;
}
.rule-status.warning {
border-color: #FF9800;
background-color: #FFF3E0;
color: #E65100;
}
.warning-box {
border: var(--border-width) solid #FF9800;
border-radius: var(--border-radius);
background-color: #FFF3E0;
padding: 10px;
margin: 10px 0;
font-size: 13px;
color: #E65100;
font-family: var(--font-family);
}
.warning-box strong {
color: #D84315;
}
#login-section {
text-align: center;
padding: 20px;
}
/* Floating tab styles */
.floating-tab {
font-family: var(--font-family);
border-radius: var(--border-radius);
border: var(--border-width) solid;
transition: all 0.2s ease;
}
.floating-tab--logged-out {
background: rgba(255, 255, 255, var(--tab-bg-opacity-logged-out));
color: var(--tab-color-logged-out);
border-color: rgba(0, 0, 0, var(--tab-border-opacity-logged-out));
}
.floating-tab--logged-in {
background: rgba(0, 0, 0, var(--tab-bg-opacity-logged-in));
color: var(--tab-color-logged-in);
border-color: rgba(255, 0, 0, var(--tab-border-opacity-logged-in));
}
.transition {
transition: all 0.2s ease;
}
/* Main Sections Wrapper */
.main-sections-wrapper {
display: flex;
flex-wrap: wrap;
gap: var(--border-width);
margin-bottom: 20px;
}
.flex-section {
flex: 1;
min-width: 300px;
}
@media (max-width: 700px) {
body {
padding: 10px;
}
.inline-buttons {
flex-direction: column;
}
h1 {
font-size: 20px;
}
h2 {
font-size: 14px;
}
}

3731
api/index.html
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api/index.js Normal file
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api/nostr-lite.js
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243
build_and_push.sh
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@@ -17,6 +17,33 @@ print_error() { echo -e "${RED}[ERROR]${NC} $1"; }
COMMIT_MESSAGE=""
RELEASE_MODE=false
show_usage() {
echo "C-Relay Build and Push Script"
echo ""
echo "Usage:"
echo " $0 \"commit message\" - Default: compile, increment patch, commit & push"
echo " $0 -r \"commit message\" - Release: compile x86+arm64, increment minor, create release"
echo ""
echo "Examples:"
echo " $0 \"Fixed event validation bug\""
echo " $0 --release \"Major release with new features\""
echo ""
echo "Default Mode (patch increment):"
echo " - Compile C-Relay"
echo " - Increment patch version (v1.2.3 → v1.2.4)"
echo " - Git add, commit with message, and push"
echo ""
echo "Release Mode (-r flag):"
echo " - Compile C-Relay for x86_64 and arm64 (dynamic and static versions)"
echo " - Increment minor version, zero patch (v1.2.3 → v1.3.0)"
echo " - Git add, commit, push, and create Gitea release"
echo ""
echo "Requirements for Release Mode:"
echo " - For ARM64 builds: make install-arm64-deps (optional - will build x86_64 only if missing)"
echo " - For static builds: sudo apt-get install musl-dev libcap-dev libuv1-dev libev-dev"
echo " - Gitea token in ~/.gitea_token for release uploads"
}
# Parse command line arguments
while [[ $# -gt 0 ]]; do
case $1 in
@@ -38,32 +65,6 @@ while [[ $# -gt 0 ]]; do
esac
done
show_usage() {
echo "C-Relay Build and Push Script"
echo ""
echo "Usage:"
echo " $0 \"commit message\" - Default: compile, increment patch, commit & push"
echo " $0 -r \"commit message\" - Release: compile x86+arm64, increment minor, create release"
echo ""
echo "Examples:"
echo " $0 \"Fixed event validation bug\""
echo " $0 --release \"Major release with new features\""
echo ""
echo "Default Mode (patch increment):"
echo " - Compile C-Relay"
echo " - Increment patch version (v1.2.3 → v1.2.4)"
echo " - Git add, commit with message, and push"
echo ""
echo "Release Mode (-r flag):"
echo " - Compile C-Relay for x86_64 and arm64"
echo " - Increment minor version, zero patch (v1.2.3 → v1.3.0)"
echo " - Git add, commit, push, and create Gitea release"
echo ""
echo "Requirements for Release Mode:"
echo " - For ARM64 builds: make install-arm64-deps (optional - will build x86_64 only if missing)"
echo " - Gitea token in ~/.gitea_token for release uploads"
}
# Validate inputs
if [[ -z "$COMMIT_MESSAGE" ]]; then
print_error "Commit message is required"
@@ -190,6 +191,35 @@ build_release_binaries() {
print_status "Only x86_64 binary will be included in release"
fi
# Build static x86_64 version
print_status "Building static x86_64 version..."
make clean > /dev/null 2>&1
if make static-musl-x86_64 > /dev/null 2>&1; then
if [[ -f "build/c_relay_static_musl_x86_64" ]]; then
cp build/c_relay_static_musl_x86_64 c-relay-static-x86_64
print_success "Static x86_64 binary created: c-relay-static-x86_64"
else
print_warning "Static x86_64 binary not found after compilation"
fi
else
print_warning "Static x86_64 build failed - MUSL development packages may not be installed"
print_status "Run 'sudo apt-get install musl-dev libcap-dev libuv1-dev libev-dev' to enable static builds"
fi
# Try to build static ARM64 version
print_status "Attempting static ARM64 build..."
make clean > /dev/null 2>&1
if make static-musl-arm64 > /dev/null 2>&1; then
if [[ -f "build/c_relay_static_musl_arm64" ]]; then
cp build/c_relay_static_musl_arm64 c-relay-static-arm64
print_success "Static ARM64 binary created: c-relay-static-arm64"
else
print_warning "Static ARM64 binary not found after compilation"
fi
else
print_warning "Static ARM64 build failed - ARM64 cross-compilation or MUSL ARM64 packages not set up"
fi
# Restore normal build
make clean > /dev/null 2>&1
make > /dev/null 2>&1
@@ -319,12 +349,18 @@ create_gitea_release() {
-H "Content-Type: application/json" \
-d "{\"tag_name\": \"$NEW_VERSION\", \"name\": \"$NEW_VERSION\", \"body\": \"$COMMIT_MESSAGE\"}")
local upload_result=false
if echo "$response" | grep -q '"id"'; then
print_success "Created release $NEW_VERSION"
upload_release_binaries "$api_url" "$token"
if upload_release_binaries "$api_url" "$token"; then
upload_result=true
fi
elif echo "$response" | grep -q "already exists"; then
print_warning "Release $NEW_VERSION already exists"
upload_release_binaries "$api_url" "$token"
if upload_release_binaries "$api_url" "$token"; then
upload_result=true
fi
else
print_error "Failed to create release $NEW_VERSION"
print_error "Response: $response"
@@ -334,18 +370,29 @@ create_gitea_release() {
local check_response=$(curl -s -H "Authorization: token $token" "$api_url/releases/tags/$NEW_VERSION")
if echo "$check_response" | grep -q '"id"'; then
print_warning "Release exists but creation response was unexpected"
upload_release_binaries "$api_url" "$token"
if upload_release_binaries "$api_url" "$token"; then
upload_result=true
fi
else
print_error "Release does not exist and creation failed"
return 1
fi
fi
# Return based on upload success
if [[ "$upload_result" == true ]]; then
return 0
else
print_error "Binary upload failed"
return 1
fi
}
# Function to upload release binaries
upload_release_binaries() {
local api_url="$1"
local token="$2"
local upload_success=true
# Get release ID with more robust parsing
print_status "Getting release ID for $NEW_VERSION..."
@@ -367,37 +414,131 @@ upload_release_binaries() {
# Upload x86_64 binary
if [[ -f "c-relay-x86_64" ]]; then
print_status "Uploading x86_64 binary..."
if curl -s -X POST "$api_url/releases/$release_id/assets" \
local upload_response=$(curl -s -w "\n%{http_code}" -X POST "$api_url/releases/$release_id/assets" \
-H "Authorization: token $token" \
-F "attachment=@c-relay-x86_64;filename=c-relay-${NEW_VERSION}-linux-x86_64" > /dev/null; then
print_success "Uploaded x86_64 binary"
-F "attachment=@c-relay-x86_64;filename=c-relay-${NEW_VERSION}-linux-x86_64")
local http_code=$(echo "$upload_response" | tail -n1)
local response_body=$(echo "$upload_response" | head -n -1)
if [[ "$http_code" == "201" ]]; then
print_success "Uploaded x86_64 binary successfully"
else
print_warning "Failed to upload x86_64 binary"
print_error "Failed to upload x86_64 binary (HTTP $http_code)"
print_error "Response: $response_body"
upload_success=false
fi
else
print_warning "x86_64 binary not found: c-relay-x86_64"
fi
# Upload ARM64 binary
if [[ -f "c-relay-arm64" ]]; then
print_status "Uploading ARM64 binary..."
if curl -s -X POST "$api_url/releases/$release_id/assets" \
local upload_response=$(curl -s -w "\n%{http_code}" -X POST "$api_url/releases/$release_id/assets" \
-H "Authorization: token $token" \
-F "attachment=@c-relay-arm64;filename=c-relay-${NEW_VERSION}-linux-arm64" > /dev/null; then
print_success "Uploaded ARM64 binary"
-F "attachment=@c-relay-arm64;filename=c-relay-${NEW_VERSION}-linux-arm64")
local http_code=$(echo "$upload_response" | tail -n1)
local response_body=$(echo "$upload_response" | head -n -1)
if [[ "$http_code" == "201" ]]; then
print_success "Uploaded ARM64 binary successfully"
else
print_warning "Failed to upload ARM64 binary"
print_error "Failed to upload ARM64 binary (HTTP $http_code)"
print_error "Response: $response_body"
upload_success=false
fi
else
print_warning "ARM64 binary not found: c-relay-arm64"
fi
# Upload static x86_64 binary
if [[ -f "c-relay-static-x86_64" ]]; then
print_status "Uploading static x86_64 binary..."
local upload_response=$(curl -s -w "\n%{http_code}" -X POST "$api_url/releases/$release_id/assets" \
-H "Authorization: token $token" \
-F "attachment=@c-relay-static-x86_64;filename=c-relay-${NEW_VERSION}-linux-x86_64-static")
local http_code=$(echo "$upload_response" | tail -n1)
local response_body=$(echo "$upload_response" | head -n -1)
if [[ "$http_code" == "201" ]]; then
print_success "Uploaded static x86_64 binary successfully"
else
print_error "Failed to upload static x86_64 binary (HTTP $http_code)"
print_error "Response: $response_body"
upload_success=false
fi
else
print_warning "Static x86_64 binary not found: c-relay-static-x86_64"
fi
# Upload static ARM64 binary
if [[ -f "c-relay-static-arm64" ]]; then
print_status "Uploading static ARM64 binary..."
local upload_response=$(curl -s -w "\n%{http_code}" -X POST "$api_url/releases/$release_id/assets" \
-H "Authorization: token $token" \
-F "attachment=@c-relay-static-arm64;filename=c-relay-${NEW_VERSION}-linux-arm64-static")
local http_code=$(echo "$upload_response" | tail -n1)
local response_body=$(echo "$upload_response" | head -n -1)
if [[ "$http_code" == "201" ]]; then
print_success "Uploaded static ARM64 binary successfully"
else
print_error "Failed to upload static ARM64 binary (HTTP $http_code)"
print_error "Response: $response_body"
upload_success=false
fi
else
print_warning "Static ARM64 binary not found: c-relay-static-arm64"
fi
# Return success/failure status
if [[ "$upload_success" == true ]]; then
return 0
else
return 1
fi
}
# Function to clean up release binaries
cleanup_release_binaries() {
if [[ -f "c-relay-x86_64" ]]; then
rm -f c-relay-x86_64
print_status "Cleaned up x86_64 binary"
fi
if [[ -f "c-relay-arm64" ]]; then
rm -f c-relay-arm64
print_status "Cleaned up ARM64 binary"
local force_cleanup="$1" # Optional parameter to force cleanup even on failure
if [[ "$force_cleanup" == "force" ]] || [[ "$upload_success" == true ]]; then
if [[ -f "c-relay-x86_64" ]]; then
rm -f c-relay-x86_64
print_status "Cleaned up x86_64 binary"
fi
if [[ -f "c-relay-arm64" ]]; then
rm -f c-relay-arm64
print_status "Cleaned up ARM64 binary"
fi
if [[ -f "c-relay-static-x86_64" ]]; then
rm -f c-relay-static-x86_64
print_status "Cleaned up static x86_64 binary"
fi
if [[ -f "c-relay-static-arm64" ]]; then
rm -f c-relay-static-arm64
print_status "Cleaned up static ARM64 binary"
fi
else
print_warning "Keeping binary files due to upload failures"
print_status "Files available for manual upload:"
if [[ -f "c-relay-x86_64" ]]; then
print_status " - c-relay-x86_64"
fi
if [[ -f "c-relay-arm64" ]]; then
print_status " - c-relay-arm64"
fi
if [[ -f "c-relay-static-x86_64" ]]; then
print_status " - c-relay-static-x86_64"
fi
if [[ -f "c-relay-static-arm64" ]]; then
print_status " - c-relay-static-arm64"
fi
fi
}
@@ -433,14 +574,18 @@ main() {
git_commit_and_push_no_tag
# Create Gitea release with binaries
create_gitea_release
if create_gitea_release; then
print_success "Release $NEW_VERSION completed successfully!"
print_status "Binaries uploaded to Gitea release"
upload_success=true
else
print_error "Release creation or binary upload failed"
upload_success=false
fi
# Cleanup
# Cleanup (only if upload was successful)
cleanup_release_binaries
print_success "Release $NEW_VERSION completed successfully!"
print_status "Binaries uploaded to Gitea release"
else
print_status "=== DEFAULT MODE ==="

144
build_static.sh Executable file
View File

@@ -0,0 +1,144 @@
#!/bin/bash
# Build fully static MUSL binaries for C-Relay
# Produces portable binaries with zero runtime dependencies
set -e
SCRIPT_DIR="$(cd "$(dirname "${BASH_SOURCE[0]}")" && pwd)"
BUILD_DIR="$SCRIPT_DIR/build"
echo "Building fully static MUSL binaries for C-Relay..."
echo "Project directory: $SCRIPT_DIR"
echo "Build directory: $BUILD_DIR"
# Create build directory
mkdir -p "$BUILD_DIR"
# Check if Docker is available first
if command -v docker &> /dev/null && sudo docker buildx version &> /dev/null 2>&1; then
echo "Docker available but Alpine repositories are having issues - using native build"
USE_DOCKER=false
else
echo "Docker not available - attempting native MUSL build"
USE_DOCKER=false
fi
# Check if musl-gcc is available for native build
if [ "$USE_DOCKER" = false ]; then
if ! command -v musl-gcc &> /dev/null; then
echo "Installing musl development tools..."
sudo apt update && sudo apt install -y musl-dev musl-tools
if ! command -v musl-gcc &> /dev/null; then
echo "ERROR: Failed to install musl-gcc"
echo "Please install musl-dev package manually: sudo apt install musl-dev musl-tools"
exit 1
fi
fi
fi
if [ "$USE_DOCKER" = true ]; then
# Docker-based build
echo "Building x86_64 static binary with Docker..."
sudo docker buildx build \
--platform linux/amd64 \
-f "$SCRIPT_DIR/examples/deployment/static-builder.Dockerfile" \
-t c-relay-static-builder-x86_64 \
--load \
"$SCRIPT_DIR"
# Extract x86_64 binary
sudo docker run --rm -v "$BUILD_DIR:/output" c-relay-static-builder-x86_64 \
sh -c "cp /c_relay_static_musl_x86_64 /output/c_relay_static_x86_64"
echo "x86_64 static binary created: $BUILD_DIR/c_relay_static_x86_64"
# Build ARM64 static binary
echo "Building ARM64 static binary with Docker..."
sudo docker buildx build \
--platform linux/arm64 \
-f "$SCRIPT_DIR/examples/deployment/static-builder.Dockerfile" \
-t c-relay-static-builder-arm64 \
--load \
"$SCRIPT_DIR"
# Extract ARM64 binary
sudo docker run --rm -v "$BUILD_DIR:/output" c-relay-static-builder-arm64 \
sh -c "cp /c_relay_static_musl_arm64 /output/c_relay_static_arm64"
echo "ARM64 static binary created: $BUILD_DIR/c_relay_static_arm64"
else
# Native static build with regular gcc
echo "Building static binary with gcc..."
# Check for required static libraries
echo "Checking for static libraries..."
MISSING_LIBS=""
for lib in libsqlite3.a libssl.a libcrypto.a libz.a; do
if ! find /usr/lib* /usr/local/lib* -name "$lib" 2>/dev/null | head -1 | grep -q .; then
MISSING_LIBS="$MISSING_LIBS $lib"
fi
done
# libsecp256k1 might not be available as static lib, so we'll try without it first
# Initialize submodules if needed
if [ ! -f "nostr_core_lib/libnostr_core_x64.a" ]; then
echo "Building nostr_core_lib..."
git submodule update --init --recursive
cd nostr_core_lib && ./build.sh && cd ..
fi
# Install additional static libraries needed for libwebsockets
echo "Installing additional static libraries..."
sudo apt install -y libcap-dev libuv1-dev libev-dev
# Try building with regular gcc and static linking
echo "Compiling with gcc -static..."
# Use the same approach as the regular Makefile but with static linking
gcc -static -O2 -Wall -Wextra -std=c99 -g \
-I. -Inostr_core_lib -Inostr_core_lib/nostr_core -Inostr_core_lib/cjson -Inostr_core_lib/nostr_websocket \
src/main.c src/config.c src/dm_admin.c src/request_validator.c src/nip009.c src/nip011.c src/nip013.c src/nip040.c src/nip042.c src/websockets.c src/subscriptions.c src/api.c src/embedded_web_content.c \
-o "$BUILD_DIR/c_relay_static_x86_64" \
nostr_core_lib/libnostr_core_x64.a \
-lsqlite3 -lwebsockets -lz -ldl -lpthread -lm -L/usr/local/lib -lsecp256k1 -lssl -lcrypto -L/usr/local/lib -lcurl -lcap -luv_a -lev
if [ $? -eq 0 ]; then
echo "x86_64 static binary created: $BUILD_DIR/c_relay_static_x86_64"
else
echo "ERROR: Static build failed"
echo "This may be due to missing static libraries or incompatible library versions"
echo "Consider using Docker-based build instead"
exit 1
fi
fi
# Verify binaries
echo "Verifying static binaries..."
for binary in "$BUILD_DIR"/c_relay_static_*; do
if [ -f "$binary" ]; then
echo "Binary: $(basename "$binary")"
file "$binary"
ls -lh "$binary"
# Test if binary is truly static (no dynamic dependencies)
if ldd "$binary" 2>/dev/null | grep -q "not a dynamic executable"; then
echo "✓ Binary is fully static"
elif ldd "$binary" 2>/dev/null | grep -q "statically linked"; then
echo "✓ Binary is statically linked"
else
echo "⚠ Binary may have dynamic dependencies:"
ldd "$binary" 2>/dev/null || echo " (ldd check failed)"
fi
echo ""
fi
done
echo "Static build complete!"
echo "Binaries available in: $BUILD_DIR/"
ls -la "$BUILD_DIR"/c_relay_static_* 2>/dev/null || echo "No static binaries found"
echo ""
echo "These binaries should have minimal runtime dependencies and work across Linux distributions."

3
deploy_local.sh Executable file
View File

@@ -0,0 +1,3 @@
#!/bin/bash
cp build/c_relay_x86 ~/Storage/c_relay/crelay

36
docs/user_guide.md
View File

@@ -6,6 +6,7 @@ Complete guide for deploying, configuring, and managing the C Nostr Relay with e
- [Quick Start](#quick-start)
- [Installation](#installation)
- [Web Admin Interface](#web-admin-interface)
- [Configuration Management](#configuration-management)
- [Administration](#administration)
- [Monitoring](#monitoring)
@@ -43,7 +44,8 @@ Admin Public Key: 68394d08ab87f936a42ff2deb15a84fbdfbe0996ee0eb20cda064aae67328
### 3. Connect Clients
Your relay is now available at:
- **WebSocket**: `ws://localhost:8888`
- **NIP-11 Info**: `http://localhost:8888`
- **NIP-11 Info**: `http://localhost:8888` (with `Accept: application/nostr+json` header)
- **Web Admin Interface**: `http://localhost:8888/api/` (serves embedded admin interface)
## Installation
@@ -211,6 +213,38 @@ Send this to your relay via WebSocket, and changes are applied immediately.
| `nip40_expiration_filter` | Filter expired events | "true" | "true", "false" |
| `nip40_expiration_grace_period` | Grace period (seconds) | "300" | 0-86400 |
## Web Admin Interface
The relay includes a built-in web-based administration interface that provides a user-friendly way to manage your relay without command-line tools.
### Accessing the Interface
1. **Open your browser** and navigate to: `http://localhost:8888/api/`
2. **Authenticate** using your Nostr identity (the admin interface uses NIP-42 authentication)
3. **Manage configuration** through the web interface
### Features
- **Real-time Configuration**: View and edit all relay settings
- **Database Statistics**: Monitor event counts, storage usage, and performance metrics
- **Auth Rules Management**: Configure whitelist/blacklist rules for pubkeys
- **Relay Connection Testing**: Verify WebSocket connectivity and NIP-11 information
- **Event-Based Updates**: All changes are applied as signed Nostr events
### Security Notes
- The web interface requires NIP-42 authentication with your admin pubkey
- All configuration changes are cryptographically signed
- The interface serves embedded static files (no external dependencies)
- CORS headers are included for proper browser operation
### Browser Compatibility
The admin interface works with modern browsers that support:
- WebSocket connections
- ES6 JavaScript features
- Modern CSS Grid and Flexbox layouts
## Administration
### Viewing Current Configuration

128
embed_web_files.sh Executable file
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@@ -0,0 +1,128 @@
#!/bin/bash
# Script to embed web files into C headers for the C-Relay admin interface
# Converts HTML, CSS, and JS files from api/ directory into C byte arrays
set -e
echo "Embedding web files into C headers..."
# Output directory for generated headers
OUTPUT_DIR="src"
mkdir -p "$OUTPUT_DIR"
# Function to convert a file to C byte array
file_to_c_array() {
local input_file="$1"
local array_name="$2"
local output_file="$3"
# Get file size
local file_size=$(stat -c%s "$input_file" 2>/dev/null || stat -f%z "$input_file" 2>/dev/null || echo "0")
echo "// Auto-generated from $input_file" >> "$output_file"
echo "static const unsigned char ${array_name}_data[] = {" >> "$output_file"
# Convert file to hex bytes
hexdump -v -e '1/1 "0x%02x,"' "$input_file" >> "$output_file"
echo "};" >> "$output_file"
echo "static const size_t ${array_name}_size = $file_size;" >> "$output_file"
echo "" >> "$output_file"
}
# Generate the header file
HEADER_FILE="$OUTPUT_DIR/embedded_web_content.h"
echo "// Auto-generated embedded web content header" > "$HEADER_FILE"
echo "// Do not edit manually - generated by embed_web_files.sh" >> "$HEADER_FILE"
echo "" >> "$HEADER_FILE"
echo "#ifndef EMBEDDED_WEB_CONTENT_H" >> "$HEADER_FILE"
echo "#define EMBEDDED_WEB_CONTENT_H" >> "$HEADER_FILE"
echo "" >> "$HEADER_FILE"
echo "#include <stddef.h>" >> "$HEADER_FILE"
echo "" >> "$HEADER_FILE"
# Generate the C file
SOURCE_FILE="$OUTPUT_DIR/embedded_web_content.c"
echo "// Auto-generated embedded web content" > "$SOURCE_FILE"
echo "// Do not edit manually - generated by embed_web_files.sh" >> "$SOURCE_FILE"
echo "" >> "$SOURCE_FILE"
echo "#include \"embedded_web_content.h\"" >> "$SOURCE_FILE"
echo "#include <string.h>" >> "$SOURCE_FILE"
echo "" >> "$SOURCE_FILE"
# Process each web file
declare -A file_map
# Find all web files
for file in api/*.html api/*.css api/*.js; do
if [ -f "$file" ]; then
# Get filename without path
basename=$(basename "$file")
# Create C identifier from filename
c_name=$(echo "$basename" | sed 's/[^a-zA-Z0-9_]/_/g' | sed 's/^_//')
# Determine content type
case "$file" in
*.html) content_type="text/html" ;;
*.css) content_type="text/css" ;;
*.js) content_type="application/javascript" ;;
*) content_type="text/plain" ;;
esac
echo "Processing $file -> ${c_name}"
# No extern declarations needed - data is accessed through get_embedded_file()
# Add to source
file_to_c_array "$file" "$c_name" "$SOURCE_FILE"
# Store mapping for lookup function
file_map["/$basename"]="$c_name:$content_type"
if [ "$basename" = "index.html" ]; then
file_map["/"]="$c_name:$content_type"
fi
fi
done
# Generate lookup function
echo "// Embedded file lookup function" >> "$HEADER_FILE"
echo "typedef struct {" >> "$HEADER_FILE"
echo " const char *path;" >> "$HEADER_FILE"
echo " const unsigned char *data;" >> "$HEADER_FILE"
echo " size_t size;" >> "$HEADER_FILE"
echo " const char *content_type;" >> "$HEADER_FILE"
echo "} embedded_file_t;" >> "$HEADER_FILE"
echo "" >> "$HEADER_FILE"
echo "embedded_file_t *get_embedded_file(const char *path);" >> "$HEADER_FILE"
echo "" >> "$HEADER_FILE"
echo "#endif // EMBEDDED_WEB_CONTENT_H" >> "$HEADER_FILE"
# Generate lookup function implementation
echo "// File mapping" >> "$SOURCE_FILE"
echo "static embedded_file_t embedded_files[] = {" >> "$SOURCE_FILE"
for path in "${!file_map[@]}"; do
entry="${file_map[$path]}"
c_name="${entry%:*}"
content_type="${entry#*:}"
echo " {\"$path\", ${c_name}_data, ${c_name}_size, \"$content_type\"}," >> "$SOURCE_FILE"
done
echo " {NULL, NULL, 0, NULL} // Sentinel" >> "$SOURCE_FILE"
echo "};" >> "$SOURCE_FILE"
echo "" >> "$SOURCE_FILE"
echo "embedded_file_t *get_embedded_file(const char *path) {" >> "$SOURCE_FILE"
echo " for (int i = 0; embedded_files[i].path != NULL; i++) {" >> "$SOURCE_FILE"
echo " if (strcmp(path, embedded_files[i].path) == 0) {" >> "$SOURCE_FILE"
echo " return &embedded_files[i];" >> "$SOURCE_FILE"
echo " }" >> "$SOURCE_FILE"
echo " }" >> "$SOURCE_FILE"
echo " return NULL;" >> "$SOURCE_FILE"
echo "}" >> "$SOURCE_FILE"
echo "Web file embedding complete. Generated:" >&2
echo " $HEADER_FILE" >&2
echo " $SOURCE_FILE" >&2

136
examples/deployment/static-builder.Dockerfile Normal file
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@@ -0,0 +1,136 @@
# MUSL-based fully static C-Relay builder
# Produces portable binaries with zero runtime dependencies
FROM alpine:latest AS builder
# Add alternative mirrors and install build dependencies with retry
RUN echo "http://dl-cdn.alpinelinux.org/alpine/v3.22/main" > /etc/apk/repositories && \
echo "http://dl-cdn.alpinelinux.org/alpine/v3.22/community" >> /etc/apk/repositories && \
echo "http://mirror.leaseweb.com/alpine/v3.22/main" >> /etc/apk/repositories && \
echo "http://mirror.leaseweb.com/alpine/v3.22/community" >> /etc/apk/repositories && \
apk update --no-cache || (sleep 5 && apk update --no-cache) || (sleep 10 && apk update --no-cache)
# Install build dependencies with retry logic
RUN apk add --no-cache \
build-base \
musl-dev \
git \
cmake \
pkgconfig \
autoconf \
automake \
libtool \
openssl-dev \
openssl-libs-static \
zlib-dev \
zlib-static \
curl-dev \
curl-static \
sqlite-dev \
sqlite-static \
linux-headers || \
(sleep 10 && apk add --no-cache \
build-base \
musl-dev \
git \
cmake \
pkgconfig \
autoconf \
automake \
libtool \
openssl-dev \
openssl-libs-static \
zlib-dev \
zlib-static \
curl-dev \
curl-static \
sqlite-dev \
sqlite-static \
linux-headers)
# Set working directory
WORKDIR /build
# Build zlib static (if needed)
RUN if [ ! -f /usr/lib/libz.a ]; then \
cd /tmp && \
wget https://zlib.net/zlib-1.3.1.tar.gz && \
tar xzf zlib-1.3.1.tar.gz && \
cd zlib-1.3.1 && \
./configure --static --prefix=/usr && \
make && make install; \
fi
# Build OpenSSL static
RUN cd /tmp && \
wget https://www.openssl.org/source/openssl-3.0.13.tar.gz && \
tar xzf openssl-3.0.13.tar.gz && \
cd openssl-3.0.13 && \
./Configure linux-x86_64 no-shared --prefix=/usr && \
make && make install_sw
# Build libsecp256k1 static
RUN cd /tmp && \
git clone https://github.com/bitcoin-core/secp256k1.git && \
cd secp256k1 && \
./autogen.sh && \
./configure --enable-static --disable-shared --prefix=/usr && \
make && make install
# Build libwebsockets static with OpenSSL
RUN cd /tmp && \
git clone https://github.com/warmcat/libwebsockets.git && \
cd libwebsockets && \
mkdir build && cd build && \
cmake .. \
-DLWS_WITH_STATIC=ON \
-DLWS_WITH_SHARED=OFF \
-DLWS_WITH_SSL=ON \
-DLWS_OPENSSL_LIBRARIES="/usr/lib/libssl.a;/usr/lib/libcrypto.a" \
-DLWS_OPENSSL_INCLUDE_DIRS="/usr/include" \
-DCMAKE_BUILD_TYPE=Release \
-DCMAKE_INSTALL_PREFIX=/usr && \
make && make install
# Build curl static (minimal features)
RUN cd /tmp && \
wget https://curl.se/download/curl-8.6.0.tar.gz && \
tar xzf curl-8.6.0.tar.gz && \
cd curl-8.6.0 && \
./configure \
--disable-shared \
--enable-static \
--disable-ldap \
--without-libidn2 \
--without-brotli \
--without-zstd \
--without-rtmp \
--without-libpsl \
--without-krb5 \
--with-openssl \
--prefix=/usr && \
make && make install
# Copy c-relay source
COPY . /build/
# Initialize submodules
RUN git submodule update --init --recursive
# Build nostr_core_lib
RUN cd nostr_core_lib && ./build.sh
# Build c-relay static
RUN make clean && \
CC="musl-gcc -static" \
CFLAGS="-O2 -Wall -Wextra -std=c99 -g" \
LDFLAGS="-static -Wl,--whole-archive -lpthread -Wl,--no-whole-archive" \
LIBS="-lsqlite3 -lwebsockets -lz -ldl -lpthread -lm -lsecp256k1 -lssl -lcrypto -lcurl" \
make
# Strip binary for size
RUN strip build/c_relay_x86
# Multi-stage build to produce minimal output
FROM scratch AS output
COPY --from=builder /build/build/c_relay_x86 /c_relay_static_musl_x86_64

4
make_and_restart_relay.sh
View File

@@ -159,6 +159,10 @@ fi
rm -rf dev-config/ 2>/dev/null
rm -f db/c_nostr_relay.db* 2>/dev/null
# Embed web files into C headers before building
echo "Embedding web files..."
./embed_web_files.sh
# Build the project first
echo "Building project..."
make clean all

3
nip_11_curl.sh Executable file
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@@ -0,0 +1,3 @@
#!/bin/bash
curl -H "Accept: application/nostr+json" http://localhost:8888/

153
node_modules/.package-lock.json generated vendored Normal file
View File

@@ -0,0 +1,153 @@
{
"name": "c-relay",
"lockfileVersion": 3,
"requires": true,
"packages": {
"node_modules/@noble/ciphers": {
"version": "0.5.3",
"resolved": "https://registry.npmjs.org/@noble/ciphers/-/ciphers-0.5.3.tgz",
"integrity": "sha512-B0+6IIHiqEs3BPMT0hcRmHvEj2QHOLu+uwt+tqDDeVd0oyVzh7BPrDcPjRnV1PV/5LaknXJJQvOuRGR0zQJz+w==",
"license": "MIT",
"funding": {
"url": "https://paulmillr.com/funding/"
}
},
"node_modules/@noble/curves": {
"version": "1.2.0",
"resolved": "https://registry.npmjs.org/@noble/curves/-/curves-1.2.0.tgz",
"integrity": "sha512-oYclrNgRaM9SsBUBVbb8M6DTV7ZHRTKugureoYEncY5c65HOmRzvSiTE3y5CYaPYJA/GVkrhXEoF0M3Ya9PMnw==",
"license": "MIT",
"dependencies": {
"@noble/hashes": "1.3.2"
},
"funding": {
"url": "https://paulmillr.com/funding/"
}
},
"node_modules/@noble/curves/node_modules/@noble/hashes": {
"version": "1.3.2",
"resolved": "https://registry.npmjs.org/@noble/hashes/-/hashes-1.3.2.tgz",
"integrity": "sha512-MVC8EAQp7MvEcm30KWENFjgR+Mkmf+D189XJTkFIlwohU5hcBbn1ZkKq7KVTi2Hme3PMGF390DaL52beVrIihQ==",
"license": "MIT",
"engines": {
"node": ">= 16"
},
"funding": {
"url": "https://paulmillr.com/funding/"
}
},
"node_modules/@noble/hashes": {
"version": "1.3.1",
"resolved": "https://registry.npmjs.org/@noble/hashes/-/hashes-1.3.1.tgz",
"integrity": "sha512-EbqwksQwz9xDRGfDST86whPBgM65E0OH/pCgqW0GBVzO22bNE+NuIbeTb714+IfSjU3aRk47EUvXIb5bTsenKA==",
"license": "MIT",
"engines": {
"node": ">= 16"
},
"funding": {
"url": "https://paulmillr.com/funding/"
}
},
"node_modules/@scure/base": {
"version": "1.1.1",
"resolved": "https://registry.npmjs.org/@scure/base/-/base-1.1.1.tgz",
"integrity": "sha512-ZxOhsSyxYwLJj3pLZCefNitxsj093tb2vq90mp2txoYeBqbcjDjqFhyM8eUjq/uFm6zJ+mUuqxlS2FkuSY1MTA==",
"funding": [
{
"type": "individual",
"url": "https://paulmillr.com/funding/"
}
],
"license": "MIT"
},
"node_modules/@scure/bip32": {
"version": "1.3.1",
"resolved": "https://registry.npmjs.org/@scure/bip32/-/bip32-1.3.1.tgz",
"integrity": "sha512-osvveYtyzdEVbt3OfwwXFr4P2iVBL5u1Q3q4ONBfDY/UpOuXmOlbgwc1xECEboY8wIays8Yt6onaWMUdUbfl0A==",
"license": "MIT",
"dependencies": {
"@noble/curves": "~1.1.0",
"@noble/hashes": "~1.3.1",
"@scure/base": "~1.1.0"
},
"funding": {
"url": "https://paulmillr.com/funding/"
}
},
"node_modules/@scure/bip32/node_modules/@noble/curves": {
"version": "1.1.0",
"resolved": "https://registry.npmjs.org/@noble/curves/-/curves-1.1.0.tgz",
"integrity": "sha512-091oBExgENk/kGj3AZmtBDMpxQPDtxQABR2B9lb1JbVTs6ytdzZNwvhxQ4MWasRNEzlbEH8jCWFCwhF/Obj5AA==",
"license": "MIT",
"dependencies": {
"@noble/hashes": "1.3.1"
},
"funding": {
"url": "https://paulmillr.com/funding/"
}
},
"node_modules/@scure/bip39": {
"version": "1.2.1",
"resolved": "https://registry.npmjs.org/@scure/bip39/-/bip39-1.2.1.tgz",
"integrity": "sha512-Z3/Fsz1yr904dduJD0NpiyRHhRYHdcnyh73FZWiV+/qhWi83wNJ3NWolYqCEN+ZWsUz2TWwajJggcRE9r1zUYg==",
"license": "MIT",
"dependencies": {
"@noble/hashes": "~1.3.0",
"@scure/base": "~1.1.0"
},
"funding": {
"url": "https://paulmillr.com/funding/"
}
},
"node_modules/nostr-tools": {
"version": "2.17.0",
"resolved": "https://registry.npmjs.org/nostr-tools/-/nostr-tools-2.17.0.tgz",
"integrity": "sha512-lrvHM7cSaGhz7F0YuBvgHMoU2s8/KuThihDoOYk8w5gpVHTy0DeUCAgCN8uLGeuSl5MAWekJr9Dkfo5HClqO9w==",
"license": "Unlicense",
"dependencies": {
"@noble/ciphers": "^0.5.1",
"@noble/curves": "1.2.0",
"@noble/hashes": "1.3.1",
"@scure/base": "1.1.1",
"@scure/bip32": "1.3.1",
"@scure/bip39": "1.2.1",
"nostr-wasm": "0.1.0"
},
"peerDependencies": {
"typescript": ">=5.0.0"
},
"peerDependenciesMeta": {
"typescript": {
"optional": true
}
}
},
"node_modules/nostr-wasm": {
"version": "0.1.0",
"resolved": "https://registry.npmjs.org/nostr-wasm/-/nostr-wasm-0.1.0.tgz",
"integrity": "sha512-78BTryCLcLYv96ONU8Ws3Q1JzjlAt+43pWQhIl86xZmWeegYCNLPml7yQ+gG3vR6V5h4XGj+TxO+SS5dsThQIA==",
"license": "MIT"
},
"node_modules/ws": {
"version": "8.18.3",
"resolved": "https://registry.npmjs.org/ws/-/ws-8.18.3.tgz",
"integrity": "sha512-PEIGCY5tSlUt50cqyMXfCzX+oOPqN0vuGqWzbcJ2xvnkzkq46oOpz7dQaTDBdfICb4N14+GARUDw2XV2N4tvzg==",
"license": "MIT",
"engines": {
"node": ">=10.0.0"
},
"peerDependencies": {
"bufferutil": "^4.0.1",
"utf-8-validate": ">=5.0.2"
},
"peerDependenciesMeta": {
"bufferutil": {
"optional": true
},
"utf-8-validate": {
"optional": true
}
}
}
}
}

22
node_modules/@noble/ciphers/LICENSE generated vendored Normal file
View File

@@ -0,0 +1,22 @@
The MIT License (MIT)
Copyright (c) 2022 Paul Miller (https://paulmillr.com)
Copyright (c) 2016 Thomas Pornin <pornin@bolet.org>
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the “Software”), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED “AS IS”, WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.

655
node_modules/@noble/ciphers/README.md generated vendored Normal file
View File

@@ -0,0 +1,655 @@
# noble-ciphers
Auditable & minimal JS implementation of Salsa20, ChaCha and AES.
- 🔒 Auditable
- 🔻 Tree-shaking-friendly: use only what's necessary, other code won't be included
- 🏎 [Ultra-fast](#speed), hand-optimized for caveats of JS engines
- 🔍 Unique tests ensure correctness: property-based, cross-library and Wycheproof vectors
- 💼 AES: ECB, CBC, CTR, CFB, GCM, SIV (nonce misuse-resistant)
- 💃 Salsa20, ChaCha, XSalsa20, XChaCha, Poly1305, ChaCha8, ChaCha12
- 🥈 Two AES implementations: choose between friendly webcrypto wrapper and pure JS one
- 🪶 45KB (8KB gzipped) for everything, 10KB (3KB gzipped) for ChaCha build
For discussions, questions and support, visit
[GitHub Discussions](https://github.com/paulmillr/noble-ciphers/discussions)
section of the repository.
### This library belongs to _noble_ cryptography
> **noble cryptography** — high-security, easily auditable set of contained cryptographic libraries and tools.
- Zero or minimal dependencies
- Highly readable TypeScript / JS code
- PGP-signed releases and transparent NPM builds
- All libraries:
[ciphers](https://github.com/paulmillr/noble-ciphers),
[curves](https://github.com/paulmillr/noble-curves),
[hashes](https://github.com/paulmillr/noble-hashes),
[post-quantum](https://github.com/paulmillr/noble-post-quantum),
4kb [secp256k1](https://github.com/paulmillr/noble-secp256k1) /
[ed25519](https://github.com/paulmillr/noble-ed25519)
- [Check out homepage](https://paulmillr.com/noble/)
for reading resources, documentation and apps built with noble
## Usage
> npm install @noble/ciphers
We support all major platforms and runtimes.
For [Deno](https://deno.land), ensure to use
[npm specifier](https://deno.land/manual@v1.28.0/node/npm_specifiers).
For React Native, you may need a
[polyfill for getRandomValues](https://github.com/LinusU/react-native-get-random-values).
A standalone file
[noble-ciphers.js](https://github.com/paulmillr/noble-ciphers/releases) is also available.
```js
// import * from '@noble/ciphers'; // Error: use sub-imports, to ensure small app size
import { xchacha20poly1305 } from '@noble/ciphers/chacha';
// import { xchacha20poly1305 } from 'npm:@noble/ciphers@0.5.0/chacha'; // Deno
```
- [Examples](#examples)
- [Encrypt with XChaCha20-Poly1305](#encrypt-with-xchacha20-poly1305)
- [Encrypt with AES-256-GCM](#encrypt-with-aes-256-gcm)
- [Use existing key instead of a new one](#use-existing-key-instead-of-a-new-one)
- [Encrypt without nonce](#encrypt-without-nonce)
- [Use same array for input and output](#use-same-array-for-input-and-output)
- [All imports](#all-imports)
- [Implementations](#implementations)
- [Salsa20](#salsa)
- [ChaCha](#chacha)
- [AES](#aes)
- [Webcrypto AES](#webcrypto-aes)
- [Poly1305, GHash, Polyval](#poly1305-ghash-polyval)
- [FF1 format-preserving encryption](#ff1)
- [Managed nonces](#managed-nonces)
- [Guidance](#guidance)
- [Which cipher should I pick?](#which-cipher-should-i-pick)
- [How to encrypt properly](#how-to-encrypt-properly)
- [Nonces](#nonces)
- [Encryption limits](#encryption-limits)
- [AES internals and block modes](#aes-internals-and-block-modes)
- [Security](#security)
- [Speed](#speed)
- [Upgrading](#upgrading)
- [Contributing & testing](#contributing--testing)
- [Resources](#resources)
## Examples
#### Encrypt with XChaCha20-Poly1305
```js
import { xchacha20poly1305 } from '@noble/ciphers/chacha';
import { utf8ToBytes } from '@noble/ciphers/utils';
import { randomBytes } from '@noble/ciphers/webcrypto';
const key = randomBytes(32);
const nonce = randomBytes(24);
const chacha = xchacha20poly1305(key, nonce);
const data = utf8ToBytes('hello, noble');
const ciphertext = chacha.encrypt(data);
const data_ = chacha.decrypt(ciphertext); // utils.bytesToUtf8(data_) === data
```
#### Encrypt with AES-256-GCM
```js
import { gcm } from '@noble/ciphers/aes';
import { utf8ToBytes } from '@noble/ciphers/utils';
import { randomBytes } from '@noble/ciphers/webcrypto';
const key = randomBytes(32);
const nonce = randomBytes(24);
const aes = gcm(key, nonce);
const data = utf8ToBytes('hello, noble');
const ciphertext = aes.encrypt(data);
const data_ = aes.decrypt(ciphertext); // utils.bytesToUtf8(data_) === data
```
#### Use existing key instead of a new one
```js
const key = new Uint8Array([
169, 88, 160, 139, 168, 29, 147, 196, 14, 88, 237, 76, 243, 177, 109, 140, 195, 140, 80, 10, 216,
134, 215, 71, 191, 48, 20, 104, 189, 37, 38, 55,
]);
const nonce = new Uint8Array([
180, 90, 27, 63, 160, 191, 150, 33, 67, 212, 86, 71, 144, 6, 200, 102, 218, 32, 23, 147, 8, 41,
147, 11,
]);
// or, hex:
import { hexToBytes } from '@noble/ciphers/utils';
const key2 = hexToBytes('4b7f89bac90a1086fef73f5da2cbe93b2fae9dfbf7678ae1f3e75fd118ddf999');
const nonce2 = hexToBytes('9610467513de0bbd7c4cc2c3c64069f1802086fbd3232b13');
```
#### Encrypt without nonce
```js
import { xchacha20poly1305 } from '@noble/ciphers/chacha';
import { managedNonce } from '@noble/ciphers/webcrypto';
import { hexToBytes, utf8ToBytes } from '@noble/ciphers/utils';
const key = hexToBytes('fa686bfdffd3758f6377abbc23bf3d9bdc1a0dda4a6e7f8dbdd579fa1ff6d7e1');
const chacha = managedNonce(xchacha20poly1305)(key); // manages nonces for you
const data = utf8ToBytes('hello, noble');
const ciphertext = chacha.encrypt(data);
const data_ = chacha.decrypt(ciphertext);
```
#### Use same array for input and output
```js
import { chacha20poly1305 } from '@noble/ciphers/chacha';
import { utf8ToBytes } from '@noble/ciphers/utils';
import { randomBytes } from '@noble/ciphers/webcrypto';
const key = randomBytes(32);
const nonce = randomBytes(12);
const buf = new Uint8Array(12 + 16);
const _data = utf8ToBytes('hello, noble');
buf.set(_data, 0); // first 12 bytes
const _12b = buf.subarray(0, 12);
const chacha = chacha20poly1305(key, nonce);
chacha.encrypt(_12b, buf);
chacha.decrypt(buf, _12b); // _12b now same as _data
```
#### All imports
```js
import { gcm, siv } from '@noble/ciphers/aes';
import { xsalsa20poly1305 } from '@noble/ciphers/salsa';
import { chacha20poly1305, xchacha20poly1305 } from '@noble/ciphers/chacha';
// Unauthenticated encryption: make sure to use HMAC or similar
import { ctr, cfb, cbc, ecb } from '@noble/ciphers/aes';
import { salsa20, xsalsa20 } from '@noble/ciphers/salsa';
import { chacha20, xchacha20, chacha8, chacha12 } from '@noble/ciphers/chacha';
// Utilities
import { bytesToHex, hexToBytes, bytesToUtf8, utf8ToBytes } from '@noble/ciphers/utils';
import { managedNonce, randomBytes } from '@noble/ciphers/webcrypto';
```
## Implementations
### Salsa
```js
import { xsalsa20poly1305 } from '@noble/ciphers/salsa';
import { secretbox } from '@noble/ciphers/salsa'; // == xsalsa20poly1305
import { salsa20, xsalsa20 } from '@noble/ciphers/salsa';
```
[Salsa20](https://cr.yp.to/snuffle.html) stream cipher was released in 2005.
Salsa's goal was to implement AES replacement that does not rely on S-Boxes,
which are hard to implement in a constant-time manner.
Salsa20 is usually faster than AES, a big deal on slow, budget mobile phones.
[XSalsa20](https://cr.yp.to/snuffle/xsalsa-20110204.pdf), extended-nonce
variant was released in 2008. It switched nonces from 96-bit to 192-bit,
and became safe to be picked at random.
Nacl / Libsodium popularized term "secretbox", a simple black-box
authenticated encryption. Secretbox is just xsalsa20-poly1305. We provide the
alias and corresponding seal / open methods. We don't provide "box" or "sealedbox".
Check out [PDF](https://cr.yp.to/snuffle/salsafamily-20071225.pdf) and
[wiki](https://en.wikipedia.org/wiki/Salsa20).
### ChaCha
```js
import { chacha20poly1305, xchacha20poly1305 } from '@noble/ciphers/chacha';
import { chacha20, xchacha20, chacha8, chacha12 } from '@noble/ciphers/chacha';
```
[ChaCha20](https://cr.yp.to/chacha.html) stream cipher was released
in 2008. ChaCha aims to increase the diffusion per round, but had slightly less
cryptanalysis. It was standardized in
[RFC 8439](https://datatracker.ietf.org/doc/html/rfc8439) and is now used in TLS 1.3.
[XChaCha20](https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha)
extended-nonce variant is also provided. Similar to XSalsa, it's safe to use with
randomly-generated nonces.
Check out [PDF](http://cr.yp.to/chacha/chacha-20080128.pdf) and [wiki](https://en.wikipedia.org/wiki/Salsa20).
### AES
```js
import { gcm, siv, ctr, cfb, cbc, ecb } from '@noble/ciphers/aes';
import { randomBytes } from '@noble/ciphers/webcrypto';
const plaintext = new Uint8Array(32).fill(16);
const key = randomBytes(32); // 24 for AES-192, 16 for AES-128
for (let cipher of [gcm, siv]) {
const stream = cipher(key, randomBytes(12));
const ciphertext_ = stream.encrypt(plaintext);
const plaintext_ = stream.decrypt(ciphertext_);
}
for (const cipher of [ctr, cbc, cbc]) {
const stream = cipher(key, randomBytes(16));
const ciphertext_ = stream.encrypt(plaintext);
const plaintext_ = stream.decrypt(ciphertext_);
}
for (const cipher of [ecb]) {
const stream = cipher(key);
const ciphertext_ = stream.encrypt(plaintext);
const plaintext_ = stream.decrypt(ciphertext_);
}
```
[AES](https://en.wikipedia.org/wiki/Advanced_Encryption_Standard)
is a variant of Rijndael block cipher, standardized by NIST in 2001.
We provide the fastest available pure JS implementation.
We support AES-128, AES-192 and AES-256: the mode is selected dynamically,
based on key length (16, 24, 32).
[AES-GCM-SIV](https://en.wikipedia.org/wiki/AES-GCM-SIV)
nonce-misuse-resistant mode is also provided. It's recommended to use it,
to prevent catastrophic consequences of nonce reuse. Our implementation of SIV
has the same speed as GCM: there is no performance hit.
Check out [AES internals and block modes](#aes-internals-and-block-modes).
### Webcrypto AES
```js
import { gcm, ctr, cbc, randomBytes } from '@noble/ciphers/webcrypto';
const plaintext = new Uint8Array(32).fill(16);
const key = randomBytes(32);
for (const cipher of [gcm]) {
const stream = cipher(key, randomBytes(12));
const ciphertext_ = await stream.encrypt(plaintext);
const plaintext_ = await stream.decrypt(ciphertext_);
}
for (const cipher of [ctr, cbc]) {
const stream = cipher(key, randomBytes(16));
const ciphertext_ = await stream.encrypt(plaintext);
const plaintext_ = await stream.decrypt(ciphertext_);
}
```
We also have a separate wrapper over WebCrypto built-in.
It's the same as using `crypto.subtle`, but with massively simplified API.
Unlike pure js version, it's asynchronous.
### Poly1305, GHash, Polyval
```js
import { poly1305 } from '@noble/ciphers/_poly1305';
import { ghash, polyval } from '@noble/ciphers/_polyval';
```
We expose polynomial-evaluation MACs: [Poly1305](https://cr.yp.to/mac.html),
AES-GCM's [GHash](https://en.wikipedia.org/wiki/Galois/Counter_Mode) and
AES-SIV's [Polyval](https://en.wikipedia.org/wiki/AES-GCM-SIV).
Poly1305 ([PDF](https://cr.yp.to/mac/poly1305-20050329.pdf),
[wiki](https://en.wikipedia.org/wiki/Poly1305))
is a fast and parallel secret-key message-authentication code suitable for
a wide variety of applications. It was standardized in
[RFC 8439](https://datatracker.ietf.org/doc/html/rfc8439) and is now used in TLS 1.3.
Polynomial MACs are not perfect for every situation:
they lack Random Key Robustness: the MAC can be forged, and can't
be used in PAKE schemes. See
[invisible salamanders attack](https://keymaterial.net/2020/09/07/invisible-salamanders-in-aes-gcm-siv/).
To combat invisible salamanders, `hash(key)` can be included in ciphertext,
however, this would violate ciphertext indistinguishability:
an attacker would know which key was used - so `HKDF(key, i)`
could be used instead.
### FF1
Format-preserving encryption algorithm (FPE-FF1) specified in NIST Special Publication 800-38G.
[See more info](https://nvlpubs.nist.gov/nistpubs/SpecialPublications/NIST.SP.800-38G.pdf).
### Managed nonces
```js
import { managedNonce } from '@noble/ciphers/webcrypto';
import { gcm, siv, ctr, cbc, cbc, ecb } from '@noble/ciphers/aes';
import { xsalsa20poly1305 } from '@noble/ciphers/salsa';
import { chacha20poly1305, xchacha20poly1305 } from '@noble/ciphers/chacha';
const wgcm = managedNonce(gcm);
const wsiv = managedNonce(siv);
const wcbc = managedNonce(cbc);
const wctr = managedNonce(ctr);
const wsalsapoly = managedNonce(xsalsa20poly1305);
const wchacha = managedNonce(chacha20poly1305);
const wxchacha = managedNonce(xchacha20poly1305);
// Now:
const encrypted = wgcm(key).encrypt(data); // no nonces
```
We provide API that manages nonce internally instead of exposing them to library's user.
For `encrypt`, a `nonceBytes`-length buffer is fetched from CSPRNG and prenended to encrypted ciphertext.
For `decrypt`, first `nonceBytes` of ciphertext are treated as nonce.
## Guidance
### Which cipher should I pick?
XChaCha20-Poly1305 is the safest bet these days.
AES-GCM-SIV is the second safest.
AES-GCM is the third.
### How to encrypt properly
- Use unpredictable key with enough entropy
- Random key must be using cryptographically secure random number generator (CSPRNG), not `Math.random` etc.
- Non-random key generated from KDF is fine
- Re-using key is fine, but be aware of rules for cryptographic key wear-out and [encryption limits](#encryption-limits)
- Use new nonce every time and [don't repeat it](#nonces)
- chacha and salsa20 are fine for sequential counters that _never_ repeat: `01, 02...`
- xchacha and xsalsa20 should be used for random nonces instead
- Prefer authenticated encryption (AEAD)
- HMAC+ChaCha / HMAC+AES / chacha20poly1305 / aes-gcm is good
- chacha20 without poly1305 or hmac / aes-ctr / aes-cbc is bad
- Flipping bits or ciphertext substitution won't be detected in unauthenticated ciphers
- Don't re-use keys between different protocols
- For example, using secp256k1 key in AES is bad
- Use hkdf or, at least, a hash function to create sub-key instead
### Nonces
Most ciphers need a key and a nonce (aka initialization vector / IV) to encrypt a data:
ciphertext = encrypt(plaintext, key, nonce)
Repeating (key, nonce) pair with different plaintexts would allow an attacker to decrypt it:
ciphertext_a = encrypt(plaintext_a, key, nonce)
ciphertext_b = encrypt(plaintext_b, key, nonce)
stream_diff = xor(ciphertext_a, ciphertext_b) # Break encryption
So, you can't repeat nonces. One way of doing so is using counters:
for i in 0..:
ciphertext[i] = encrypt(plaintexts[i], key, i)
Another is generating random nonce every time:
for i in 0..:
rand_nonces[i] = random()
ciphertext[i] = encrypt(plaintexts[i], key, rand_nonces[i])
Counters are OK, but it's not always possible to store current counter value:
e.g. in decentralized, unsyncable systems.
Randomness is OK, but there's a catch:
ChaCha20 and AES-GCM use 96-bit / 12-byte nonces, which implies
higher chance of collision. In the example above,
`random()` can collide and produce repeating nonce.
To safely use random nonces, utilize XSalsa20 or XChaCha:
they increased nonce length to 192-bit, minimizing a chance of collision.
AES-SIV is also fine. In situations where you can't use eXtended-nonce
algorithms, key rotation is advised. hkdf would work great for this case.
### Encryption limits
A "protected message" would mean a probability of `2**-50` that a passive attacker
successfully distinguishes the ciphertext outputs of the AEAD scheme from the outputs
of a random function. See [draft-irtf-cfrg-aead-limits](https://datatracker.ietf.org/doc/draft-irtf-cfrg-aead-limits/) for details.
- Max message size:
- AES-GCM: ~68GB, `2**36-256`
- Salsa, ChaCha, XSalsa, XChaCha: ~256GB, `2**38-64`
- Max amount of protected messages, under same key:
- AES-GCM: `2**32.5`
- Salsa, ChaCha: `2**46`, but only integrity is affected, not confidentiality
- XSalsa, XChaCha: `2**72`
- Max amount of protected messages, across all keys:
- AES-GCM: `2**69/B` where B is max blocks encrypted by a key. Meaning
`2**59` for 1KB, `2**49` for 1MB, `2**39` for 1GB
- Salsa, ChaCha, XSalsa, XChaCha: `2**100`
##### AES internals and block modes
`cipher = encrypt(block, key)`. Data is split into 128-bit blocks. Encrypted in 10/12/14 rounds (128/192/256bit). Every round does:
1. **S-box**, table substitution
2. **Shift rows**, cyclic shift left of all rows of data array
3. **Mix columns**, multiplying every column by fixed polynomial
4. **Add round key**, round_key xor i-th column of array
For non-deterministic (not ECB) schemes, initialization vector (IV) is mixed to block/key;
and each new round either depends on previous block's key, or on some counter.
- ECB — simple deterministic replacement. Dangerous: always map x to y. See [AES Penguin](https://words.filippo.io/the-ecb-penguin/)
- CBC — key is previous rounds block. Hard to use: need proper padding, also needs MAC
- CTR — counter, allows to create streaming cipher. Requires good IV. Parallelizable. OK, but no MAC
- GCM — modern CTR, parallel, with MAC
- SIV — synthetic initialization vector, nonce-misuse-resistant. Guarantees that, when a nonce is repeated,
the only security loss is that identical plaintexts will produce identical ciphertexts.
- XTS — used in hard drives. Similar to ECB (deterministic), but has `[i][j]`
tweak arguments corresponding to sector i and 16-byte block (part of sector) j. Not authenticated!
GCM / SIV are not ideal:
- Conservative key wear-out is `2**32` (4B) msgs
- MAC can be forged: see Poly1305 section above. Same for SIV
## Security
The library has not been independently audited yet.
It is tested against property-based, cross-library and Wycheproof vectors,
and has fuzzing by [Guido Vranken's cryptofuzz](https://github.com/guidovranken/cryptofuzz).
If you see anything unusual: investigate and report.
### Constant-timeness
_JIT-compiler_ and _Garbage Collector_ make "constant time" extremely hard to
achieve [timing attack](https://en.wikipedia.org/wiki/Timing_attack) resistance
in a scripting language. Which means _any other JS library can't have
constant-timeness_. Even statically typed Rust, a language without GC,
[makes it harder to achieve constant-time](https://www.chosenplaintext.ca/open-source/rust-timing-shield/security)
for some cases. If your goal is absolute security, don't use any JS lib — including bindings to native ones.
Use low-level libraries & languages. Nonetheless we're targetting algorithmic constant time.
AES uses T-tables, which means it can't be done in constant-time in JS.
### Supply chain security
- **Commits** are signed with PGP keys, to prevent forgery. Make sure to verify commit signatures.
- **Releases** are transparent and built on GitHub CI. Make sure to verify [provenance](https://docs.npmjs.com/generating-provenance-statements) logs
- **Rare releasing** is followed to ensure less re-audit need for end-users
- **Dependencies** are minimized and locked-down:
- If your app has 500 dependencies, any dep could get hacked and you'll be downloading
malware with every install. We make sure to use as few dependencies as possible
- We prevent automatic dependency updates by locking-down version ranges. Every update is checked with `npm-diff`
- **Dev Dependencies** are only used if you want to contribute to the repo. They are disabled for end-users:
- scure-base, micro-bmark and micro-should are developed by the same author and follow identical security practices
- prettier (linter), fast-check (property-based testing) and typescript are used for code quality, vector generation and ts compilation. The packages are big, which makes it hard to audit their source code thoroughly and fully
### Randomness
We're deferring to built-in
[crypto.getRandomValues](https://developer.mozilla.org/en-US/docs/Web/API/Crypto/getRandomValues)
which is considered cryptographically secure (CSPRNG).
In the past, browsers had bugs that made it weak: it may happen again.
Implementing a userspace CSPRNG to get resilient to the weakness
is even worse: there is no reliable userspace source of quality entropy.
## Speed
To summarize, noble is the fastest JS implementation of Salsa, ChaCha and AES.
You can gain additional speed-up and
avoid memory allocations by passing `output`
uint8array into encrypt / decrypt methods.
Benchmark results on Apple M2 with node v20:
```
encrypt (64B)
├─xsalsa20poly1305 x 485,672 ops/sec @ 2μs/op
├─chacha20poly1305 x 466,200 ops/sec @ 2μs/op
├─xchacha20poly1305 x 312,500 ops/sec @ 3μs/op
├─aes-256-gcm x 151,057 ops/sec @ 6μs/op
└─aes-256-gcm-siv x 124,984 ops/sec @ 8μs/op
encrypt (1KB)
├─xsalsa20poly1305 x 146,477 ops/sec @ 6μs/op
├─chacha20poly1305 x 145,518 ops/sec @ 6μs/op
├─xchacha20poly1305 x 126,119 ops/sec @ 7μs/op
├─aes-256-gcm x 43,207 ops/sec @ 23μs/op
└─aes-256-gcm-siv x 39,363 ops/sec @ 25μs/op
encrypt (8KB)
├─xsalsa20poly1305 x 23,773 ops/sec @ 42μs/op
├─chacha20poly1305 x 24,134 ops/sec @ 41μs/op
├─xchacha20poly1305 x 23,520 ops/sec @ 42μs/op
├─aes-256-gcm x 8,420 ops/sec @ 118μs/op
└─aes-256-gcm-siv x 8,126 ops/sec @ 123μs/op
encrypt (1MB)
├─xsalsa20poly1305 x 195 ops/sec @ 5ms/op
├─chacha20poly1305 x 199 ops/sec @ 5ms/op
├─xchacha20poly1305 x 198 ops/sec @ 5ms/op
├─aes-256-gcm x 76 ops/sec @ 13ms/op
└─aes-256-gcm-siv x 78 ops/sec @ 12ms/op
```
Unauthenticated encryption:
```
encrypt (64B)
├─salsa x 1,287,001 ops/sec @ 777ns/op
├─chacha x 1,555,209 ops/sec @ 643ns/op
├─xsalsa x 938,086 ops/sec @ 1μs/op
└─xchacha x 920,810 ops/sec @ 1μs/op
encrypt (1KB)
├─salsa x 353,107 ops/sec @ 2μs/op
├─chacha x 377,216 ops/sec @ 2μs/op
├─xsalsa x 331,674 ops/sec @ 3μs/op
└─xchacha x 336,247 ops/sec @ 2μs/op
encrypt (8KB)
├─salsa x 57,084 ops/sec @ 17μs/op
├─chacha x 59,520 ops/sec @ 16μs/op
├─xsalsa x 57,097 ops/sec @ 17μs/op
└─xchacha x 58,278 ops/sec @ 17μs/op
encrypt (1MB)
├─salsa x 479 ops/sec @ 2ms/op
├─chacha x 491 ops/sec @ 2ms/op
├─xsalsa x 483 ops/sec @ 2ms/op
└─xchacha x 492 ops/sec @ 2ms/op
AES
encrypt (64B)
├─ctr-256 x 689,179 ops/sec @ 1μs/op
├─cbc-256 x 639,795 ops/sec @ 1μs/op
└─ecb-256 x 668,449 ops/sec @ 1μs/op
encrypt (1KB)
├─ctr-256 x 93,668 ops/sec @ 10μs/op
├─cbc-256 x 94,428 ops/sec @ 10μs/op
└─ecb-256 x 151,699 ops/sec @ 6μs/op
encrypt (8KB)
├─ctr-256 x 13,342 ops/sec @ 74μs/op
├─cbc-256 x 13,664 ops/sec @ 73μs/op
└─ecb-256 x 22,426 ops/sec @ 44μs/op
encrypt (1MB)
├─ctr-256 x 106 ops/sec @ 9ms/op
├─cbc-256 x 109 ops/sec @ 9ms/op
└─ecb-256 x 179 ops/sec @ 5ms/op
```
Compare to other implementations:
```
xsalsa20poly1305 (encrypt, 1MB)
├─tweetnacl x 108 ops/sec @ 9ms/op
└─noble x 190 ops/sec @ 5ms/op
chacha20poly1305 (encrypt, 1MB)
├─node x 1,360 ops/sec @ 735μs/op
├─stablelib x 117 ops/sec @ 8ms/op
└─noble x 193 ops/sec @ 5ms/op
chacha (encrypt, 1MB)
├─node x 2,035 ops/sec @ 491μs/op
├─stablelib x 206 ops/sec @ 4ms/op
└─noble x 474 ops/sec @ 2ms/op
ctr-256 (encrypt, 1MB)
├─node x 3,530 ops/sec @ 283μs/op
├─stablelib x 70 ops/sec @ 14ms/op
├─aesjs x 31 ops/sec @ 32ms/op
├─noble-webcrypto x 4,589 ops/sec @ 217μs/op
└─noble x 107 ops/sec @ 9ms/op
cbc-256 (encrypt, 1MB)
├─node x 993 ops/sec @ 1ms/op
├─stablelib x 63 ops/sec @ 15ms/op
├─aesjs x 29 ops/sec @ 34ms/op
├─noble-webcrypto x 1,087 ops/sec @ 919μs/op
└─noble x 110 ops/sec @ 9ms/op
gcm-256 (encrypt, 1MB)
├─node x 3,196 ops/sec @ 312μs/op
├─stablelib x 27 ops/sec @ 36ms/op
├─noble-webcrypto x 4,059 ops/sec @ 246μs/op
└─noble x 74 ops/sec @ 13ms/op
```
## Upgrading
Upgrade from `micro-aes-gcm` package is simple:
```js
// prepare
const key = Uint8Array.from([
64, 196, 127, 247, 172, 2, 34, 159, 6, 241, 30, 174, 183, 229, 41, 114, 253, 122, 119, 168, 177,
243, 155, 236, 164, 159, 98, 72, 162, 243, 224, 195,
]);
const message = 'Hello world';
// previous
import * as aes from 'micro-aes-gcm';
const ciphertext = await aes.encrypt(key, aes.utils.utf8ToBytes(message));
const plaintext = await aes.decrypt(key, ciphertext);
console.log(aes.utils.bytesToUtf8(plaintext) === message);
// became =>
import { gcm } from '@noble/ciphers/aes';
import { bytesToUtf8, utf8ToBytes } from '@noble/ciphers/utils';
import { managedNonce } from '@noble/ciphers/webcrypto';
const aes = managedNonce(gcm)(key);
const ciphertext = aes.encrypt(utf8ToBytes(message));
const plaintext = aes.decrypt(key, ciphertext);
console.log(bytesToUtf8(plaintext) === message);
```
## Contributing & testing
1. Clone the repository
2. `npm install` to install build dependencies like TypeScript
3. `npm run build` to compile TypeScript code
4. `npm run test` will execute all main tests
## Resources
Check out [paulmillr.com/noble](https://paulmillr.com/noble/)
for useful resources, articles, documentation and demos
related to the library.
## License
The MIT License (MIT)
Copyright (c) 2023 Paul Miller [(https://paulmillr.com)](https://paulmillr.com)
Copyright (c) 2016 Thomas Pornin <pornin@bolet.org>
See LICENSE file.

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import { XorStream } from './utils.js';
export declare const sigma: Uint32Array;
export declare function rotl(a: number, b: number): number;
export type CipherCoreFn = (sigma: Uint32Array, key: Uint32Array, nonce: Uint32Array, output: Uint32Array, counter: number, rounds?: number) => void;
export type ExtendNonceFn = (sigma: Uint32Array, key: Uint32Array, input: Uint32Array, output: Uint32Array) => void;
export type CipherOpts = {
allowShortKeys?: boolean;
extendNonceFn?: ExtendNonceFn;
counterLength?: number;
counterRight?: boolean;
rounds?: number;
};
export declare function createCipher(core: CipherCoreFn, opts: CipherOpts): XorStream;
//# sourceMappingURL=_arx.d.ts.map

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@@ -0,0 +1 @@
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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.createCipher = exports.rotl = exports.sigma = void 0;
// Basic utils for ARX (add-rotate-xor) salsa and chacha ciphers.
const _assert_js_1 = require("./_assert.js");
const utils_js_1 = require("./utils.js");
/*
RFC8439 requires multi-step cipher stream, where
authKey starts with counter: 0, actual msg with counter: 1.
For this, we need a way to re-use nonce / counter:
const counter = new Uint8Array(4);
chacha(..., counter, ...); // counter is now 1
chacha(..., counter, ...); // counter is now 2
This is complicated:
- 32-bit counters are enough, no need for 64-bit: max ArrayBuffer size in JS is 4GB
- Original papers don't allow mutating counters
- Counter overflow is undefined [^1]
- Idea A: allow providing (nonce | counter) instead of just nonce, re-use it
- Caveat: Cannot be re-used through all cases:
- * chacha has (counter | nonce)
- * xchacha has (nonce16 | counter | nonce16)
- Idea B: separate nonce / counter and provide separate API for counter re-use
- Caveat: there are different counter sizes depending on an algorithm.
- salsa & chacha also differ in structures of key & sigma:
salsa20: s[0] | k(4) | s[1] | nonce(2) | ctr(2) | s[2] | k(4) | s[3]
chacha: s(4) | k(8) | ctr(1) | nonce(3)
chacha20orig: s(4) | k(8) | ctr(2) | nonce(2)
- Idea C: helper method such as `setSalsaState(key, nonce, sigma, data)`
- Caveat: we can't re-use counter array
xchacha [^2] uses the subkey and remaining 8 byte nonce with ChaCha20 as normal
(prefixed by 4 NUL bytes, since [RFC8439] specifies a 12-byte nonce).
[^1]: https://mailarchive.ietf.org/arch/msg/cfrg/gsOnTJzcbgG6OqD8Sc0GO5aR_tU/
[^2]: https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha#appendix-A.2
*/
// We can't make top-level var depend on utils.utf8ToBytes
// because it's not present in all envs. Creating a similar fn here
const _utf8ToBytes = (str) => Uint8Array.from(str.split('').map((c) => c.charCodeAt(0)));
const sigma16 = _utf8ToBytes('expand 16-byte k');
const sigma32 = _utf8ToBytes('expand 32-byte k');
const sigma16_32 = (0, utils_js_1.u32)(sigma16);
const sigma32_32 = (0, utils_js_1.u32)(sigma32);
exports.sigma = sigma32_32.slice();
function rotl(a, b) {
return (a << b) | (a >>> (32 - b));
}
exports.rotl = rotl;
// Is byte array aligned to 4 byte offset (u32)?
function isAligned32(b) {
return b.byteOffset % 4 === 0;
}
// Salsa and Chacha block length is always 512-bit
const BLOCK_LEN = 64;
const BLOCK_LEN32 = 16;
// new Uint32Array([2**32]) // => Uint32Array(1) [ 0 ]
// new Uint32Array([2**32-1]) // => Uint32Array(1) [ 4294967295 ]
const MAX_COUNTER = 2 ** 32 - 1;
const U32_EMPTY = new Uint32Array();
function runCipher(core, sigma, key, nonce, data, output, counter, rounds) {
const len = data.length;
const block = new Uint8Array(BLOCK_LEN);
const b32 = (0, utils_js_1.u32)(block);
// Make sure that buffers aligned to 4 bytes
const isAligned = isAligned32(data) && isAligned32(output);
const d32 = isAligned ? (0, utils_js_1.u32)(data) : U32_EMPTY;
const o32 = isAligned ? (0, utils_js_1.u32)(output) : U32_EMPTY;
for (let pos = 0; pos < len; counter++) {
core(sigma, key, nonce, b32, counter, rounds);
if (counter >= MAX_COUNTER)
throw new Error('arx: counter overflow');
const take = Math.min(BLOCK_LEN, len - pos);
// aligned to 4 bytes
if (isAligned && take === BLOCK_LEN) {
const pos32 = pos / 4;
if (pos % 4 !== 0)
throw new Error('arx: invalid block position');
for (let j = 0, posj; j < BLOCK_LEN32; j++) {
posj = pos32 + j;
o32[posj] = d32[posj] ^ b32[j];
}
pos += BLOCK_LEN;
continue;
}
for (let j = 0, posj; j < take; j++) {
posj = pos + j;
output[posj] = data[posj] ^ block[j];
}
pos += take;
}
}
function createCipher(core, opts) {
const { allowShortKeys, extendNonceFn, counterLength, counterRight, rounds } = (0, utils_js_1.checkOpts)({ allowShortKeys: false, counterLength: 8, counterRight: false, rounds: 20 }, opts);
if (typeof core !== 'function')
throw new Error('core must be a function');
(0, _assert_js_1.number)(counterLength);
(0, _assert_js_1.number)(rounds);
(0, _assert_js_1.bool)(counterRight);
(0, _assert_js_1.bool)(allowShortKeys);
return (key, nonce, data, output, counter = 0) => {
(0, _assert_js_1.bytes)(key);
(0, _assert_js_1.bytes)(nonce);
(0, _assert_js_1.bytes)(data);
const len = data.length;
if (!output)
output = new Uint8Array(len);
(0, _assert_js_1.bytes)(output);
(0, _assert_js_1.number)(counter);
if (counter < 0 || counter >= MAX_COUNTER)
throw new Error('arx: counter overflow');
if (output.length < len)
throw new Error(`arx: output (${output.length}) is shorter than data (${len})`);
const toClean = [];
// Key & sigma
// key=16 -> sigma16, k=key|key
// key=32 -> sigma32, k=key
let l = key.length, k, sigma;
if (l === 32) {
k = key.slice();
toClean.push(k);
sigma = sigma32_32;
}
else if (l === 16 && allowShortKeys) {
k = new Uint8Array(32);
k.set(key);
k.set(key, 16);
sigma = sigma16_32;
toClean.push(k);
}
else {
throw new Error(`arx: invalid 32-byte key, got length=${l}`);
}
// Nonce
// salsa20: 8 (8-byte counter)
// chacha20orig: 8 (8-byte counter)
// chacha20: 12 (4-byte counter)
// xsalsa20: 24 (16 -> hsalsa, 8 -> old nonce)
// xchacha20: 24 (16 -> hchacha, 8 -> old nonce)
// Align nonce to 4 bytes
if (!isAligned32(nonce)) {
nonce = nonce.slice();
toClean.push(nonce);
}
const k32 = (0, utils_js_1.u32)(k);
// hsalsa & hchacha: handle extended nonce
if (extendNonceFn) {
if (nonce.length !== 24)
throw new Error(`arx: extended nonce must be 24 bytes`);
extendNonceFn(sigma, k32, (0, utils_js_1.u32)(nonce.subarray(0, 16)), k32);
nonce = nonce.subarray(16);
}
// Handle nonce counter
const nonceNcLen = 16 - counterLength;
if (nonceNcLen !== nonce.length)
throw new Error(`arx: nonce must be ${nonceNcLen} or 16 bytes`);
// Pad counter when nonce is 64 bit
if (nonceNcLen !== 12) {
const nc = new Uint8Array(12);
nc.set(nonce, counterRight ? 0 : 12 - nonce.length);
nonce = nc;
toClean.push(nonce);
}
const n32 = (0, utils_js_1.u32)(nonce);
runCipher(core, sigma, k32, n32, data, output, counter, rounds);
while (toClean.length > 0)
toClean.pop().fill(0);
return output;
};
}
exports.createCipher = createCipher;
//# sourceMappingURL=_arx.js.map

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declare function number(n: number): void;
declare function bool(b: boolean): void;
export declare function isBytes(a: unknown): a is Uint8Array;
declare function bytes(b: Uint8Array | undefined, ...lengths: number[]): void;
export type Hash = {
(data: Uint8Array): Uint8Array;
blockLen: number;
outputLen: number;
create: any;
};
declare function hash(hash: Hash): void;
declare function exists(instance: any, checkFinished?: boolean): void;
declare function output(out: any, instance: any): void;
export { number, bool, bytes, hash, exists, output };
declare const assert: {
number: typeof number;
bool: typeof bool;
bytes: typeof bytes;
hash: typeof hash;
exists: typeof exists;
output: typeof output;
};
export default assert;
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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.output = exports.exists = exports.hash = exports.bytes = exports.bool = exports.number = exports.isBytes = void 0;
function number(n) {
if (!Number.isSafeInteger(n) || n < 0)
throw new Error(`positive integer expected, not ${n}`);
}
exports.number = number;
function bool(b) {
if (typeof b !== 'boolean')
throw new Error(`boolean expected, not ${b}`);
}
exports.bool = bool;
function isBytes(a) {
return (a instanceof Uint8Array ||
(a != null && typeof a === 'object' && a.constructor.name === 'Uint8Array'));
}
exports.isBytes = isBytes;
function bytes(b, ...lengths) {
if (!isBytes(b))
throw new Error('Uint8Array expected');
if (lengths.length > 0 && !lengths.includes(b.length))
throw new Error(`Uint8Array expected of length ${lengths}, not of length=${b.length}`);
}
exports.bytes = bytes;
function hash(hash) {
if (typeof hash !== 'function' || typeof hash.create !== 'function')
throw new Error('hash must be wrapped by utils.wrapConstructor');
number(hash.outputLen);
number(hash.blockLen);
}
exports.hash = hash;
function exists(instance, checkFinished = true) {
if (instance.destroyed)
throw new Error('Hash instance has been destroyed');
if (checkFinished && instance.finished)
throw new Error('Hash#digest() has already been called');
}
exports.exists = exists;
function output(out, instance) {
bytes(out);
const min = instance.outputLen;
if (out.length < min) {
throw new Error(`digestInto() expects output buffer of length at least ${min}`);
}
}
exports.output = output;
const assert = { number, bool, bytes, hash, exists, output };
exports.default = assert;
//# sourceMappingURL=_assert.js.map

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/*! noble-ciphers - MIT License (c) 2023 Paul Miller (paulmillr.com) */
import { Cipher, XorStream } from './utils.js';
export declare function hsalsa(s: Uint32Array, k: Uint32Array, i: Uint32Array, o32: Uint32Array): void;
export declare function hchacha(s: Uint32Array, k: Uint32Array, i: Uint32Array, o32: Uint32Array): void;
/**
* salsa20, 12-byte nonce.
*/
export declare const salsa20: XorStream;
/**
* xsalsa20, 24-byte nonce.
*/
export declare const xsalsa20: XorStream;
/**
* chacha20 non-RFC, original version by djb. 8-byte nonce, 8-byte counter.
*/
export declare const chacha20orig: XorStream;
/**
* chacha20 RFC 8439 (IETF / TLS). 12-byte nonce, 4-byte counter.
*/
export declare const chacha20: XorStream;
/**
* xchacha20 eXtended-nonce. https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha
*/
export declare const xchacha20: XorStream;
/**
* 8-round chacha from the original paper.
*/
export declare const chacha8: XorStream;
/**
* 12-round chacha from the original paper.
*/
export declare const chacha12: XorStream;
export declare function poly1305(msg: Uint8Array, key: Uint8Array): Uint8Array;
/**
* xsalsa20-poly1305 eXtended-nonce (24 bytes) salsa.
*/
export declare const xsalsa20poly1305: ((key: Uint8Array, nonce: Uint8Array) => {
encrypt: (plaintext: Uint8Array) => Uint8Array;
decrypt: (ciphertext: Uint8Array) => Uint8Array;
}) & {
blockSize: number;
nonceLength: number;
tagLength: number;
};
/**
* Alias to xsalsa20-poly1305
*/
export declare function secretbox(key: Uint8Array, nonce: Uint8Array): {
seal: (plaintext: Uint8Array) => Uint8Array;
open: (ciphertext: Uint8Array) => Uint8Array;
};
export declare const _poly1305_aead: (fn: XorStream) => (key: Uint8Array, nonce: Uint8Array, AAD?: Uint8Array) => Cipher;
/**
* chacha20-poly1305 12-byte-nonce chacha.
*/
export declare const chacha20poly1305: ((key: Uint8Array, nonce: Uint8Array, AAD?: Uint8Array) => Cipher) & {
blockSize: number;
nonceLength: number;
tagLength: number;
};
/**
* xchacha20-poly1305 eXtended-nonce (24 bytes) chacha.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
*/
export declare const xchacha20poly1305: ((key: Uint8Array, nonce: Uint8Array, AAD?: Uint8Array) => Cipher) & {
blockSize: number;
nonceLength: number;
tagLength: number;
};
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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.xchacha20poly1305 = exports.chacha20poly1305 = exports._poly1305_aead = exports.secretbox = exports.xsalsa20poly1305 = exports.poly1305 = exports.chacha12 = exports.chacha8 = exports.xchacha20 = exports.chacha20 = exports.chacha20orig = exports.xsalsa20 = exports.salsa20 = exports.hchacha = exports.hsalsa = void 0;
/*! noble-ciphers - MIT License (c) 2023 Paul Miller (paulmillr.com) */
// prettier-ignore
const utils_js_1 = require("./utils.js");
const _arx_js_1 = require("./_arx.js");
const _assert_js_1 = require("./_assert.js");
/*
noble-ciphers-micro: more auditable, but slower version of salsa20, chacha & poly1305.
Implements the same algorithms that are present in other files, but without
unrolled loops (https://en.wikipedia.org/wiki/Loop_unrolling).
*/
function bytesToNumberLE(bytes) {
return (0, utils_js_1.hexToNumber)((0, utils_js_1.bytesToHex)(Uint8Array.from(bytes).reverse()));
}
function numberToBytesLE(n, len) {
return (0, utils_js_1.numberToBytesBE)(n, len).reverse();
}
function salsaQR(x, a, b, c, d) {
x[b] ^= (0, _arx_js_1.rotl)((x[a] + x[d]) | 0, 7);
x[c] ^= (0, _arx_js_1.rotl)((x[b] + x[a]) | 0, 9);
x[d] ^= (0, _arx_js_1.rotl)((x[c] + x[b]) | 0, 13);
x[a] ^= (0, _arx_js_1.rotl)((x[d] + x[c]) | 0, 18);
}
// prettier-ignore
function chachaQR(x, a, b, c, d) {
x[a] = (x[a] + x[b]) | 0;
x[d] = (0, _arx_js_1.rotl)(x[d] ^ x[a], 16);
x[c] = (x[c] + x[d]) | 0;
x[b] = (0, _arx_js_1.rotl)(x[b] ^ x[c], 12);
x[a] = (x[a] + x[b]) | 0;
x[d] = (0, _arx_js_1.rotl)(x[d] ^ x[a], 8);
x[c] = (x[c] + x[d]) | 0;
x[b] = (0, _arx_js_1.rotl)(x[b] ^ x[c], 7);
}
function salsaRound(x, rounds = 20) {
for (let r = 0; r < rounds; r += 2) {
salsaQR(x, 0, 4, 8, 12);
salsaQR(x, 5, 9, 13, 1);
salsaQR(x, 10, 14, 2, 6);
salsaQR(x, 15, 3, 7, 11);
salsaQR(x, 0, 1, 2, 3);
salsaQR(x, 5, 6, 7, 4);
salsaQR(x, 10, 11, 8, 9);
salsaQR(x, 15, 12, 13, 14);
}
}
function chachaRound(x, rounds = 20) {
for (let r = 0; r < rounds; r += 2) {
chachaQR(x, 0, 4, 8, 12);
chachaQR(x, 1, 5, 9, 13);
chachaQR(x, 2, 6, 10, 14);
chachaQR(x, 3, 7, 11, 15);
chachaQR(x, 0, 5, 10, 15);
chachaQR(x, 1, 6, 11, 12);
chachaQR(x, 2, 7, 8, 13);
chachaQR(x, 3, 4, 9, 14);
}
}
function salsaCore(s, k, n, out, cnt, rounds = 20) {
// prettier-ignore
const y = new Uint32Array([
s[0], k[0], k[1], k[2], // "expa" Key Key Key
k[3], s[1], n[0], n[1], // Key "nd 3" Nonce Nonce
cnt, 0, s[2], k[4], // Pos. Pos. "2-by" Key
k[5], k[6], k[7], s[3], // Key Key Key "te k"
]);
const x = y.slice();
salsaRound(x, rounds);
for (let i = 0; i < 16; i++)
out[i] = (y[i] + x[i]) | 0;
}
// prettier-ignore
function hsalsa(s, k, i, o32) {
const x = new Uint32Array([
s[0], k[0], k[1], k[2],
k[3], s[1], i[0], i[1],
i[2], i[3], s[2], k[4],
k[5], k[6], k[7], s[3]
]);
salsaRound(x, 20);
let oi = 0;
o32[oi++] = x[0];
o32[oi++] = x[5];
o32[oi++] = x[10];
o32[oi++] = x[15];
o32[oi++] = x[6];
o32[oi++] = x[7];
o32[oi++] = x[8];
o32[oi++] = x[9];
}
exports.hsalsa = hsalsa;
function chachaCore(s, k, n, out, cnt, rounds = 20) {
// prettier-ignore
const y = new Uint32Array([
s[0], s[1], s[2], s[3], // "expa" "nd 3" "2-by" "te k"
k[0], k[1], k[2], k[3], // Key Key Key Key
k[4], k[5], k[6], k[7], // Key Key Key Key
cnt, n[0], n[1], n[2], // Counter Counter Nonce Nonce
]);
const x = y.slice();
chachaRound(x, rounds);
for (let i = 0; i < 16; i++)
out[i] = (y[i] + x[i]) | 0;
}
// prettier-ignore
function hchacha(s, k, i, o32) {
const x = new Uint32Array([
s[0], s[1], s[2], s[3],
k[0], k[1], k[2], k[3],
k[4], k[5], k[6], k[7],
i[0], i[1], i[2], i[3],
]);
chachaRound(x, 20);
let oi = 0;
o32[oi++] = x[0];
o32[oi++] = x[1];
o32[oi++] = x[2];
o32[oi++] = x[3];
o32[oi++] = x[12];
o32[oi++] = x[13];
o32[oi++] = x[14];
o32[oi++] = x[15];
}
exports.hchacha = hchacha;
/**
* salsa20, 12-byte nonce.
*/
exports.salsa20 = (0, _arx_js_1.createCipher)(salsaCore, {
allowShortKeys: true,
counterRight: true,
});
/**
* xsalsa20, 24-byte nonce.
*/
exports.xsalsa20 = (0, _arx_js_1.createCipher)(salsaCore, {
counterRight: true,
extendNonceFn: hsalsa,
});
/**
* chacha20 non-RFC, original version by djb. 8-byte nonce, 8-byte counter.
*/
exports.chacha20orig = (0, _arx_js_1.createCipher)(chachaCore, {
allowShortKeys: true,
counterRight: false,
counterLength: 8,
});
/**
* chacha20 RFC 8439 (IETF / TLS). 12-byte nonce, 4-byte counter.
*/
exports.chacha20 = (0, _arx_js_1.createCipher)(chachaCore, {
counterRight: false,
counterLength: 4,
});
/**
* xchacha20 eXtended-nonce. https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha
*/
exports.xchacha20 = (0, _arx_js_1.createCipher)(chachaCore, {
counterRight: false,
counterLength: 8,
extendNonceFn: hchacha,
});
/**
* 8-round chacha from the original paper.
*/
exports.chacha8 = (0, _arx_js_1.createCipher)(chachaCore, {
counterRight: false,
counterLength: 4,
rounds: 8,
});
/**
* 12-round chacha from the original paper.
*/
exports.chacha12 = (0, _arx_js_1.createCipher)(chachaCore, {
counterRight: false,
counterLength: 4,
rounds: 12,
});
const POW_2_130_5 = BigInt(2) ** BigInt(130) - BigInt(5);
const POW_2_128_1 = BigInt(2) ** BigInt(16 * 8) - BigInt(1);
const CLAMP_R = BigInt('0x0ffffffc0ffffffc0ffffffc0fffffff');
const _0 = BigInt(0);
const _1 = BigInt(1);
// Can be speed-up using BigUint64Array, but would be more complicated
function poly1305(msg, key) {
(0, _assert_js_1.bytes)(msg);
(0, _assert_js_1.bytes)(key);
let acc = _0;
const r = bytesToNumberLE(key.subarray(0, 16)) & CLAMP_R;
const s = bytesToNumberLE(key.subarray(16));
// Process by 16 byte chunks
for (let i = 0; i < msg.length; i += 16) {
const m = msg.subarray(i, i + 16);
const n = bytesToNumberLE(m) | (_1 << BigInt(8 * m.length));
acc = ((acc + n) * r) % POW_2_130_5;
}
const res = (acc + s) & POW_2_128_1;
return numberToBytesLE(res, 16);
}
exports.poly1305 = poly1305;
function computeTag(fn, key, nonce, ciphertext, AAD) {
const res = [];
if (AAD) {
res.push(AAD);
const leftover = AAD.length % 16;
if (leftover > 0)
res.push(new Uint8Array(16 - leftover));
}
res.push(ciphertext);
const leftover = ciphertext.length % 16;
if (leftover > 0)
res.push(new Uint8Array(16 - leftover));
// Lengths
const num = new Uint8Array(16);
const view = (0, utils_js_1.createView)(num);
(0, utils_js_1.setBigUint64)(view, 0, BigInt(AAD ? AAD.length : 0), true);
(0, utils_js_1.setBigUint64)(view, 8, BigInt(ciphertext.length), true);
res.push(num);
const authKey = fn(key, nonce, new Uint8Array(32));
return poly1305((0, utils_js_1.concatBytes)(...res), authKey);
}
/**
* xsalsa20-poly1305 eXtended-nonce (24 bytes) salsa.
*/
exports.xsalsa20poly1305 = (0, utils_js_1.wrapCipher)({ blockSize: 64, nonceLength: 24, tagLength: 16 }, function xsalsa20poly1305(key, nonce) {
(0, _assert_js_1.bytes)(key);
(0, _assert_js_1.bytes)(nonce);
return {
encrypt: (plaintext) => {
(0, _assert_js_1.bytes)(plaintext);
const m = (0, utils_js_1.concatBytes)(new Uint8Array(32), plaintext);
const c = (0, exports.xsalsa20)(key, nonce, m);
const authKey = c.subarray(0, 32);
const data = c.subarray(32);
const tag = poly1305(data, authKey);
return (0, utils_js_1.concatBytes)(tag, data);
},
decrypt: (ciphertext) => {
(0, _assert_js_1.bytes)(ciphertext);
if (ciphertext.length < 16)
throw new Error('encrypted data must be at least 16 bytes');
const c = (0, utils_js_1.concatBytes)(new Uint8Array(16), ciphertext);
const authKey = (0, exports.xsalsa20)(key, nonce, new Uint8Array(32));
const tag = poly1305(c.subarray(32), authKey);
if (!(0, utils_js_1.equalBytes)(c.subarray(16, 32), tag))
throw new Error('invalid poly1305 tag');
return (0, exports.xsalsa20)(key, nonce, c).subarray(32);
},
};
});
/**
* Alias to xsalsa20-poly1305
*/
function secretbox(key, nonce) {
const xs = (0, exports.xsalsa20poly1305)(key, nonce);
return { seal: xs.encrypt, open: xs.decrypt };
}
exports.secretbox = secretbox;
const _poly1305_aead = (fn) => (key, nonce, AAD) => {
const tagLength = 16;
const keyLength = 32;
(0, _assert_js_1.bytes)(key, keyLength);
(0, _assert_js_1.bytes)(nonce);
return {
encrypt: (plaintext) => {
(0, _assert_js_1.bytes)(plaintext);
const res = fn(key, nonce, plaintext, undefined, 1);
const tag = computeTag(fn, key, nonce, res, AAD);
return (0, utils_js_1.concatBytes)(res, tag);
},
decrypt: (ciphertext) => {
(0, _assert_js_1.bytes)(ciphertext);
if (ciphertext.length < tagLength)
throw new Error(`encrypted data must be at least ${tagLength} bytes`);
const passedTag = ciphertext.subarray(-tagLength);
const data = ciphertext.subarray(0, -tagLength);
const tag = computeTag(fn, key, nonce, data, AAD);
if (!(0, utils_js_1.equalBytes)(passedTag, tag))
throw new Error('invalid poly1305 tag');
return fn(key, nonce, data, undefined, 1);
},
};
};
exports._poly1305_aead = _poly1305_aead;
/**
* chacha20-poly1305 12-byte-nonce chacha.
*/
exports.chacha20poly1305 = (0, utils_js_1.wrapCipher)({ blockSize: 64, nonceLength: 12, tagLength: 16 }, (0, exports._poly1305_aead)(exports.chacha20));
/**
* xchacha20-poly1305 eXtended-nonce (24 bytes) chacha.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
*/
exports.xchacha20poly1305 = (0, utils_js_1.wrapCipher)({ blockSize: 64, nonceLength: 24, tagLength: 16 }, (0, exports._poly1305_aead)(exports.xchacha20));
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import { Input, Hash } from './utils.js';
export type CHash = ReturnType<typeof wrapConstructorWithKey>;
export declare function wrapConstructorWithKey<H extends Hash<H>>(hashCons: (key: Input) => Hash<H>): {
(msg: Input, key: Input): Uint8Array;
outputLen: number;
blockLen: number;
create(key: Input): Hash<H>;
};
export declare const poly1305: {
(msg: Input, key: Input): Uint8Array;
outputLen: number;
blockLen: number;
create(key: Input): Hash<Hash<unknown>>;
};
//# sourceMappingURL=_poly1305.d.ts.map

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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.poly1305 = exports.wrapConstructorWithKey = void 0;
const _assert_js_1 = require("./_assert.js");
const utils_js_1 = require("./utils.js");
// Poly1305 is a fast and parallel secret-key message-authentication code.
// https://cr.yp.to/mac.html, https://cr.yp.to/mac/poly1305-20050329.pdf
// https://datatracker.ietf.org/doc/html/rfc8439
// Based on Public Domain poly1305-donna https://github.com/floodyberry/poly1305-donna
const u8to16 = (a, i) => (a[i++] & 0xff) | ((a[i++] & 0xff) << 8);
class Poly1305 {
constructor(key) {
this.blockLen = 16;
this.outputLen = 16;
this.buffer = new Uint8Array(16);
this.r = new Uint16Array(10);
this.h = new Uint16Array(10);
this.pad = new Uint16Array(8);
this.pos = 0;
this.finished = false;
key = (0, utils_js_1.toBytes)(key);
(0, _assert_js_1.bytes)(key, 32);
const t0 = u8to16(key, 0);
const t1 = u8to16(key, 2);
const t2 = u8to16(key, 4);
const t3 = u8to16(key, 6);
const t4 = u8to16(key, 8);
const t5 = u8to16(key, 10);
const t6 = u8to16(key, 12);
const t7 = u8to16(key, 14);
// https://github.com/floodyberry/poly1305-donna/blob/e6ad6e091d30d7f4ec2d4f978be1fcfcbce72781/poly1305-donna-16.h#L47
this.r[0] = t0 & 0x1fff;
this.r[1] = ((t0 >>> 13) | (t1 << 3)) & 0x1fff;
this.r[2] = ((t1 >>> 10) | (t2 << 6)) & 0x1f03;
this.r[3] = ((t2 >>> 7) | (t3 << 9)) & 0x1fff;
this.r[4] = ((t3 >>> 4) | (t4 << 12)) & 0x00ff;
this.r[5] = (t4 >>> 1) & 0x1ffe;
this.r[6] = ((t4 >>> 14) | (t5 << 2)) & 0x1fff;
this.r[7] = ((t5 >>> 11) | (t6 << 5)) & 0x1f81;
this.r[8] = ((t6 >>> 8) | (t7 << 8)) & 0x1fff;
this.r[9] = (t7 >>> 5) & 0x007f;
for (let i = 0; i < 8; i++)
this.pad[i] = u8to16(key, 16 + 2 * i);
}
process(data, offset, isLast = false) {
const hibit = isLast ? 0 : 1 << 11;
const { h, r } = this;
const r0 = r[0];
const r1 = r[1];
const r2 = r[2];
const r3 = r[3];
const r4 = r[4];
const r5 = r[5];
const r6 = r[6];
const r7 = r[7];
const r8 = r[8];
const r9 = r[9];
const t0 = u8to16(data, offset + 0);
const t1 = u8to16(data, offset + 2);
const t2 = u8to16(data, offset + 4);
const t3 = u8to16(data, offset + 6);
const t4 = u8to16(data, offset + 8);
const t5 = u8to16(data, offset + 10);
const t6 = u8to16(data, offset + 12);
const t7 = u8to16(data, offset + 14);
let h0 = h[0] + (t0 & 0x1fff);
let h1 = h[1] + (((t0 >>> 13) | (t1 << 3)) & 0x1fff);
let h2 = h[2] + (((t1 >>> 10) | (t2 << 6)) & 0x1fff);
let h3 = h[3] + (((t2 >>> 7) | (t3 << 9)) & 0x1fff);
let h4 = h[4] + (((t3 >>> 4) | (t4 << 12)) & 0x1fff);
let h5 = h[5] + ((t4 >>> 1) & 0x1fff);
let h6 = h[6] + (((t4 >>> 14) | (t5 << 2)) & 0x1fff);
let h7 = h[7] + (((t5 >>> 11) | (t6 << 5)) & 0x1fff);
let h8 = h[8] + (((t6 >>> 8) | (t7 << 8)) & 0x1fff);
let h9 = h[9] + ((t7 >>> 5) | hibit);
let c = 0;
let d0 = c + h0 * r0 + h1 * (5 * r9) + h2 * (5 * r8) + h3 * (5 * r7) + h4 * (5 * r6);
c = d0 >>> 13;
d0 &= 0x1fff;
d0 += h5 * (5 * r5) + h6 * (5 * r4) + h7 * (5 * r3) + h8 * (5 * r2) + h9 * (5 * r1);
c += d0 >>> 13;
d0 &= 0x1fff;
let d1 = c + h0 * r1 + h1 * r0 + h2 * (5 * r9) + h3 * (5 * r8) + h4 * (5 * r7);
c = d1 >>> 13;
d1 &= 0x1fff;
d1 += h5 * (5 * r6) + h6 * (5 * r5) + h7 * (5 * r4) + h8 * (5 * r3) + h9 * (5 * r2);
c += d1 >>> 13;
d1 &= 0x1fff;
let d2 = c + h0 * r2 + h1 * r1 + h2 * r0 + h3 * (5 * r9) + h4 * (5 * r8);
c = d2 >>> 13;
d2 &= 0x1fff;
d2 += h5 * (5 * r7) + h6 * (5 * r6) + h7 * (5 * r5) + h8 * (5 * r4) + h9 * (5 * r3);
c += d2 >>> 13;
d2 &= 0x1fff;
let d3 = c + h0 * r3 + h1 * r2 + h2 * r1 + h3 * r0 + h4 * (5 * r9);
c = d3 >>> 13;
d3 &= 0x1fff;
d3 += h5 * (5 * r8) + h6 * (5 * r7) + h7 * (5 * r6) + h8 * (5 * r5) + h9 * (5 * r4);
c += d3 >>> 13;
d3 &= 0x1fff;
let d4 = c + h0 * r4 + h1 * r3 + h2 * r2 + h3 * r1 + h4 * r0;
c = d4 >>> 13;
d4 &= 0x1fff;
d4 += h5 * (5 * r9) + h6 * (5 * r8) + h7 * (5 * r7) + h8 * (5 * r6) + h9 * (5 * r5);
c += d4 >>> 13;
d4 &= 0x1fff;
let d5 = c + h0 * r5 + h1 * r4 + h2 * r3 + h3 * r2 + h4 * r1;
c = d5 >>> 13;
d5 &= 0x1fff;
d5 += h5 * r0 + h6 * (5 * r9) + h7 * (5 * r8) + h8 * (5 * r7) + h9 * (5 * r6);
c += d5 >>> 13;
d5 &= 0x1fff;
let d6 = c + h0 * r6 + h1 * r5 + h2 * r4 + h3 * r3 + h4 * r2;
c = d6 >>> 13;
d6 &= 0x1fff;
d6 += h5 * r1 + h6 * r0 + h7 * (5 * r9) + h8 * (5 * r8) + h9 * (5 * r7);
c += d6 >>> 13;
d6 &= 0x1fff;
let d7 = c + h0 * r7 + h1 * r6 + h2 * r5 + h3 * r4 + h4 * r3;
c = d7 >>> 13;
d7 &= 0x1fff;
d7 += h5 * r2 + h6 * r1 + h7 * r0 + h8 * (5 * r9) + h9 * (5 * r8);
c += d7 >>> 13;
d7 &= 0x1fff;
let d8 = c + h0 * r8 + h1 * r7 + h2 * r6 + h3 * r5 + h4 * r4;
c = d8 >>> 13;
d8 &= 0x1fff;
d8 += h5 * r3 + h6 * r2 + h7 * r1 + h8 * r0 + h9 * (5 * r9);
c += d8 >>> 13;
d8 &= 0x1fff;
let d9 = c + h0 * r9 + h1 * r8 + h2 * r7 + h3 * r6 + h4 * r5;
c = d9 >>> 13;
d9 &= 0x1fff;
d9 += h5 * r4 + h6 * r3 + h7 * r2 + h8 * r1 + h9 * r0;
c += d9 >>> 13;
d9 &= 0x1fff;
c = ((c << 2) + c) | 0;
c = (c + d0) | 0;
d0 = c & 0x1fff;
c = c >>> 13;
d1 += c;
h[0] = d0;
h[1] = d1;
h[2] = d2;
h[3] = d3;
h[4] = d4;
h[5] = d5;
h[6] = d6;
h[7] = d7;
h[8] = d8;
h[9] = d9;
}
finalize() {
const { h, pad } = this;
const g = new Uint16Array(10);
let c = h[1] >>> 13;
h[1] &= 0x1fff;
for (let i = 2; i < 10; i++) {
h[i] += c;
c = h[i] >>> 13;
h[i] &= 0x1fff;
}
h[0] += c * 5;
c = h[0] >>> 13;
h[0] &= 0x1fff;
h[1] += c;
c = h[1] >>> 13;
h[1] &= 0x1fff;
h[2] += c;
g[0] = h[0] + 5;
c = g[0] >>> 13;
g[0] &= 0x1fff;
for (let i = 1; i < 10; i++) {
g[i] = h[i] + c;
c = g[i] >>> 13;
g[i] &= 0x1fff;
}
g[9] -= 1 << 13;
let mask = (c ^ 1) - 1;
for (let i = 0; i < 10; i++)
g[i] &= mask;
mask = ~mask;
for (let i = 0; i < 10; i++)
h[i] = (h[i] & mask) | g[i];
h[0] = (h[0] | (h[1] << 13)) & 0xffff;
h[1] = ((h[1] >>> 3) | (h[2] << 10)) & 0xffff;
h[2] = ((h[2] >>> 6) | (h[3] << 7)) & 0xffff;
h[3] = ((h[3] >>> 9) | (h[4] << 4)) & 0xffff;
h[4] = ((h[4] >>> 12) | (h[5] << 1) | (h[6] << 14)) & 0xffff;
h[5] = ((h[6] >>> 2) | (h[7] << 11)) & 0xffff;
h[6] = ((h[7] >>> 5) | (h[8] << 8)) & 0xffff;
h[7] = ((h[8] >>> 8) | (h[9] << 5)) & 0xffff;
let f = h[0] + pad[0];
h[0] = f & 0xffff;
for (let i = 1; i < 8; i++) {
f = (((h[i] + pad[i]) | 0) + (f >>> 16)) | 0;
h[i] = f & 0xffff;
}
}
update(data) {
(0, _assert_js_1.exists)(this);
const { buffer, blockLen } = this;
data = (0, utils_js_1.toBytes)(data);
const len = data.length;
for (let pos = 0; pos < len;) {
const take = Math.min(blockLen - this.pos, len - pos);
// Fast path: we have at least one block in input
if (take === blockLen) {
for (; blockLen <= len - pos; pos += blockLen)
this.process(data, pos);
continue;
}
buffer.set(data.subarray(pos, pos + take), this.pos);
this.pos += take;
pos += take;
if (this.pos === blockLen) {
this.process(buffer, 0, false);
this.pos = 0;
}
}
return this;
}
destroy() {
this.h.fill(0);
this.r.fill(0);
this.buffer.fill(0);
this.pad.fill(0);
}
digestInto(out) {
(0, _assert_js_1.exists)(this);
(0, _assert_js_1.output)(out, this);
this.finished = true;
const { buffer, h } = this;
let { pos } = this;
if (pos) {
buffer[pos++] = 1;
// buffer.subarray(pos).fill(0);
for (; pos < 16; pos++)
buffer[pos] = 0;
this.process(buffer, 0, true);
}
this.finalize();
let opos = 0;
for (let i = 0; i < 8; i++) {
out[opos++] = h[i] >>> 0;
out[opos++] = h[i] >>> 8;
}
return out;
}
digest() {
const { buffer, outputLen } = this;
this.digestInto(buffer);
const res = buffer.slice(0, outputLen);
this.destroy();
return res;
}
}
function wrapConstructorWithKey(hashCons) {
const hashC = (msg, key) => hashCons(key).update((0, utils_js_1.toBytes)(msg)).digest();
const tmp = hashCons(new Uint8Array(32));
hashC.outputLen = tmp.outputLen;
hashC.blockLen = tmp.blockLen;
hashC.create = (key) => hashCons(key);
return hashC;
}
exports.wrapConstructorWithKey = wrapConstructorWithKey;
exports.poly1305 = wrapConstructorWithKey((key) => new Poly1305(key));
//# sourceMappingURL=_poly1305.js.map

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import { Input, Hash } from './utils.js';
/**
* `mulX_POLYVAL(ByteReverse(H))` from spec
* @param k mutated in place
*/
export declare function _toGHASHKey(k: Uint8Array): Uint8Array;
export type CHash = ReturnType<typeof wrapConstructorWithKey>;
declare function wrapConstructorWithKey<H extends Hash<H>>(hashCons: (key: Input, expectedLength?: number) => Hash<H>): {
(msg: Input, key: Input): Uint8Array;
outputLen: number;
blockLen: number;
create(key: Input, expectedLength?: number): Hash<H>;
};
export declare const ghash: {
(msg: Input, key: Input): Uint8Array;
outputLen: number;
blockLen: number;
create(key: Input, expectedLength?: number): Hash<Hash<unknown>>;
};
export declare const polyval: {
(msg: Input, key: Input): Uint8Array;
outputLen: number;
blockLen: number;
create(key: Input, expectedLength?: number): Hash<Hash<unknown>>;
};
export {};
//# sourceMappingURL=_polyval.d.ts.map

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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.polyval = exports.ghash = exports._toGHASHKey = void 0;
const utils_js_1 = require("./utils.js");
const _assert_js_1 = require("./_assert.js");
// GHash from AES-GCM and its little-endian "mirror image" Polyval from AES-SIV.
// Implemented in terms of GHash with conversion function for keys
// GCM GHASH from NIST SP800-38d, SIV from RFC 8452.
// https://nvlpubs.nist.gov/nistpubs/Legacy/SP/nistspecialpublication800-38d.pdf
// GHASH modulo: x^128 + x^7 + x^2 + x + 1
// POLYVAL modulo: x^128 + x^127 + x^126 + x^121 + 1
const BLOCK_SIZE = 16;
// TODO: rewrite
// temporary padding buffer
const ZEROS16 = /* @__PURE__ */ new Uint8Array(16);
const ZEROS32 = (0, utils_js_1.u32)(ZEROS16);
const POLY = 0xe1; // v = 2*v % POLY
// v = 2*v % POLY
// NOTE: because x + x = 0 (add/sub is same), mul2(x) != x+x
// We can multiply any number using montgomery ladder and this function (works as double, add is simple xor)
const mul2 = (s0, s1, s2, s3) => {
const hiBit = s3 & 1;
return {
s3: (s2 << 31) | (s3 >>> 1),
s2: (s1 << 31) | (s2 >>> 1),
s1: (s0 << 31) | (s1 >>> 1),
s0: (s0 >>> 1) ^ ((POLY << 24) & -(hiBit & 1)), // reduce % poly
};
};
const swapLE = (n) => (((n >>> 0) & 0xff) << 24) |
(((n >>> 8) & 0xff) << 16) |
(((n >>> 16) & 0xff) << 8) |
((n >>> 24) & 0xff) |
0;
/**
* `mulX_POLYVAL(ByteReverse(H))` from spec
* @param k mutated in place
*/
function _toGHASHKey(k) {
k.reverse();
const hiBit = k[15] & 1;
// k >>= 1
let carry = 0;
for (let i = 0; i < k.length; i++) {
const t = k[i];
k[i] = (t >>> 1) | carry;
carry = (t & 1) << 7;
}
k[0] ^= -hiBit & 0xe1; // if (hiBit) n ^= 0xe1000000000000000000000000000000;
return k;
}
exports._toGHASHKey = _toGHASHKey;
const estimateWindow = (bytes) => {
if (bytes > 64 * 1024)
return 8;
if (bytes > 1024)
return 4;
return 2;
};
class GHASH {
// We select bits per window adaptively based on expectedLength
constructor(key, expectedLength) {
this.blockLen = BLOCK_SIZE;
this.outputLen = BLOCK_SIZE;
this.s0 = 0;
this.s1 = 0;
this.s2 = 0;
this.s3 = 0;
this.finished = false;
key = (0, utils_js_1.toBytes)(key);
(0, _assert_js_1.bytes)(key, 16);
const kView = (0, utils_js_1.createView)(key);
let k0 = kView.getUint32(0, false);
let k1 = kView.getUint32(4, false);
let k2 = kView.getUint32(8, false);
let k3 = kView.getUint32(12, false);
// generate table of doubled keys (half of montgomery ladder)
const doubles = [];
for (let i = 0; i < 128; i++) {
doubles.push({ s0: swapLE(k0), s1: swapLE(k1), s2: swapLE(k2), s3: swapLE(k3) });
({ s0: k0, s1: k1, s2: k2, s3: k3 } = mul2(k0, k1, k2, k3));
}
const W = estimateWindow(expectedLength || 1024);
if (![1, 2, 4, 8].includes(W))
throw new Error(`ghash: wrong window size=${W}, should be 2, 4 or 8`);
this.W = W;
const bits = 128; // always 128 bits;
const windows = bits / W;
const windowSize = (this.windowSize = 2 ** W);
const items = [];
// Create precompute table for window of W bits
for (let w = 0; w < windows; w++) {
// truth table: 00, 01, 10, 11
for (let byte = 0; byte < windowSize; byte++) {
// prettier-ignore
let s0 = 0, s1 = 0, s2 = 0, s3 = 0;
for (let j = 0; j < W; j++) {
const bit = (byte >>> (W - j - 1)) & 1;
if (!bit)
continue;
const { s0: d0, s1: d1, s2: d2, s3: d3 } = doubles[W * w + j];
(s0 ^= d0), (s1 ^= d1), (s2 ^= d2), (s3 ^= d3);
}
items.push({ s0, s1, s2, s3 });
}
}
this.t = items;
}
_updateBlock(s0, s1, s2, s3) {
(s0 ^= this.s0), (s1 ^= this.s1), (s2 ^= this.s2), (s3 ^= this.s3);
const { W, t, windowSize } = this;
// prettier-ignore
let o0 = 0, o1 = 0, o2 = 0, o3 = 0;
const mask = (1 << W) - 1; // 2**W will kill performance.
let w = 0;
for (const num of [s0, s1, s2, s3]) {
for (let bytePos = 0; bytePos < 4; bytePos++) {
const byte = (num >>> (8 * bytePos)) & 0xff;
for (let bitPos = 8 / W - 1; bitPos >= 0; bitPos--) {
const bit = (byte >>> (W * bitPos)) & mask;
const { s0: e0, s1: e1, s2: e2, s3: e3 } = t[w * windowSize + bit];
(o0 ^= e0), (o1 ^= e1), (o2 ^= e2), (o3 ^= e3);
w += 1;
}
}
}
this.s0 = o0;
this.s1 = o1;
this.s2 = o2;
this.s3 = o3;
}
update(data) {
data = (0, utils_js_1.toBytes)(data);
(0, _assert_js_1.exists)(this);
const b32 = (0, utils_js_1.u32)(data);
const blocks = Math.floor(data.length / BLOCK_SIZE);
const left = data.length % BLOCK_SIZE;
for (let i = 0; i < blocks; i++) {
this._updateBlock(b32[i * 4 + 0], b32[i * 4 + 1], b32[i * 4 + 2], b32[i * 4 + 3]);
}
if (left) {
ZEROS16.set(data.subarray(blocks * BLOCK_SIZE));
this._updateBlock(ZEROS32[0], ZEROS32[1], ZEROS32[2], ZEROS32[3]);
ZEROS32.fill(0); // clean tmp buffer
}
return this;
}
destroy() {
const { t } = this;
// clean precompute table
for (const elm of t) {
(elm.s0 = 0), (elm.s1 = 0), (elm.s2 = 0), (elm.s3 = 0);
}
}
digestInto(out) {
(0, _assert_js_1.exists)(this);
(0, _assert_js_1.output)(out, this);
this.finished = true;
const { s0, s1, s2, s3 } = this;
const o32 = (0, utils_js_1.u32)(out);
o32[0] = s0;
o32[1] = s1;
o32[2] = s2;
o32[3] = s3;
return out;
}
digest() {
const res = new Uint8Array(BLOCK_SIZE);
this.digestInto(res);
this.destroy();
return res;
}
}
class Polyval extends GHASH {
constructor(key, expectedLength) {
key = (0, utils_js_1.toBytes)(key);
const ghKey = _toGHASHKey(key.slice());
super(ghKey, expectedLength);
ghKey.fill(0);
}
update(data) {
data = (0, utils_js_1.toBytes)(data);
(0, _assert_js_1.exists)(this);
const b32 = (0, utils_js_1.u32)(data);
const left = data.length % BLOCK_SIZE;
const blocks = Math.floor(data.length / BLOCK_SIZE);
for (let i = 0; i < blocks; i++) {
this._updateBlock(swapLE(b32[i * 4 + 3]), swapLE(b32[i * 4 + 2]), swapLE(b32[i * 4 + 1]), swapLE(b32[i * 4 + 0]));
}
if (left) {
ZEROS16.set(data.subarray(blocks * BLOCK_SIZE));
this._updateBlock(swapLE(ZEROS32[3]), swapLE(ZEROS32[2]), swapLE(ZEROS32[1]), swapLE(ZEROS32[0]));
ZEROS32.fill(0); // clean tmp buffer
}
return this;
}
digestInto(out) {
(0, _assert_js_1.exists)(this);
(0, _assert_js_1.output)(out, this);
this.finished = true;
// tmp ugly hack
const { s0, s1, s2, s3 } = this;
const o32 = (0, utils_js_1.u32)(out);
o32[0] = s0;
o32[1] = s1;
o32[2] = s2;
o32[3] = s3;
return out.reverse();
}
}
function wrapConstructorWithKey(hashCons) {
const hashC = (msg, key) => hashCons(key, msg.length).update((0, utils_js_1.toBytes)(msg)).digest();
const tmp = hashCons(new Uint8Array(16), 0);
hashC.outputLen = tmp.outputLen;
hashC.blockLen = tmp.blockLen;
hashC.create = (key, expectedLength) => hashCons(key, expectedLength);
return hashC;
}
exports.ghash = wrapConstructorWithKey((key, expectedLength) => new GHASH(key, expectedLength));
exports.polyval = wrapConstructorWithKey((key, expectedLength) => new Polyval(key, expectedLength));
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import { Cipher, CipherWithOutput } from './utils.js';
export declare function expandKeyLE(key: Uint8Array): Uint32Array;
export declare function expandKeyDecLE(key: Uint8Array): Uint32Array;
declare function encrypt(xk: Uint32Array, s0: number, s1: number, s2: number, s3: number): {
s0: number;
s1: number;
s2: number;
s3: number;
};
declare function decrypt(xk: Uint32Array, s0: number, s1: number, s2: number, s3: number): {
s0: number;
s1: number;
s2: number;
s3: number;
};
declare function ctrCounter(xk: Uint32Array, nonce: Uint8Array, src: Uint8Array, dst?: Uint8Array): Uint8Array;
declare function ctr32(xk: Uint32Array, isLE: boolean, nonce: Uint8Array, src: Uint8Array, dst?: Uint8Array): Uint8Array;
/**
* CTR: counter mode. Creates stream cipher.
* Requires good IV. Parallelizable. OK, but no MAC.
*/
export declare const ctr: ((key: Uint8Array, nonce: Uint8Array) => CipherWithOutput) & {
blockSize: number;
nonceLength: number;
};
export type BlockOpts = {
disablePadding?: boolean;
};
/**
* ECB: Electronic CodeBook. Simple deterministic replacement.
* Dangerous: always map x to y. See [AES Penguin](https://words.filippo.io/the-ecb-penguin/).
*/
export declare const ecb: ((key: Uint8Array, opts?: BlockOpts) => CipherWithOutput) & {
blockSize: number;
};
/**
* CBC: Cipher-Block-Chaining. Key is previous rounds block.
* Fragile: needs proper padding. Unauthenticated: needs MAC.
*/
export declare const cbc: ((key: Uint8Array, iv: Uint8Array, opts?: BlockOpts) => CipherWithOutput) & {
blockSize: number;
nonceLength: number;
};
/**
* CFB: Cipher Feedback Mode. The input for the block cipher is the previous cipher output.
* Unauthenticated: needs MAC.
*/
export declare const cfb: ((key: Uint8Array, iv: Uint8Array) => CipherWithOutput) & {
blockSize: number;
nonceLength: number;
};
/**
* GCM: Galois/Counter Mode.
* Good, modern version of CTR, parallel, with MAC.
* Be careful: MACs can be forged.
*/
export declare const gcm: ((key: Uint8Array, nonce: Uint8Array, AAD?: Uint8Array) => Cipher) & {
blockSize: number;
nonceLength: number;
tagLength: number;
};
/**
* AES-GCM-SIV: classic AES-GCM with nonce-misuse resistance.
* Guarantees that, when a nonce is repeated, the only security loss is that identical
* plaintexts will produce identical ciphertexts.
* RFC 8452, https://datatracker.ietf.org/doc/html/rfc8452
*/
export declare const siv: ((key: Uint8Array, nonce: Uint8Array, AAD?: Uint8Array) => Cipher) & {
blockSize: number;
nonceLength: number;
tagLength: number;
};
declare function encryptBlock(xk: Uint32Array, block: Uint8Array): Uint8Array;
declare function decryptBlock(xk: Uint32Array, block: Uint8Array): Uint8Array;
export declare const unsafe: {
expandKeyLE: typeof expandKeyLE;
expandKeyDecLE: typeof expandKeyDecLE;
encrypt: typeof encrypt;
decrypt: typeof decrypt;
encryptBlock: typeof encryptBlock;
decryptBlock: typeof decryptBlock;
ctrCounter: typeof ctrCounter;
ctr32: typeof ctr32;
};
export {};
//# sourceMappingURL=aes.d.ts.map

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node_modules/@noble/ciphers/aes.js generated vendored Normal file
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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.unsafe = exports.siv = exports.gcm = exports.cfb = exports.cbc = exports.ecb = exports.ctr = exports.expandKeyDecLE = exports.expandKeyLE = void 0;
// prettier-ignore
const utils_js_1 = require("./utils.js");
const _polyval_js_1 = require("./_polyval.js");
const _assert_js_1 = require("./_assert.js");
/*
AES (Advanced Encryption Standard) aka Rijndael block cipher.
Data is split into 128-bit blocks. Encrypted in 10/12/14 rounds (128/192/256 bits). In every round:
1. **S-box**, table substitution
2. **Shift rows**, cyclic shift left of all rows of data array
3. **Mix columns**, multiplying every column by fixed polynomial
4. **Add round key**, round_key xor i-th column of array
Resources:
- FIPS-197 https://csrc.nist.gov/files/pubs/fips/197/final/docs/fips-197.pdf
- Original proposal: https://csrc.nist.gov/csrc/media/projects/cryptographic-standards-and-guidelines/documents/aes-development/rijndael-ammended.pdf
*/
const BLOCK_SIZE = 16;
const BLOCK_SIZE32 = 4;
const EMPTY_BLOCK = new Uint8Array(BLOCK_SIZE);
const POLY = 0x11b; // 1 + x + x**3 + x**4 + x**8
// TODO: remove multiplication, binary ops only
function mul2(n) {
return (n << 1) ^ (POLY & -(n >> 7));
}
function mul(a, b) {
let res = 0;
for (; b > 0; b >>= 1) {
// Montgomery ladder
res ^= a & -(b & 1); // if (b&1) res ^=a (but const-time).
a = mul2(a); // a = 2*a
}
return res;
}
// AES S-box is generated using finite field inversion,
// an affine transform, and xor of a constant 0x63.
const sbox = /* @__PURE__ */ (() => {
let t = new Uint8Array(256);
for (let i = 0, x = 1; i < 256; i++, x ^= mul2(x))
t[i] = x;
const box = new Uint8Array(256);
box[0] = 0x63; // first elm
for (let i = 0; i < 255; i++) {
let x = t[255 - i];
x |= x << 8;
box[t[i]] = (x ^ (x >> 4) ^ (x >> 5) ^ (x >> 6) ^ (x >> 7) ^ 0x63) & 0xff;
}
return box;
})();
// Inverted S-box
const invSbox = /* @__PURE__ */ sbox.map((_, j) => sbox.indexOf(j));
// Rotate u32 by 8
const rotr32_8 = (n) => (n << 24) | (n >>> 8);
const rotl32_8 = (n) => (n << 8) | (n >>> 24);
// T-table is optimization suggested in 5.2 of original proposal (missed from FIPS-197). Changes:
// - LE instead of BE
// - bigger tables: T0 and T1 are merged into T01 table and T2 & T3 into T23;
// so index is u16, instead of u8. This speeds up things, unexpectedly
function genTtable(sbox, fn) {
if (sbox.length !== 256)
throw new Error('Wrong sbox length');
const T0 = new Uint32Array(256).map((_, j) => fn(sbox[j]));
const T1 = T0.map(rotl32_8);
const T2 = T1.map(rotl32_8);
const T3 = T2.map(rotl32_8);
const T01 = new Uint32Array(256 * 256);
const T23 = new Uint32Array(256 * 256);
const sbox2 = new Uint16Array(256 * 256);
for (let i = 0; i < 256; i++) {
for (let j = 0; j < 256; j++) {
const idx = i * 256 + j;
T01[idx] = T0[i] ^ T1[j];
T23[idx] = T2[i] ^ T3[j];
sbox2[idx] = (sbox[i] << 8) | sbox[j];
}
}
return { sbox, sbox2, T0, T1, T2, T3, T01, T23 };
}
const tableEncoding = /* @__PURE__ */ genTtable(sbox, (s) => (mul(s, 3) << 24) | (s << 16) | (s << 8) | mul(s, 2));
const tableDecoding = /* @__PURE__ */ genTtable(invSbox, (s) => (mul(s, 11) << 24) | (mul(s, 13) << 16) | (mul(s, 9) << 8) | mul(s, 14));
const xPowers = /* @__PURE__ */ (() => {
const p = new Uint8Array(16);
for (let i = 0, x = 1; i < 16; i++, x = mul2(x))
p[i] = x;
return p;
})();
function expandKeyLE(key) {
(0, _assert_js_1.bytes)(key);
const len = key.length;
if (![16, 24, 32].includes(len))
throw new Error(`aes: wrong key size: should be 16, 24 or 32, got: ${len}`);
const { sbox2 } = tableEncoding;
const k32 = (0, utils_js_1.u32)(key);
const Nk = k32.length;
const subByte = (n) => applySbox(sbox2, n, n, n, n);
const xk = new Uint32Array(len + 28); // expanded key
xk.set(k32);
// 4.3.1 Key expansion
for (let i = Nk; i < xk.length; i++) {
let t = xk[i - 1];
if (i % Nk === 0)
t = subByte(rotr32_8(t)) ^ xPowers[i / Nk - 1];
else if (Nk > 6 && i % Nk === 4)
t = subByte(t);
xk[i] = xk[i - Nk] ^ t;
}
return xk;
}
exports.expandKeyLE = expandKeyLE;
function expandKeyDecLE(key) {
const encKey = expandKeyLE(key);
const xk = encKey.slice();
const Nk = encKey.length;
const { sbox2 } = tableEncoding;
const { T0, T1, T2, T3 } = tableDecoding;
// Inverse key by chunks of 4 (rounds)
for (let i = 0; i < Nk; i += 4) {
for (let j = 0; j < 4; j++)
xk[i + j] = encKey[Nk - i - 4 + j];
}
encKey.fill(0);
// apply InvMixColumn except first & last round
for (let i = 4; i < Nk - 4; i++) {
const x = xk[i];
const w = applySbox(sbox2, x, x, x, x);
xk[i] = T0[w & 0xff] ^ T1[(w >>> 8) & 0xff] ^ T2[(w >>> 16) & 0xff] ^ T3[w >>> 24];
}
return xk;
}
exports.expandKeyDecLE = expandKeyDecLE;
// Apply tables
function apply0123(T01, T23, s0, s1, s2, s3) {
return (T01[((s0 << 8) & 0xff00) | ((s1 >>> 8) & 0xff)] ^
T23[((s2 >>> 8) & 0xff00) | ((s3 >>> 24) & 0xff)]);
}
function applySbox(sbox2, s0, s1, s2, s3) {
return (sbox2[(s0 & 0xff) | (s1 & 0xff00)] |
(sbox2[((s2 >>> 16) & 0xff) | ((s3 >>> 16) & 0xff00)] << 16));
}
function encrypt(xk, s0, s1, s2, s3) {
const { sbox2, T01, T23 } = tableEncoding;
let k = 0;
(s0 ^= xk[k++]), (s1 ^= xk[k++]), (s2 ^= xk[k++]), (s3 ^= xk[k++]);
const rounds = xk.length / 4 - 2;
for (let i = 0; i < rounds; i++) {
const t0 = xk[k++] ^ apply0123(T01, T23, s0, s1, s2, s3);
const t1 = xk[k++] ^ apply0123(T01, T23, s1, s2, s3, s0);
const t2 = xk[k++] ^ apply0123(T01, T23, s2, s3, s0, s1);
const t3 = xk[k++] ^ apply0123(T01, T23, s3, s0, s1, s2);
(s0 = t0), (s1 = t1), (s2 = t2), (s3 = t3);
}
// last round (without mixcolumns, so using SBOX2 table)
const t0 = xk[k++] ^ applySbox(sbox2, s0, s1, s2, s3);
const t1 = xk[k++] ^ applySbox(sbox2, s1, s2, s3, s0);
const t2 = xk[k++] ^ applySbox(sbox2, s2, s3, s0, s1);
const t3 = xk[k++] ^ applySbox(sbox2, s3, s0, s1, s2);
return { s0: t0, s1: t1, s2: t2, s3: t3 };
}
function decrypt(xk, s0, s1, s2, s3) {
const { sbox2, T01, T23 } = tableDecoding;
let k = 0;
(s0 ^= xk[k++]), (s1 ^= xk[k++]), (s2 ^= xk[k++]), (s3 ^= xk[k++]);
const rounds = xk.length / 4 - 2;
for (let i = 0; i < rounds; i++) {
const t0 = xk[k++] ^ apply0123(T01, T23, s0, s3, s2, s1);
const t1 = xk[k++] ^ apply0123(T01, T23, s1, s0, s3, s2);
const t2 = xk[k++] ^ apply0123(T01, T23, s2, s1, s0, s3);
const t3 = xk[k++] ^ apply0123(T01, T23, s3, s2, s1, s0);
(s0 = t0), (s1 = t1), (s2 = t2), (s3 = t3);
}
// Last round
const t0 = xk[k++] ^ applySbox(sbox2, s0, s3, s2, s1);
const t1 = xk[k++] ^ applySbox(sbox2, s1, s0, s3, s2);
const t2 = xk[k++] ^ applySbox(sbox2, s2, s1, s0, s3);
const t3 = xk[k++] ^ applySbox(sbox2, s3, s2, s1, s0);
return { s0: t0, s1: t1, s2: t2, s3: t3 };
}
function getDst(len, dst) {
if (!dst)
return new Uint8Array(len);
(0, _assert_js_1.bytes)(dst);
if (dst.length < len)
throw new Error(`aes: wrong destination length, expected at least ${len}, got: ${dst.length}`);
return dst;
}
// TODO: investigate merging with ctr32
function ctrCounter(xk, nonce, src, dst) {
(0, _assert_js_1.bytes)(nonce, BLOCK_SIZE);
(0, _assert_js_1.bytes)(src);
const srcLen = src.length;
dst = getDst(srcLen, dst);
const ctr = nonce;
const c32 = (0, utils_js_1.u32)(ctr);
// Fill block (empty, ctr=0)
let { s0, s1, s2, s3 } = encrypt(xk, c32[0], c32[1], c32[2], c32[3]);
const src32 = (0, utils_js_1.u32)(src);
const dst32 = (0, utils_js_1.u32)(dst);
// process blocks
for (let i = 0; i + 4 <= src32.length; i += 4) {
dst32[i + 0] = src32[i + 0] ^ s0;
dst32[i + 1] = src32[i + 1] ^ s1;
dst32[i + 2] = src32[i + 2] ^ s2;
dst32[i + 3] = src32[i + 3] ^ s3;
// Full 128 bit counter with wrap around
let carry = 1;
for (let i = ctr.length - 1; i >= 0; i--) {
carry = (carry + (ctr[i] & 0xff)) | 0;
ctr[i] = carry & 0xff;
carry >>>= 8;
}
({ s0, s1, s2, s3 } = encrypt(xk, c32[0], c32[1], c32[2], c32[3]));
}
// leftovers (less than block)
// It's possible to handle > u32 fast, but is it worth it?
const start = BLOCK_SIZE * Math.floor(src32.length / BLOCK_SIZE32);
if (start < srcLen) {
const b32 = new Uint32Array([s0, s1, s2, s3]);
const buf = (0, utils_js_1.u8)(b32);
for (let i = start, pos = 0; i < srcLen; i++, pos++)
dst[i] = src[i] ^ buf[pos];
}
return dst;
}
// AES CTR with overflowing 32 bit counter
// It's possible to do 32le significantly simpler (and probably faster) by using u32.
// But, we need both, and perf bottleneck is in ghash anyway.
function ctr32(xk, isLE, nonce, src, dst) {
(0, _assert_js_1.bytes)(nonce, BLOCK_SIZE);
(0, _assert_js_1.bytes)(src);
dst = getDst(src.length, dst);
const ctr = nonce; // write new value to nonce, so it can be re-used
const c32 = (0, utils_js_1.u32)(ctr);
const view = (0, utils_js_1.createView)(ctr);
const src32 = (0, utils_js_1.u32)(src);
const dst32 = (0, utils_js_1.u32)(dst);
const ctrPos = isLE ? 0 : 12;
const srcLen = src.length;
// Fill block (empty, ctr=0)
let ctrNum = view.getUint32(ctrPos, isLE); // read current counter value
let { s0, s1, s2, s3 } = encrypt(xk, c32[0], c32[1], c32[2], c32[3]);
// process blocks
for (let i = 0; i + 4 <= src32.length; i += 4) {
dst32[i + 0] = src32[i + 0] ^ s0;
dst32[i + 1] = src32[i + 1] ^ s1;
dst32[i + 2] = src32[i + 2] ^ s2;
dst32[i + 3] = src32[i + 3] ^ s3;
ctrNum = (ctrNum + 1) >>> 0; // u32 wrap
view.setUint32(ctrPos, ctrNum, isLE);
({ s0, s1, s2, s3 } = encrypt(xk, c32[0], c32[1], c32[2], c32[3]));
}
// leftovers (less than a block)
const start = BLOCK_SIZE * Math.floor(src32.length / BLOCK_SIZE32);
if (start < srcLen) {
const b32 = new Uint32Array([s0, s1, s2, s3]);
const buf = (0, utils_js_1.u8)(b32);
for (let i = start, pos = 0; i < srcLen; i++, pos++)
dst[i] = src[i] ^ buf[pos];
}
return dst;
}
/**
* CTR: counter mode. Creates stream cipher.
* Requires good IV. Parallelizable. OK, but no MAC.
*/
exports.ctr = (0, utils_js_1.wrapCipher)({ blockSize: 16, nonceLength: 16 }, function ctr(key, nonce) {
(0, _assert_js_1.bytes)(key);
(0, _assert_js_1.bytes)(nonce, BLOCK_SIZE);
function processCtr(buf, dst) {
const xk = expandKeyLE(key);
const n = nonce.slice();
const out = ctrCounter(xk, n, buf, dst);
xk.fill(0);
n.fill(0);
return out;
}
return {
encrypt: (plaintext, dst) => processCtr(plaintext, dst),
decrypt: (ciphertext, dst) => processCtr(ciphertext, dst),
};
});
function validateBlockDecrypt(data) {
(0, _assert_js_1.bytes)(data);
if (data.length % BLOCK_SIZE !== 0) {
throw new Error(`aes/(cbc-ecb).decrypt ciphertext should consist of blocks with size ${BLOCK_SIZE}`);
}
}
function validateBlockEncrypt(plaintext, pcks5, dst) {
let outLen = plaintext.length;
const remaining = outLen % BLOCK_SIZE;
if (!pcks5 && remaining !== 0)
throw new Error('aec/(cbc-ecb): unpadded plaintext with disabled padding');
const b = (0, utils_js_1.u32)(plaintext);
if (pcks5) {
let left = BLOCK_SIZE - remaining;
if (!left)
left = BLOCK_SIZE; // if no bytes left, create empty padding block
outLen = outLen + left;
}
const out = getDst(outLen, dst);
const o = (0, utils_js_1.u32)(out);
return { b, o, out };
}
function validatePCKS(data, pcks5) {
if (!pcks5)
return data;
const len = data.length;
if (!len)
throw new Error(`aes/pcks5: empty ciphertext not allowed`);
const lastByte = data[len - 1];
if (lastByte <= 0 || lastByte > 16)
throw new Error(`aes/pcks5: wrong padding byte: ${lastByte}`);
const out = data.subarray(0, -lastByte);
for (let i = 0; i < lastByte; i++)
if (data[len - i - 1] !== lastByte)
throw new Error(`aes/pcks5: wrong padding`);
return out;
}
function padPCKS(left) {
const tmp = new Uint8Array(16);
const tmp32 = (0, utils_js_1.u32)(tmp);
tmp.set(left);
const paddingByte = BLOCK_SIZE - left.length;
for (let i = BLOCK_SIZE - paddingByte; i < BLOCK_SIZE; i++)
tmp[i] = paddingByte;
return tmp32;
}
/**
* ECB: Electronic CodeBook. Simple deterministic replacement.
* Dangerous: always map x to y. See [AES Penguin](https://words.filippo.io/the-ecb-penguin/).
*/
exports.ecb = (0, utils_js_1.wrapCipher)({ blockSize: 16 }, function ecb(key, opts = {}) {
(0, _assert_js_1.bytes)(key);
const pcks5 = !opts.disablePadding;
return {
encrypt: (plaintext, dst) => {
(0, _assert_js_1.bytes)(plaintext);
const { b, o, out: _out } = validateBlockEncrypt(plaintext, pcks5, dst);
const xk = expandKeyLE(key);
let i = 0;
for (; i + 4 <= b.length;) {
const { s0, s1, s2, s3 } = encrypt(xk, b[i + 0], b[i + 1], b[i + 2], b[i + 3]);
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
if (pcks5) {
const tmp32 = padPCKS(plaintext.subarray(i * 4));
const { s0, s1, s2, s3 } = encrypt(xk, tmp32[0], tmp32[1], tmp32[2], tmp32[3]);
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
xk.fill(0);
return _out;
},
decrypt: (ciphertext, dst) => {
validateBlockDecrypt(ciphertext);
const xk = expandKeyDecLE(key);
const out = getDst(ciphertext.length, dst);
const b = (0, utils_js_1.u32)(ciphertext);
const o = (0, utils_js_1.u32)(out);
for (let i = 0; i + 4 <= b.length;) {
const { s0, s1, s2, s3 } = decrypt(xk, b[i + 0], b[i + 1], b[i + 2], b[i + 3]);
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
xk.fill(0);
return validatePCKS(out, pcks5);
},
};
});
/**
* CBC: Cipher-Block-Chaining. Key is previous rounds block.
* Fragile: needs proper padding. Unauthenticated: needs MAC.
*/
exports.cbc = (0, utils_js_1.wrapCipher)({ blockSize: 16, nonceLength: 16 }, function cbc(key, iv, opts = {}) {
(0, _assert_js_1.bytes)(key);
(0, _assert_js_1.bytes)(iv, 16);
const pcks5 = !opts.disablePadding;
return {
encrypt: (plaintext, dst) => {
const xk = expandKeyLE(key);
const { b, o, out: _out } = validateBlockEncrypt(plaintext, pcks5, dst);
const n32 = (0, utils_js_1.u32)(iv);
// prettier-ignore
let s0 = n32[0], s1 = n32[1], s2 = n32[2], s3 = n32[3];
let i = 0;
for (; i + 4 <= b.length;) {
(s0 ^= b[i + 0]), (s1 ^= b[i + 1]), (s2 ^= b[i + 2]), (s3 ^= b[i + 3]);
({ s0, s1, s2, s3 } = encrypt(xk, s0, s1, s2, s3));
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
if (pcks5) {
const tmp32 = padPCKS(plaintext.subarray(i * 4));
(s0 ^= tmp32[0]), (s1 ^= tmp32[1]), (s2 ^= tmp32[2]), (s3 ^= tmp32[3]);
({ s0, s1, s2, s3 } = encrypt(xk, s0, s1, s2, s3));
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
xk.fill(0);
return _out;
},
decrypt: (ciphertext, dst) => {
validateBlockDecrypt(ciphertext);
const xk = expandKeyDecLE(key);
const n32 = (0, utils_js_1.u32)(iv);
const out = getDst(ciphertext.length, dst);
const b = (0, utils_js_1.u32)(ciphertext);
const o = (0, utils_js_1.u32)(out);
// prettier-ignore
let s0 = n32[0], s1 = n32[1], s2 = n32[2], s3 = n32[3];
for (let i = 0; i + 4 <= b.length;) {
// prettier-ignore
const ps0 = s0, ps1 = s1, ps2 = s2, ps3 = s3;
(s0 = b[i + 0]), (s1 = b[i + 1]), (s2 = b[i + 2]), (s3 = b[i + 3]);
const { s0: o0, s1: o1, s2: o2, s3: o3 } = decrypt(xk, s0, s1, s2, s3);
(o[i++] = o0 ^ ps0), (o[i++] = o1 ^ ps1), (o[i++] = o2 ^ ps2), (o[i++] = o3 ^ ps3);
}
xk.fill(0);
return validatePCKS(out, pcks5);
},
};
});
/**
* CFB: Cipher Feedback Mode. The input for the block cipher is the previous cipher output.
* Unauthenticated: needs MAC.
*/
exports.cfb = (0, utils_js_1.wrapCipher)({ blockSize: 16, nonceLength: 16 }, function cfb(key, iv) {
(0, _assert_js_1.bytes)(key);
(0, _assert_js_1.bytes)(iv, 16);
function processCfb(src, isEncrypt, dst) {
const xk = expandKeyLE(key);
const srcLen = src.length;
dst = getDst(srcLen, dst);
const src32 = (0, utils_js_1.u32)(src);
const dst32 = (0, utils_js_1.u32)(dst);
const next32 = isEncrypt ? dst32 : src32;
const n32 = (0, utils_js_1.u32)(iv);
// prettier-ignore
let s0 = n32[0], s1 = n32[1], s2 = n32[2], s3 = n32[3];
for (let i = 0; i + 4 <= src32.length;) {
const { s0: e0, s1: e1, s2: e2, s3: e3 } = encrypt(xk, s0, s1, s2, s3);
dst32[i + 0] = src32[i + 0] ^ e0;
dst32[i + 1] = src32[i + 1] ^ e1;
dst32[i + 2] = src32[i + 2] ^ e2;
dst32[i + 3] = src32[i + 3] ^ e3;
(s0 = next32[i++]), (s1 = next32[i++]), (s2 = next32[i++]), (s3 = next32[i++]);
}
// leftovers (less than block)
const start = BLOCK_SIZE * Math.floor(src32.length / BLOCK_SIZE32);
if (start < srcLen) {
({ s0, s1, s2, s3 } = encrypt(xk, s0, s1, s2, s3));
const buf = (0, utils_js_1.u8)(new Uint32Array([s0, s1, s2, s3]));
for (let i = start, pos = 0; i < srcLen; i++, pos++)
dst[i] = src[i] ^ buf[pos];
buf.fill(0);
}
xk.fill(0);
return dst;
}
return {
encrypt: (plaintext, dst) => processCfb(plaintext, true, dst),
decrypt: (ciphertext, dst) => processCfb(ciphertext, false, dst),
};
});
// TODO: merge with chacha, however gcm has bitLen while chacha has byteLen
function computeTag(fn, isLE, key, data, AAD) {
const h = fn.create(key, data.length + (AAD?.length || 0));
if (AAD)
h.update(AAD);
h.update(data);
const num = new Uint8Array(16);
const view = (0, utils_js_1.createView)(num);
if (AAD)
(0, utils_js_1.setBigUint64)(view, 0, BigInt(AAD.length * 8), isLE);
(0, utils_js_1.setBigUint64)(view, 8, BigInt(data.length * 8), isLE);
h.update(num);
return h.digest();
}
/**
* GCM: Galois/Counter Mode.
* Good, modern version of CTR, parallel, with MAC.
* Be careful: MACs can be forged.
*/
exports.gcm = (0, utils_js_1.wrapCipher)({ blockSize: 16, nonceLength: 12, tagLength: 16 }, function gcm(key, nonce, AAD) {
(0, _assert_js_1.bytes)(nonce);
// Nonce can be pretty much anything (even 1 byte). But smaller nonces less secure.
if (nonce.length === 0)
throw new Error('aes/gcm: empty nonce');
const tagLength = 16;
function _computeTag(authKey, tagMask, data) {
const tag = computeTag(_polyval_js_1.ghash, false, authKey, data, AAD);
for (let i = 0; i < tagMask.length; i++)
tag[i] ^= tagMask[i];
return tag;
}
function deriveKeys() {
const xk = expandKeyLE(key);
const authKey = EMPTY_BLOCK.slice();
const counter = EMPTY_BLOCK.slice();
ctr32(xk, false, counter, counter, authKey);
if (nonce.length === 12) {
counter.set(nonce);
}
else {
// Spec (NIST 800-38d) supports variable size nonce.
// Not supported for now, but can be useful.
const nonceLen = EMPTY_BLOCK.slice();
const view = (0, utils_js_1.createView)(nonceLen);
(0, utils_js_1.setBigUint64)(view, 8, BigInt(nonce.length * 8), false);
// ghash(nonce || u64be(0) || u64be(nonceLen*8))
_polyval_js_1.ghash.create(authKey).update(nonce).update(nonceLen).digestInto(counter);
}
const tagMask = ctr32(xk, false, counter, EMPTY_BLOCK);
return { xk, authKey, counter, tagMask };
}
return {
encrypt: (plaintext) => {
(0, _assert_js_1.bytes)(plaintext);
const { xk, authKey, counter, tagMask } = deriveKeys();
const out = new Uint8Array(plaintext.length + tagLength);
ctr32(xk, false, counter, plaintext, out);
const tag = _computeTag(authKey, tagMask, out.subarray(0, out.length - tagLength));
out.set(tag, plaintext.length);
xk.fill(0);
return out;
},
decrypt: (ciphertext) => {
(0, _assert_js_1.bytes)(ciphertext);
if (ciphertext.length < tagLength)
throw new Error(`aes/gcm: ciphertext less than tagLen (${tagLength})`);
const { xk, authKey, counter, tagMask } = deriveKeys();
const data = ciphertext.subarray(0, -tagLength);
const passedTag = ciphertext.subarray(-tagLength);
const tag = _computeTag(authKey, tagMask, data);
if (!(0, utils_js_1.equalBytes)(tag, passedTag))
throw new Error('aes/gcm: invalid ghash tag');
const out = ctr32(xk, false, counter, data);
authKey.fill(0);
tagMask.fill(0);
xk.fill(0);
return out;
},
};
});
const limit = (name, min, max) => (value) => {
if (!Number.isSafeInteger(value) || min > value || value > max)
throw new Error(`${name}: invalid value=${value}, must be [${min}..${max}]`);
};
/**
* AES-GCM-SIV: classic AES-GCM with nonce-misuse resistance.
* Guarantees that, when a nonce is repeated, the only security loss is that identical
* plaintexts will produce identical ciphertexts.
* RFC 8452, https://datatracker.ietf.org/doc/html/rfc8452
*/
exports.siv = (0, utils_js_1.wrapCipher)({ blockSize: 16, nonceLength: 12, tagLength: 16 }, function siv(key, nonce, AAD) {
const tagLength = 16;
// From RFC 8452: Section 6
const AAD_LIMIT = limit('AAD', 0, 2 ** 36);
const PLAIN_LIMIT = limit('plaintext', 0, 2 ** 36);
const NONCE_LIMIT = limit('nonce', 12, 12);
const CIPHER_LIMIT = limit('ciphertext', 16, 2 ** 36 + 16);
(0, _assert_js_1.bytes)(nonce);
NONCE_LIMIT(nonce.length);
if (AAD) {
(0, _assert_js_1.bytes)(AAD);
AAD_LIMIT(AAD.length);
}
function deriveKeys() {
const len = key.length;
if (len !== 16 && len !== 24 && len !== 32)
throw new Error(`key length must be 16, 24 or 32 bytes, got: ${len} bytes`);
const xk = expandKeyLE(key);
const encKey = new Uint8Array(len);
const authKey = new Uint8Array(16);
const n32 = (0, utils_js_1.u32)(nonce);
// prettier-ignore
let s0 = 0, s1 = n32[0], s2 = n32[1], s3 = n32[2];
let counter = 0;
for (const derivedKey of [authKey, encKey].map(utils_js_1.u32)) {
const d32 = (0, utils_js_1.u32)(derivedKey);
for (let i = 0; i < d32.length; i += 2) {
// aes(u32le(0) || nonce)[:8] || aes(u32le(1) || nonce)[:8] ...
const { s0: o0, s1: o1 } = encrypt(xk, s0, s1, s2, s3);
d32[i + 0] = o0;
d32[i + 1] = o1;
s0 = ++counter; // increment counter inside state
}
}
xk.fill(0);
return { authKey, encKey: expandKeyLE(encKey) };
}
function _computeTag(encKey, authKey, data) {
const tag = computeTag(_polyval_js_1.polyval, true, authKey, data, AAD);
// Compute the expected tag by XORing S_s and the nonce, clearing the
// most significant bit of the last byte and encrypting with the
// message-encryption key.
for (let i = 0; i < 12; i++)
tag[i] ^= nonce[i];
tag[15] &= 0x7f; // Clear the highest bit
// encrypt tag as block
const t32 = (0, utils_js_1.u32)(tag);
// prettier-ignore
let s0 = t32[0], s1 = t32[1], s2 = t32[2], s3 = t32[3];
({ s0, s1, s2, s3 } = encrypt(encKey, s0, s1, s2, s3));
(t32[0] = s0), (t32[1] = s1), (t32[2] = s2), (t32[3] = s3);
return tag;
}
// actual decrypt/encrypt of message.
function processSiv(encKey, tag, input) {
let block = tag.slice();
block[15] |= 0x80; // Force highest bit
return ctr32(encKey, true, block, input);
}
return {
encrypt: (plaintext) => {
(0, _assert_js_1.bytes)(plaintext);
PLAIN_LIMIT(plaintext.length);
const { encKey, authKey } = deriveKeys();
const tag = _computeTag(encKey, authKey, plaintext);
const out = new Uint8Array(plaintext.length + tagLength);
out.set(tag, plaintext.length);
out.set(processSiv(encKey, tag, plaintext));
encKey.fill(0);
authKey.fill(0);
return out;
},
decrypt: (ciphertext) => {
(0, _assert_js_1.bytes)(ciphertext);
CIPHER_LIMIT(ciphertext.length);
const tag = ciphertext.subarray(-tagLength);
const { encKey, authKey } = deriveKeys();
const plaintext = processSiv(encKey, tag, ciphertext.subarray(0, -tagLength));
const expectedTag = _computeTag(encKey, authKey, plaintext);
encKey.fill(0);
authKey.fill(0);
if (!(0, utils_js_1.equalBytes)(tag, expectedTag))
throw new Error('invalid polyval tag');
return plaintext;
},
};
});
function isBytes32(a) {
return (a != null &&
typeof a === 'object' &&
(a instanceof Uint32Array || a.constructor.name === 'Uint32Array'));
}
function encryptBlock(xk, block) {
(0, _assert_js_1.bytes)(block, 16);
if (!isBytes32(xk))
throw new Error('_encryptBlock accepts result of expandKeyLE');
const b32 = (0, utils_js_1.u32)(block);
let { s0, s1, s2, s3 } = encrypt(xk, b32[0], b32[1], b32[2], b32[3]);
(b32[0] = s0), (b32[1] = s1), (b32[2] = s2), (b32[3] = s3);
return block;
}
function decryptBlock(xk, block) {
(0, _assert_js_1.bytes)(block, 16);
if (!isBytes32(xk))
throw new Error('_decryptBlock accepts result of expandKeyLE');
const b32 = (0, utils_js_1.u32)(block);
let { s0, s1, s2, s3 } = decrypt(xk, b32[0], b32[1], b32[2], b32[3]);
(b32[0] = s0), (b32[1] = s1), (b32[2] = s2), (b32[3] = s3);
return block;
}
// Highly unsafe private functions for implementing new modes or ciphers based on AES
// Can change at any time, no API guarantees
exports.unsafe = {
expandKeyLE,
expandKeyDecLE,
encrypt,
decrypt,
encryptBlock,
decryptBlock,
ctrCounter,
ctr32,
};
//# sourceMappingURL=aes.js.map

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import { CipherWithOutput, XorStream } from './utils.js';
/**
* hchacha helper method, used primarily in xchacha, to hash
* key and nonce into key' and nonce'.
* Same as chachaCore, but there doesn't seem to be a way to move the block
* out without 25% performance hit.
*/
export declare function hchacha(s: Uint32Array, k: Uint32Array, i: Uint32Array, o32: Uint32Array): void;
/**
* Original, non-RFC chacha20 from DJB. 8-byte nonce, 8-byte counter.
*/
export declare const chacha20orig: XorStream;
/**
* ChaCha stream cipher. Conforms to RFC 8439 (IETF, TLS). 12-byte nonce, 4-byte counter.
* With 12-byte nonce, it's not safe to use fill it with random (CSPRNG), due to collision chance.
*/
export declare const chacha20: XorStream;
/**
* XChaCha eXtended-nonce ChaCha. 24-byte nonce.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
* https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha
*/
export declare const xchacha20: XorStream;
/**
* Reduced 8-round chacha, described in original paper.
*/
export declare const chacha8: XorStream;
/**
* Reduced 12-round chacha, described in original paper.
*/
export declare const chacha12: XorStream;
/**
* AEAD algorithm from RFC 8439.
* Salsa20 and chacha (RFC 8439) use poly1305 differently.
* We could have composed them similar to:
* https://github.com/paulmillr/scure-base/blob/b266c73dde977b1dd7ef40ef7a23cc15aab526b3/index.ts#L250
* But it's hard because of authKey:
* In salsa20, authKey changes position in salsa stream.
* In chacha, authKey can't be computed inside computeTag, it modifies the counter.
*/
export declare const _poly1305_aead: (xorStream: XorStream) => (key: Uint8Array, nonce: Uint8Array, AAD?: Uint8Array) => CipherWithOutput;
/**
* ChaCha20-Poly1305 from RFC 8439.
* With 12-byte nonce, it's not safe to use fill it with random (CSPRNG), due to collision chance.
*/
export declare const chacha20poly1305: ((key: Uint8Array, nonce: Uint8Array, AAD?: Uint8Array) => CipherWithOutput) & {
blockSize: number;
nonceLength: number;
tagLength: number;
};
/**
* XChaCha20-Poly1305 extended-nonce chacha.
* https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
*/
export declare const xchacha20poly1305: ((key: Uint8Array, nonce: Uint8Array, AAD?: Uint8Array) => CipherWithOutput) & {
blockSize: number;
nonceLength: number;
tagLength: number;
};
//# sourceMappingURL=chacha.d.ts.map

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{"version":3,"file":"chacha.d.ts","sourceRoot":"","sources":["src/chacha.ts"],"names":[],"mappings":"AACA,OAAO,EACO,gBAAgB,EAAE,SAAS,EACxC,MAAM,YAAY,CAAC;AA6EpB;;;;;GAKG;AAEH,wBAAgB,OAAO,CACrB,CAAC,EAAE,WAAW,EAAE,CAAC,EAAE,WAAW,EAAE,CAAC,EAAE,WAAW,EAAE,GAAG,EAAE,WAAW,QAoDjE;AACD;;GAEG;AACH,eAAO,MAAM,YAAY,WAIvB,CAAC;AACH;;;GAGG;AACH,eAAO,MAAM,QAAQ,WAInB,CAAC;AAEH;;;;GAIG;AACH,eAAO,MAAM,SAAS,WAKpB,CAAC;AAEH;;GAEG;AACH,eAAO,MAAM,OAAO,WAIlB,CAAC;AAEH;;GAEG;AACH,eAAO,MAAM,QAAQ,WAInB,CAAC;AAgCH;;;;;;;;GAQG;AACH,eAAO,MAAM,cAAc,cACb,SAAS,WACf,UAAU,SAAS,UAAU,QAAQ,UAAU,KAAG,gBAoCvD,CAAC;AAEJ;;;GAGG;AACH,eAAO,MAAM,gBAAgB,SA1CrB,UAAU,SAAS,UAAU,QAAQ,UAAU,KAAG,gBAAgB;;;;CA6CzE,CAAC;AACF;;;;GAIG;AACH,eAAO,MAAM,iBAAiB,SAnDtB,UAAU,SAAS,UAAU,QAAQ,UAAU,KAAG,gBAAgB;;;;CAsDzE,CAAC"}

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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.xchacha20poly1305 = exports.chacha20poly1305 = exports._poly1305_aead = exports.chacha12 = exports.chacha8 = exports.xchacha20 = exports.chacha20 = exports.chacha20orig = exports.hchacha = void 0;
// prettier-ignore
const utils_js_1 = require("./utils.js");
const _poly1305_js_1 = require("./_poly1305.js");
const _arx_js_1 = require("./_arx.js");
const _assert_js_1 = require("./_assert.js");
// ChaCha20 stream cipher was released in 2008. ChaCha aims to increase
// the diffusion per round, but had slightly less cryptanalysis.
// https://cr.yp.to/chacha.html, http://cr.yp.to/chacha/chacha-20080128.pdf
/**
* ChaCha core function.
*/
// prettier-ignore
function chachaCore(s, k, n, out, cnt, rounds = 20) {
let y00 = s[0], y01 = s[1], y02 = s[2], y03 = s[3], // "expa" "nd 3" "2-by" "te k"
y04 = k[0], y05 = k[1], y06 = k[2], y07 = k[3], // Key Key Key Key
y08 = k[4], y09 = k[5], y10 = k[6], y11 = k[7], // Key Key Key Key
y12 = cnt, y13 = n[0], y14 = n[1], y15 = n[2]; // Counter Counter Nonce Nonce
// Save state to temporary variables
let x00 = y00, x01 = y01, x02 = y02, x03 = y03, x04 = y04, x05 = y05, x06 = y06, x07 = y07, x08 = y08, x09 = y09, x10 = y10, x11 = y11, x12 = y12, x13 = y13, x14 = y14, x15 = y15;
for (let r = 0; r < rounds; r += 2) {
x00 = (x00 + x04) | 0;
x12 = (0, _arx_js_1.rotl)(x12 ^ x00, 16);
x08 = (x08 + x12) | 0;
x04 = (0, _arx_js_1.rotl)(x04 ^ x08, 12);
x00 = (x00 + x04) | 0;
x12 = (0, _arx_js_1.rotl)(x12 ^ x00, 8);
x08 = (x08 + x12) | 0;
x04 = (0, _arx_js_1.rotl)(x04 ^ x08, 7);
x01 = (x01 + x05) | 0;
x13 = (0, _arx_js_1.rotl)(x13 ^ x01, 16);
x09 = (x09 + x13) | 0;
x05 = (0, _arx_js_1.rotl)(x05 ^ x09, 12);
x01 = (x01 + x05) | 0;
x13 = (0, _arx_js_1.rotl)(x13 ^ x01, 8);
x09 = (x09 + x13) | 0;
x05 = (0, _arx_js_1.rotl)(x05 ^ x09, 7);
x02 = (x02 + x06) | 0;
x14 = (0, _arx_js_1.rotl)(x14 ^ x02, 16);
x10 = (x10 + x14) | 0;
x06 = (0, _arx_js_1.rotl)(x06 ^ x10, 12);
x02 = (x02 + x06) | 0;
x14 = (0, _arx_js_1.rotl)(x14 ^ x02, 8);
x10 = (x10 + x14) | 0;
x06 = (0, _arx_js_1.rotl)(x06 ^ x10, 7);
x03 = (x03 + x07) | 0;
x15 = (0, _arx_js_1.rotl)(x15 ^ x03, 16);
x11 = (x11 + x15) | 0;
x07 = (0, _arx_js_1.rotl)(x07 ^ x11, 12);
x03 = (x03 + x07) | 0;
x15 = (0, _arx_js_1.rotl)(x15 ^ x03, 8);
x11 = (x11 + x15) | 0;
x07 = (0, _arx_js_1.rotl)(x07 ^ x11, 7);
x00 = (x00 + x05) | 0;
x15 = (0, _arx_js_1.rotl)(x15 ^ x00, 16);
x10 = (x10 + x15) | 0;
x05 = (0, _arx_js_1.rotl)(x05 ^ x10, 12);
x00 = (x00 + x05) | 0;
x15 = (0, _arx_js_1.rotl)(x15 ^ x00, 8);
x10 = (x10 + x15) | 0;
x05 = (0, _arx_js_1.rotl)(x05 ^ x10, 7);
x01 = (x01 + x06) | 0;
x12 = (0, _arx_js_1.rotl)(x12 ^ x01, 16);
x11 = (x11 + x12) | 0;
x06 = (0, _arx_js_1.rotl)(x06 ^ x11, 12);
x01 = (x01 + x06) | 0;
x12 = (0, _arx_js_1.rotl)(x12 ^ x01, 8);
x11 = (x11 + x12) | 0;
x06 = (0, _arx_js_1.rotl)(x06 ^ x11, 7);
x02 = (x02 + x07) | 0;
x13 = (0, _arx_js_1.rotl)(x13 ^ x02, 16);
x08 = (x08 + x13) | 0;
x07 = (0, _arx_js_1.rotl)(x07 ^ x08, 12);
x02 = (x02 + x07) | 0;
x13 = (0, _arx_js_1.rotl)(x13 ^ x02, 8);
x08 = (x08 + x13) | 0;
x07 = (0, _arx_js_1.rotl)(x07 ^ x08, 7);
x03 = (x03 + x04) | 0;
x14 = (0, _arx_js_1.rotl)(x14 ^ x03, 16);
x09 = (x09 + x14) | 0;
x04 = (0, _arx_js_1.rotl)(x04 ^ x09, 12);
x03 = (x03 + x04) | 0;
x14 = (0, _arx_js_1.rotl)(x14 ^ x03, 8);
x09 = (x09 + x14) | 0;
x04 = (0, _arx_js_1.rotl)(x04 ^ x09, 7);
}
// Write output
let oi = 0;
out[oi++] = (y00 + x00) | 0;
out[oi++] = (y01 + x01) | 0;
out[oi++] = (y02 + x02) | 0;
out[oi++] = (y03 + x03) | 0;
out[oi++] = (y04 + x04) | 0;
out[oi++] = (y05 + x05) | 0;
out[oi++] = (y06 + x06) | 0;
out[oi++] = (y07 + x07) | 0;
out[oi++] = (y08 + x08) | 0;
out[oi++] = (y09 + x09) | 0;
out[oi++] = (y10 + x10) | 0;
out[oi++] = (y11 + x11) | 0;
out[oi++] = (y12 + x12) | 0;
out[oi++] = (y13 + x13) | 0;
out[oi++] = (y14 + x14) | 0;
out[oi++] = (y15 + x15) | 0;
}
/**
* hchacha helper method, used primarily in xchacha, to hash
* key and nonce into key' and nonce'.
* Same as chachaCore, but there doesn't seem to be a way to move the block
* out without 25% performance hit.
*/
// prettier-ignore
function hchacha(s, k, i, o32) {
let x00 = s[0], x01 = s[1], x02 = s[2], x03 = s[3], x04 = k[0], x05 = k[1], x06 = k[2], x07 = k[3], x08 = k[4], x09 = k[5], x10 = k[6], x11 = k[7], x12 = i[0], x13 = i[1], x14 = i[2], x15 = i[3];
for (let r = 0; r < 20; r += 2) {
x00 = (x00 + x04) | 0;
x12 = (0, _arx_js_1.rotl)(x12 ^ x00, 16);
x08 = (x08 + x12) | 0;
x04 = (0, _arx_js_1.rotl)(x04 ^ x08, 12);
x00 = (x00 + x04) | 0;
x12 = (0, _arx_js_1.rotl)(x12 ^ x00, 8);
x08 = (x08 + x12) | 0;
x04 = (0, _arx_js_1.rotl)(x04 ^ x08, 7);
x01 = (x01 + x05) | 0;
x13 = (0, _arx_js_1.rotl)(x13 ^ x01, 16);
x09 = (x09 + x13) | 0;
x05 = (0, _arx_js_1.rotl)(x05 ^ x09, 12);
x01 = (x01 + x05) | 0;
x13 = (0, _arx_js_1.rotl)(x13 ^ x01, 8);
x09 = (x09 + x13) | 0;
x05 = (0, _arx_js_1.rotl)(x05 ^ x09, 7);
x02 = (x02 + x06) | 0;
x14 = (0, _arx_js_1.rotl)(x14 ^ x02, 16);
x10 = (x10 + x14) | 0;
x06 = (0, _arx_js_1.rotl)(x06 ^ x10, 12);
x02 = (x02 + x06) | 0;
x14 = (0, _arx_js_1.rotl)(x14 ^ x02, 8);
x10 = (x10 + x14) | 0;
x06 = (0, _arx_js_1.rotl)(x06 ^ x10, 7);
x03 = (x03 + x07) | 0;
x15 = (0, _arx_js_1.rotl)(x15 ^ x03, 16);
x11 = (x11 + x15) | 0;
x07 = (0, _arx_js_1.rotl)(x07 ^ x11, 12);
x03 = (x03 + x07) | 0;
x15 = (0, _arx_js_1.rotl)(x15 ^ x03, 8);
x11 = (x11 + x15) | 0;
x07 = (0, _arx_js_1.rotl)(x07 ^ x11, 7);
x00 = (x00 + x05) | 0;
x15 = (0, _arx_js_1.rotl)(x15 ^ x00, 16);
x10 = (x10 + x15) | 0;
x05 = (0, _arx_js_1.rotl)(x05 ^ x10, 12);
x00 = (x00 + x05) | 0;
x15 = (0, _arx_js_1.rotl)(x15 ^ x00, 8);
x10 = (x10 + x15) | 0;
x05 = (0, _arx_js_1.rotl)(x05 ^ x10, 7);
x01 = (x01 + x06) | 0;
x12 = (0, _arx_js_1.rotl)(x12 ^ x01, 16);
x11 = (x11 + x12) | 0;
x06 = (0, _arx_js_1.rotl)(x06 ^ x11, 12);
x01 = (x01 + x06) | 0;
x12 = (0, _arx_js_1.rotl)(x12 ^ x01, 8);
x11 = (x11 + x12) | 0;
x06 = (0, _arx_js_1.rotl)(x06 ^ x11, 7);
x02 = (x02 + x07) | 0;
x13 = (0, _arx_js_1.rotl)(x13 ^ x02, 16);
x08 = (x08 + x13) | 0;
x07 = (0, _arx_js_1.rotl)(x07 ^ x08, 12);
x02 = (x02 + x07) | 0;
x13 = (0, _arx_js_1.rotl)(x13 ^ x02, 8);
x08 = (x08 + x13) | 0;
x07 = (0, _arx_js_1.rotl)(x07 ^ x08, 7);
x03 = (x03 + x04) | 0;
x14 = (0, _arx_js_1.rotl)(x14 ^ x03, 16);
x09 = (x09 + x14) | 0;
x04 = (0, _arx_js_1.rotl)(x04 ^ x09, 12);
x03 = (x03 + x04) | 0;
x14 = (0, _arx_js_1.rotl)(x14 ^ x03, 8);
x09 = (x09 + x14) | 0;
x04 = (0, _arx_js_1.rotl)(x04 ^ x09, 7);
}
let oi = 0;
o32[oi++] = x00;
o32[oi++] = x01;
o32[oi++] = x02;
o32[oi++] = x03;
o32[oi++] = x12;
o32[oi++] = x13;
o32[oi++] = x14;
o32[oi++] = x15;
}
exports.hchacha = hchacha;
/**
* Original, non-RFC chacha20 from DJB. 8-byte nonce, 8-byte counter.
*/
exports.chacha20orig = (0, _arx_js_1.createCipher)(chachaCore, {
counterRight: false,
counterLength: 8,
allowShortKeys: true,
});
/**
* ChaCha stream cipher. Conforms to RFC 8439 (IETF, TLS). 12-byte nonce, 4-byte counter.
* With 12-byte nonce, it's not safe to use fill it with random (CSPRNG), due to collision chance.
*/
exports.chacha20 = (0, _arx_js_1.createCipher)(chachaCore, {
counterRight: false,
counterLength: 4,
allowShortKeys: false,
});
/**
* XChaCha eXtended-nonce ChaCha. 24-byte nonce.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
* https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha
*/
exports.xchacha20 = (0, _arx_js_1.createCipher)(chachaCore, {
counterRight: false,
counterLength: 8,
extendNonceFn: hchacha,
allowShortKeys: false,
});
/**
* Reduced 8-round chacha, described in original paper.
*/
exports.chacha8 = (0, _arx_js_1.createCipher)(chachaCore, {
counterRight: false,
counterLength: 4,
rounds: 8,
});
/**
* Reduced 12-round chacha, described in original paper.
*/
exports.chacha12 = (0, _arx_js_1.createCipher)(chachaCore, {
counterRight: false,
counterLength: 4,
rounds: 12,
});
const ZEROS16 = /* @__PURE__ */ new Uint8Array(16);
// Pad to digest size with zeros
const updatePadded = (h, msg) => {
h.update(msg);
const left = msg.length % 16;
if (left)
h.update(ZEROS16.subarray(left));
};
const ZEROS32 = /* @__PURE__ */ new Uint8Array(32);
function computeTag(fn, key, nonce, data, AAD) {
const authKey = fn(key, nonce, ZEROS32);
const h = _poly1305_js_1.poly1305.create(authKey);
if (AAD)
updatePadded(h, AAD);
updatePadded(h, data);
const num = new Uint8Array(16);
const view = (0, utils_js_1.createView)(num);
(0, utils_js_1.setBigUint64)(view, 0, BigInt(AAD ? AAD.length : 0), true);
(0, utils_js_1.setBigUint64)(view, 8, BigInt(data.length), true);
h.update(num);
const res = h.digest();
authKey.fill(0);
return res;
}
/**
* AEAD algorithm from RFC 8439.
* Salsa20 and chacha (RFC 8439) use poly1305 differently.
* We could have composed them similar to:
* https://github.com/paulmillr/scure-base/blob/b266c73dde977b1dd7ef40ef7a23cc15aab526b3/index.ts#L250
* But it's hard because of authKey:
* In salsa20, authKey changes position in salsa stream.
* In chacha, authKey can't be computed inside computeTag, it modifies the counter.
*/
const _poly1305_aead = (xorStream) => (key, nonce, AAD) => {
const tagLength = 16;
(0, _assert_js_1.bytes)(key, 32);
(0, _assert_js_1.bytes)(nonce);
return {
encrypt: (plaintext, output) => {
const plength = plaintext.length;
const clength = plength + tagLength;
if (output) {
(0, _assert_js_1.bytes)(output, clength);
}
else {
output = new Uint8Array(clength);
}
xorStream(key, nonce, plaintext, output, 1);
const tag = computeTag(xorStream, key, nonce, output.subarray(0, -tagLength), AAD);
output.set(tag, plength); // append tag
return output;
},
decrypt: (ciphertext, output) => {
const clength = ciphertext.length;
const plength = clength - tagLength;
if (clength < tagLength)
throw new Error(`encrypted data must be at least ${tagLength} bytes`);
if (output) {
(0, _assert_js_1.bytes)(output, plength);
}
else {
output = new Uint8Array(plength);
}
const data = ciphertext.subarray(0, -tagLength);
const passedTag = ciphertext.subarray(-tagLength);
const tag = computeTag(xorStream, key, nonce, data, AAD);
if (!(0, utils_js_1.equalBytes)(passedTag, tag))
throw new Error('invalid tag');
xorStream(key, nonce, data, output, 1);
return output;
},
};
};
exports._poly1305_aead = _poly1305_aead;
/**
* ChaCha20-Poly1305 from RFC 8439.
* With 12-byte nonce, it's not safe to use fill it with random (CSPRNG), due to collision chance.
*/
exports.chacha20poly1305 = (0, utils_js_1.wrapCipher)({ blockSize: 64, nonceLength: 12, tagLength: 16 }, (0, exports._poly1305_aead)(exports.chacha20));
/**
* XChaCha20-Poly1305 extended-nonce chacha.
* https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
*/
exports.xchacha20poly1305 = (0, utils_js_1.wrapCipher)({ blockSize: 64, nonceLength: 24, tagLength: 16 }, (0, exports._poly1305_aead)(exports.xchacha20));
//# sourceMappingURL=chacha.js.map

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export declare function randomBytes(bytesLength?: number): Uint8Array;
export declare function getWebcryptoSubtle(): any;
//# sourceMappingURL=crypto.d.ts.map

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{"version":3,"file":"crypto.d.ts","sourceRoot":"","sources":["src/crypto.ts"],"names":[],"mappings":"AAKA,wBAAgB,WAAW,CAAC,WAAW,SAAK,GAAG,UAAU,CAIxD;AAED,wBAAgB,kBAAkB,QAGjC"}

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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.getWebcryptoSubtle = exports.randomBytes = void 0;
const cr = typeof globalThis === 'object' && 'crypto' in globalThis ? globalThis.crypto : undefined;
function randomBytes(bytesLength = 32) {
if (cr && typeof cr.getRandomValues === 'function')
return cr.getRandomValues(new Uint8Array(bytesLength));
throw new Error('crypto.getRandomValues must be defined');
}
exports.randomBytes = randomBytes;
function getWebcryptoSubtle() {
if (cr && typeof cr.subtle === 'object' && cr.subtle != null)
return cr.subtle;
throw new Error('crypto.subtle must be defined');
}
exports.getWebcryptoSubtle = getWebcryptoSubtle;
//# sourceMappingURL=crypto.js.map

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export declare function randomBytes(bytesLength?: number): Uint8Array;
export declare function getWebcryptoSubtle(): any;
//# sourceMappingURL=cryptoNode.d.ts.map

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{"version":3,"file":"cryptoNode.d.ts","sourceRoot":"","sources":["src/cryptoNode.ts"],"names":[],"mappings":"AAOA,wBAAgB,WAAW,CAAC,WAAW,SAAK,GAAG,UAAU,CAIxD;AAED,wBAAgB,kBAAkB,QAGjC"}

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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.getWebcryptoSubtle = exports.randomBytes = void 0;
// We use WebCrypto aka globalThis.crypto, which exists in browsers and node.js 16+.
// See utils.ts for details.
// The file will throw on node.js 14 and earlier.
// @ts-ignore
const nc = require("node:crypto");
const cr = nc && typeof nc === 'object' && 'webcrypto' in nc ? nc.webcrypto : undefined;
function randomBytes(bytesLength = 32) {
if (cr && typeof cr.getRandomValues === 'function')
return cr.getRandomValues(new Uint8Array(bytesLength));
throw new Error('crypto.getRandomValues must be defined');
}
exports.randomBytes = randomBytes;
function getWebcryptoSubtle() {
if (cr && typeof cr.subtle === 'object' && cr.subtle != null)
return cr.subtle;
throw new Error('crypto.subtle must be defined');
}
exports.getWebcryptoSubtle = getWebcryptoSubtle;
//# sourceMappingURL=cryptoNode.js.map

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node_modules/@noble/ciphers/esm/_arx.js generated vendored Normal file
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// Basic utils for ARX (add-rotate-xor) salsa and chacha ciphers.
import { number as anumber, bytes as abytes, bool as abool } from './_assert.js';
import { checkOpts, u32 } from './utils.js';
/*
RFC8439 requires multi-step cipher stream, where
authKey starts with counter: 0, actual msg with counter: 1.
For this, we need a way to re-use nonce / counter:
const counter = new Uint8Array(4);
chacha(..., counter, ...); // counter is now 1
chacha(..., counter, ...); // counter is now 2
This is complicated:
- 32-bit counters are enough, no need for 64-bit: max ArrayBuffer size in JS is 4GB
- Original papers don't allow mutating counters
- Counter overflow is undefined [^1]
- Idea A: allow providing (nonce | counter) instead of just nonce, re-use it
- Caveat: Cannot be re-used through all cases:
- * chacha has (counter | nonce)
- * xchacha has (nonce16 | counter | nonce16)
- Idea B: separate nonce / counter and provide separate API for counter re-use
- Caveat: there are different counter sizes depending on an algorithm.
- salsa & chacha also differ in structures of key & sigma:
salsa20: s[0] | k(4) | s[1] | nonce(2) | ctr(2) | s[2] | k(4) | s[3]
chacha: s(4) | k(8) | ctr(1) | nonce(3)
chacha20orig: s(4) | k(8) | ctr(2) | nonce(2)
- Idea C: helper method such as `setSalsaState(key, nonce, sigma, data)`
- Caveat: we can't re-use counter array
xchacha [^2] uses the subkey and remaining 8 byte nonce with ChaCha20 as normal
(prefixed by 4 NUL bytes, since [RFC8439] specifies a 12-byte nonce).
[^1]: https://mailarchive.ietf.org/arch/msg/cfrg/gsOnTJzcbgG6OqD8Sc0GO5aR_tU/
[^2]: https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha#appendix-A.2
*/
// We can't make top-level var depend on utils.utf8ToBytes
// because it's not present in all envs. Creating a similar fn here
const _utf8ToBytes = (str) => Uint8Array.from(str.split('').map((c) => c.charCodeAt(0)));
const sigma16 = _utf8ToBytes('expand 16-byte k');
const sigma32 = _utf8ToBytes('expand 32-byte k');
const sigma16_32 = u32(sigma16);
const sigma32_32 = u32(sigma32);
export const sigma = sigma32_32.slice();
export function rotl(a, b) {
return (a << b) | (a >>> (32 - b));
}
// Is byte array aligned to 4 byte offset (u32)?
function isAligned32(b) {
return b.byteOffset % 4 === 0;
}
// Salsa and Chacha block length is always 512-bit
const BLOCK_LEN = 64;
const BLOCK_LEN32 = 16;
// new Uint32Array([2**32]) // => Uint32Array(1) [ 0 ]
// new Uint32Array([2**32-1]) // => Uint32Array(1) [ 4294967295 ]
const MAX_COUNTER = 2 ** 32 - 1;
const U32_EMPTY = new Uint32Array();
function runCipher(core, sigma, key, nonce, data, output, counter, rounds) {
const len = data.length;
const block = new Uint8Array(BLOCK_LEN);
const b32 = u32(block);
// Make sure that buffers aligned to 4 bytes
const isAligned = isAligned32(data) && isAligned32(output);
const d32 = isAligned ? u32(data) : U32_EMPTY;
const o32 = isAligned ? u32(output) : U32_EMPTY;
for (let pos = 0; pos < len; counter++) {
core(sigma, key, nonce, b32, counter, rounds);
if (counter >= MAX_COUNTER)
throw new Error('arx: counter overflow');
const take = Math.min(BLOCK_LEN, len - pos);
// aligned to 4 bytes
if (isAligned && take === BLOCK_LEN) {
const pos32 = pos / 4;
if (pos % 4 !== 0)
throw new Error('arx: invalid block position');
for (let j = 0, posj; j < BLOCK_LEN32; j++) {
posj = pos32 + j;
o32[posj] = d32[posj] ^ b32[j];
}
pos += BLOCK_LEN;
continue;
}
for (let j = 0, posj; j < take; j++) {
posj = pos + j;
output[posj] = data[posj] ^ block[j];
}
pos += take;
}
}
export function createCipher(core, opts) {
const { allowShortKeys, extendNonceFn, counterLength, counterRight, rounds } = checkOpts({ allowShortKeys: false, counterLength: 8, counterRight: false, rounds: 20 }, opts);
if (typeof core !== 'function')
throw new Error('core must be a function');
anumber(counterLength);
anumber(rounds);
abool(counterRight);
abool(allowShortKeys);
return (key, nonce, data, output, counter = 0) => {
abytes(key);
abytes(nonce);
abytes(data);
const len = data.length;
if (!output)
output = new Uint8Array(len);
abytes(output);
anumber(counter);
if (counter < 0 || counter >= MAX_COUNTER)
throw new Error('arx: counter overflow');
if (output.length < len)
throw new Error(`arx: output (${output.length}) is shorter than data (${len})`);
const toClean = [];
// Key & sigma
// key=16 -> sigma16, k=key|key
// key=32 -> sigma32, k=key
let l = key.length, k, sigma;
if (l === 32) {
k = key.slice();
toClean.push(k);
sigma = sigma32_32;
}
else if (l === 16 && allowShortKeys) {
k = new Uint8Array(32);
k.set(key);
k.set(key, 16);
sigma = sigma16_32;
toClean.push(k);
}
else {
throw new Error(`arx: invalid 32-byte key, got length=${l}`);
}
// Nonce
// salsa20: 8 (8-byte counter)
// chacha20orig: 8 (8-byte counter)
// chacha20: 12 (4-byte counter)
// xsalsa20: 24 (16 -> hsalsa, 8 -> old nonce)
// xchacha20: 24 (16 -> hchacha, 8 -> old nonce)
// Align nonce to 4 bytes
if (!isAligned32(nonce)) {
nonce = nonce.slice();
toClean.push(nonce);
}
const k32 = u32(k);
// hsalsa & hchacha: handle extended nonce
if (extendNonceFn) {
if (nonce.length !== 24)
throw new Error(`arx: extended nonce must be 24 bytes`);
extendNonceFn(sigma, k32, u32(nonce.subarray(0, 16)), k32);
nonce = nonce.subarray(16);
}
// Handle nonce counter
const nonceNcLen = 16 - counterLength;
if (nonceNcLen !== nonce.length)
throw new Error(`arx: nonce must be ${nonceNcLen} or 16 bytes`);
// Pad counter when nonce is 64 bit
if (nonceNcLen !== 12) {
const nc = new Uint8Array(12);
nc.set(nonce, counterRight ? 0 : 12 - nonce.length);
nonce = nc;
toClean.push(nonce);
}
const n32 = u32(nonce);
runCipher(core, sigma, k32, n32, data, output, counter, rounds);
while (toClean.length > 0)
toClean.pop().fill(0);
return output;
};
}
//# sourceMappingURL=_arx.js.map

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node_modules/@noble/ciphers/esm/_assert.js generated vendored Normal file
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function number(n) {
if (!Number.isSafeInteger(n) || n < 0)
throw new Error(`positive integer expected, not ${n}`);
}
function bool(b) {
if (typeof b !== 'boolean')
throw new Error(`boolean expected, not ${b}`);
}
export function isBytes(a) {
return (a instanceof Uint8Array ||
(a != null && typeof a === 'object' && a.constructor.name === 'Uint8Array'));
}
function bytes(b, ...lengths) {
if (!isBytes(b))
throw new Error('Uint8Array expected');
if (lengths.length > 0 && !lengths.includes(b.length))
throw new Error(`Uint8Array expected of length ${lengths}, not of length=${b.length}`);
}
function hash(hash) {
if (typeof hash !== 'function' || typeof hash.create !== 'function')
throw new Error('hash must be wrapped by utils.wrapConstructor');
number(hash.outputLen);
number(hash.blockLen);
}
function exists(instance, checkFinished = true) {
if (instance.destroyed)
throw new Error('Hash instance has been destroyed');
if (checkFinished && instance.finished)
throw new Error('Hash#digest() has already been called');
}
function output(out, instance) {
bytes(out);
const min = instance.outputLen;
if (out.length < min) {
throw new Error(`digestInto() expects output buffer of length at least ${min}`);
}
}
export { number, bool, bytes, hash, exists, output };
const assert = { number, bool, bytes, hash, exists, output };
export default assert;
//# sourceMappingURL=_assert.js.map

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node_modules/@noble/ciphers/esm/_micro.js generated vendored Normal file
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/*! noble-ciphers - MIT License (c) 2023 Paul Miller (paulmillr.com) */
// prettier-ignore
import { createView, setBigUint64, wrapCipher, bytesToHex, concatBytes, equalBytes, hexToNumber, numberToBytesBE, } from './utils.js';
import { createCipher, rotl } from './_arx.js';
import { bytes as abytes } from './_assert.js';
/*
noble-ciphers-micro: more auditable, but slower version of salsa20, chacha & poly1305.
Implements the same algorithms that are present in other files, but without
unrolled loops (https://en.wikipedia.org/wiki/Loop_unrolling).
*/
function bytesToNumberLE(bytes) {
return hexToNumber(bytesToHex(Uint8Array.from(bytes).reverse()));
}
function numberToBytesLE(n, len) {
return numberToBytesBE(n, len).reverse();
}
function salsaQR(x, a, b, c, d) {
x[b] ^= rotl((x[a] + x[d]) | 0, 7);
x[c] ^= rotl((x[b] + x[a]) | 0, 9);
x[d] ^= rotl((x[c] + x[b]) | 0, 13);
x[a] ^= rotl((x[d] + x[c]) | 0, 18);
}
// prettier-ignore
function chachaQR(x, a, b, c, d) {
x[a] = (x[a] + x[b]) | 0;
x[d] = rotl(x[d] ^ x[a], 16);
x[c] = (x[c] + x[d]) | 0;
x[b] = rotl(x[b] ^ x[c], 12);
x[a] = (x[a] + x[b]) | 0;
x[d] = rotl(x[d] ^ x[a], 8);
x[c] = (x[c] + x[d]) | 0;
x[b] = rotl(x[b] ^ x[c], 7);
}
function salsaRound(x, rounds = 20) {
for (let r = 0; r < rounds; r += 2) {
salsaQR(x, 0, 4, 8, 12);
salsaQR(x, 5, 9, 13, 1);
salsaQR(x, 10, 14, 2, 6);
salsaQR(x, 15, 3, 7, 11);
salsaQR(x, 0, 1, 2, 3);
salsaQR(x, 5, 6, 7, 4);
salsaQR(x, 10, 11, 8, 9);
salsaQR(x, 15, 12, 13, 14);
}
}
function chachaRound(x, rounds = 20) {
for (let r = 0; r < rounds; r += 2) {
chachaQR(x, 0, 4, 8, 12);
chachaQR(x, 1, 5, 9, 13);
chachaQR(x, 2, 6, 10, 14);
chachaQR(x, 3, 7, 11, 15);
chachaQR(x, 0, 5, 10, 15);
chachaQR(x, 1, 6, 11, 12);
chachaQR(x, 2, 7, 8, 13);
chachaQR(x, 3, 4, 9, 14);
}
}
function salsaCore(s, k, n, out, cnt, rounds = 20) {
// prettier-ignore
const y = new Uint32Array([
s[0], k[0], k[1], k[2], // "expa" Key Key Key
k[3], s[1], n[0], n[1], // Key "nd 3" Nonce Nonce
cnt, 0, s[2], k[4], // Pos. Pos. "2-by" Key
k[5], k[6], k[7], s[3], // Key Key Key "te k"
]);
const x = y.slice();
salsaRound(x, rounds);
for (let i = 0; i < 16; i++)
out[i] = (y[i] + x[i]) | 0;
}
// prettier-ignore
export function hsalsa(s, k, i, o32) {
const x = new Uint32Array([
s[0], k[0], k[1], k[2],
k[3], s[1], i[0], i[1],
i[2], i[3], s[2], k[4],
k[5], k[6], k[7], s[3]
]);
salsaRound(x, 20);
let oi = 0;
o32[oi++] = x[0];
o32[oi++] = x[5];
o32[oi++] = x[10];
o32[oi++] = x[15];
o32[oi++] = x[6];
o32[oi++] = x[7];
o32[oi++] = x[8];
o32[oi++] = x[9];
}
function chachaCore(s, k, n, out, cnt, rounds = 20) {
// prettier-ignore
const y = new Uint32Array([
s[0], s[1], s[2], s[3], // "expa" "nd 3" "2-by" "te k"
k[0], k[1], k[2], k[3], // Key Key Key Key
k[4], k[5], k[6], k[7], // Key Key Key Key
cnt, n[0], n[1], n[2], // Counter Counter Nonce Nonce
]);
const x = y.slice();
chachaRound(x, rounds);
for (let i = 0; i < 16; i++)
out[i] = (y[i] + x[i]) | 0;
}
// prettier-ignore
export function hchacha(s, k, i, o32) {
const x = new Uint32Array([
s[0], s[1], s[2], s[3],
k[0], k[1], k[2], k[3],
k[4], k[5], k[6], k[7],
i[0], i[1], i[2], i[3],
]);
chachaRound(x, 20);
let oi = 0;
o32[oi++] = x[0];
o32[oi++] = x[1];
o32[oi++] = x[2];
o32[oi++] = x[3];
o32[oi++] = x[12];
o32[oi++] = x[13];
o32[oi++] = x[14];
o32[oi++] = x[15];
}
/**
* salsa20, 12-byte nonce.
*/
export const salsa20 = /* @__PURE__ */ createCipher(salsaCore, {
allowShortKeys: true,
counterRight: true,
});
/**
* xsalsa20, 24-byte nonce.
*/
export const xsalsa20 = /* @__PURE__ */ createCipher(salsaCore, {
counterRight: true,
extendNonceFn: hsalsa,
});
/**
* chacha20 non-RFC, original version by djb. 8-byte nonce, 8-byte counter.
*/
export const chacha20orig = /* @__PURE__ */ createCipher(chachaCore, {
allowShortKeys: true,
counterRight: false,
counterLength: 8,
});
/**
* chacha20 RFC 8439 (IETF / TLS). 12-byte nonce, 4-byte counter.
*/
export const chacha20 = /* @__PURE__ */ createCipher(chachaCore, {
counterRight: false,
counterLength: 4,
});
/**
* xchacha20 eXtended-nonce. https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha
*/
export const xchacha20 = /* @__PURE__ */ createCipher(chachaCore, {
counterRight: false,
counterLength: 8,
extendNonceFn: hchacha,
});
/**
* 8-round chacha from the original paper.
*/
export const chacha8 = /* @__PURE__ */ createCipher(chachaCore, {
counterRight: false,
counterLength: 4,
rounds: 8,
});
/**
* 12-round chacha from the original paper.
*/
export const chacha12 = /* @__PURE__ */ createCipher(chachaCore, {
counterRight: false,
counterLength: 4,
rounds: 12,
});
const POW_2_130_5 = BigInt(2) ** BigInt(130) - BigInt(5);
const POW_2_128_1 = BigInt(2) ** BigInt(16 * 8) - BigInt(1);
const CLAMP_R = BigInt('0x0ffffffc0ffffffc0ffffffc0fffffff');
const _0 = BigInt(0);
const _1 = BigInt(1);
// Can be speed-up using BigUint64Array, but would be more complicated
export function poly1305(msg, key) {
abytes(msg);
abytes(key);
let acc = _0;
const r = bytesToNumberLE(key.subarray(0, 16)) & CLAMP_R;
const s = bytesToNumberLE(key.subarray(16));
// Process by 16 byte chunks
for (let i = 0; i < msg.length; i += 16) {
const m = msg.subarray(i, i + 16);
const n = bytesToNumberLE(m) | (_1 << BigInt(8 * m.length));
acc = ((acc + n) * r) % POW_2_130_5;
}
const res = (acc + s) & POW_2_128_1;
return numberToBytesLE(res, 16);
}
function computeTag(fn, key, nonce, ciphertext, AAD) {
const res = [];
if (AAD) {
res.push(AAD);
const leftover = AAD.length % 16;
if (leftover > 0)
res.push(new Uint8Array(16 - leftover));
}
res.push(ciphertext);
const leftover = ciphertext.length % 16;
if (leftover > 0)
res.push(new Uint8Array(16 - leftover));
// Lengths
const num = new Uint8Array(16);
const view = createView(num);
setBigUint64(view, 0, BigInt(AAD ? AAD.length : 0), true);
setBigUint64(view, 8, BigInt(ciphertext.length), true);
res.push(num);
const authKey = fn(key, nonce, new Uint8Array(32));
return poly1305(concatBytes(...res), authKey);
}
/**
* xsalsa20-poly1305 eXtended-nonce (24 bytes) salsa.
*/
export const xsalsa20poly1305 = /* @__PURE__ */ wrapCipher({ blockSize: 64, nonceLength: 24, tagLength: 16 }, function xsalsa20poly1305(key, nonce) {
abytes(key);
abytes(nonce);
return {
encrypt: (plaintext) => {
abytes(plaintext);
const m = concatBytes(new Uint8Array(32), plaintext);
const c = xsalsa20(key, nonce, m);
const authKey = c.subarray(0, 32);
const data = c.subarray(32);
const tag = poly1305(data, authKey);
return concatBytes(tag, data);
},
decrypt: (ciphertext) => {
abytes(ciphertext);
if (ciphertext.length < 16)
throw new Error('encrypted data must be at least 16 bytes');
const c = concatBytes(new Uint8Array(16), ciphertext);
const authKey = xsalsa20(key, nonce, new Uint8Array(32));
const tag = poly1305(c.subarray(32), authKey);
if (!equalBytes(c.subarray(16, 32), tag))
throw new Error('invalid poly1305 tag');
return xsalsa20(key, nonce, c).subarray(32);
},
};
});
/**
* Alias to xsalsa20-poly1305
*/
export function secretbox(key, nonce) {
const xs = xsalsa20poly1305(key, nonce);
return { seal: xs.encrypt, open: xs.decrypt };
}
export const _poly1305_aead = (fn) => (key, nonce, AAD) => {
const tagLength = 16;
const keyLength = 32;
abytes(key, keyLength);
abytes(nonce);
return {
encrypt: (plaintext) => {
abytes(plaintext);
const res = fn(key, nonce, plaintext, undefined, 1);
const tag = computeTag(fn, key, nonce, res, AAD);
return concatBytes(res, tag);
},
decrypt: (ciphertext) => {
abytes(ciphertext);
if (ciphertext.length < tagLength)
throw new Error(`encrypted data must be at least ${tagLength} bytes`);
const passedTag = ciphertext.subarray(-tagLength);
const data = ciphertext.subarray(0, -tagLength);
const tag = computeTag(fn, key, nonce, data, AAD);
if (!equalBytes(passedTag, tag))
throw new Error('invalid poly1305 tag');
return fn(key, nonce, data, undefined, 1);
},
};
};
/**
* chacha20-poly1305 12-byte-nonce chacha.
*/
export const chacha20poly1305 = /* @__PURE__ */ wrapCipher({ blockSize: 64, nonceLength: 12, tagLength: 16 }, _poly1305_aead(chacha20));
/**
* xchacha20-poly1305 eXtended-nonce (24 bytes) chacha.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
*/
export const xchacha20poly1305 = /* @__PURE__ */ wrapCipher({ blockSize: 64, nonceLength: 24, tagLength: 16 }, _poly1305_aead(xchacha20));
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import { exists as aexists, bytes as abytes, output as aoutput } from './_assert.js';
import { toBytes } from './utils.js';
// Poly1305 is a fast and parallel secret-key message-authentication code.
// https://cr.yp.to/mac.html, https://cr.yp.to/mac/poly1305-20050329.pdf
// https://datatracker.ietf.org/doc/html/rfc8439
// Based on Public Domain poly1305-donna https://github.com/floodyberry/poly1305-donna
const u8to16 = (a, i) => (a[i++] & 0xff) | ((a[i++] & 0xff) << 8);
class Poly1305 {
constructor(key) {
this.blockLen = 16;
this.outputLen = 16;
this.buffer = new Uint8Array(16);
this.r = new Uint16Array(10);
this.h = new Uint16Array(10);
this.pad = new Uint16Array(8);
this.pos = 0;
this.finished = false;
key = toBytes(key);
abytes(key, 32);
const t0 = u8to16(key, 0);
const t1 = u8to16(key, 2);
const t2 = u8to16(key, 4);
const t3 = u8to16(key, 6);
const t4 = u8to16(key, 8);
const t5 = u8to16(key, 10);
const t6 = u8to16(key, 12);
const t7 = u8to16(key, 14);
// https://github.com/floodyberry/poly1305-donna/blob/e6ad6e091d30d7f4ec2d4f978be1fcfcbce72781/poly1305-donna-16.h#L47
this.r[0] = t0 & 0x1fff;
this.r[1] = ((t0 >>> 13) | (t1 << 3)) & 0x1fff;
this.r[2] = ((t1 >>> 10) | (t2 << 6)) & 0x1f03;
this.r[3] = ((t2 >>> 7) | (t3 << 9)) & 0x1fff;
this.r[4] = ((t3 >>> 4) | (t4 << 12)) & 0x00ff;
this.r[5] = (t4 >>> 1) & 0x1ffe;
this.r[6] = ((t4 >>> 14) | (t5 << 2)) & 0x1fff;
this.r[7] = ((t5 >>> 11) | (t6 << 5)) & 0x1f81;
this.r[8] = ((t6 >>> 8) | (t7 << 8)) & 0x1fff;
this.r[9] = (t7 >>> 5) & 0x007f;
for (let i = 0; i < 8; i++)
this.pad[i] = u8to16(key, 16 + 2 * i);
}
process(data, offset, isLast = false) {
const hibit = isLast ? 0 : 1 << 11;
const { h, r } = this;
const r0 = r[0];
const r1 = r[1];
const r2 = r[2];
const r3 = r[3];
const r4 = r[4];
const r5 = r[5];
const r6 = r[6];
const r7 = r[7];
const r8 = r[8];
const r9 = r[9];
const t0 = u8to16(data, offset + 0);
const t1 = u8to16(data, offset + 2);
const t2 = u8to16(data, offset + 4);
const t3 = u8to16(data, offset + 6);
const t4 = u8to16(data, offset + 8);
const t5 = u8to16(data, offset + 10);
const t6 = u8to16(data, offset + 12);
const t7 = u8to16(data, offset + 14);
let h0 = h[0] + (t0 & 0x1fff);
let h1 = h[1] + (((t0 >>> 13) | (t1 << 3)) & 0x1fff);
let h2 = h[2] + (((t1 >>> 10) | (t2 << 6)) & 0x1fff);
let h3 = h[3] + (((t2 >>> 7) | (t3 << 9)) & 0x1fff);
let h4 = h[4] + (((t3 >>> 4) | (t4 << 12)) & 0x1fff);
let h5 = h[5] + ((t4 >>> 1) & 0x1fff);
let h6 = h[6] + (((t4 >>> 14) | (t5 << 2)) & 0x1fff);
let h7 = h[7] + (((t5 >>> 11) | (t6 << 5)) & 0x1fff);
let h8 = h[8] + (((t6 >>> 8) | (t7 << 8)) & 0x1fff);
let h9 = h[9] + ((t7 >>> 5) | hibit);
let c = 0;
let d0 = c + h0 * r0 + h1 * (5 * r9) + h2 * (5 * r8) + h3 * (5 * r7) + h4 * (5 * r6);
c = d0 >>> 13;
d0 &= 0x1fff;
d0 += h5 * (5 * r5) + h6 * (5 * r4) + h7 * (5 * r3) + h8 * (5 * r2) + h9 * (5 * r1);
c += d0 >>> 13;
d0 &= 0x1fff;
let d1 = c + h0 * r1 + h1 * r0 + h2 * (5 * r9) + h3 * (5 * r8) + h4 * (5 * r7);
c = d1 >>> 13;
d1 &= 0x1fff;
d1 += h5 * (5 * r6) + h6 * (5 * r5) + h7 * (5 * r4) + h8 * (5 * r3) + h9 * (5 * r2);
c += d1 >>> 13;
d1 &= 0x1fff;
let d2 = c + h0 * r2 + h1 * r1 + h2 * r0 + h3 * (5 * r9) + h4 * (5 * r8);
c = d2 >>> 13;
d2 &= 0x1fff;
d2 += h5 * (5 * r7) + h6 * (5 * r6) + h7 * (5 * r5) + h8 * (5 * r4) + h9 * (5 * r3);
c += d2 >>> 13;
d2 &= 0x1fff;
let d3 = c + h0 * r3 + h1 * r2 + h2 * r1 + h3 * r0 + h4 * (5 * r9);
c = d3 >>> 13;
d3 &= 0x1fff;
d3 += h5 * (5 * r8) + h6 * (5 * r7) + h7 * (5 * r6) + h8 * (5 * r5) + h9 * (5 * r4);
c += d3 >>> 13;
d3 &= 0x1fff;
let d4 = c + h0 * r4 + h1 * r3 + h2 * r2 + h3 * r1 + h4 * r0;
c = d4 >>> 13;
d4 &= 0x1fff;
d4 += h5 * (5 * r9) + h6 * (5 * r8) + h7 * (5 * r7) + h8 * (5 * r6) + h9 * (5 * r5);
c += d4 >>> 13;
d4 &= 0x1fff;
let d5 = c + h0 * r5 + h1 * r4 + h2 * r3 + h3 * r2 + h4 * r1;
c = d5 >>> 13;
d5 &= 0x1fff;
d5 += h5 * r0 + h6 * (5 * r9) + h7 * (5 * r8) + h8 * (5 * r7) + h9 * (5 * r6);
c += d5 >>> 13;
d5 &= 0x1fff;
let d6 = c + h0 * r6 + h1 * r5 + h2 * r4 + h3 * r3 + h4 * r2;
c = d6 >>> 13;
d6 &= 0x1fff;
d6 += h5 * r1 + h6 * r0 + h7 * (5 * r9) + h8 * (5 * r8) + h9 * (5 * r7);
c += d6 >>> 13;
d6 &= 0x1fff;
let d7 = c + h0 * r7 + h1 * r6 + h2 * r5 + h3 * r4 + h4 * r3;
c = d7 >>> 13;
d7 &= 0x1fff;
d7 += h5 * r2 + h6 * r1 + h7 * r0 + h8 * (5 * r9) + h9 * (5 * r8);
c += d7 >>> 13;
d7 &= 0x1fff;
let d8 = c + h0 * r8 + h1 * r7 + h2 * r6 + h3 * r5 + h4 * r4;
c = d8 >>> 13;
d8 &= 0x1fff;
d8 += h5 * r3 + h6 * r2 + h7 * r1 + h8 * r0 + h9 * (5 * r9);
c += d8 >>> 13;
d8 &= 0x1fff;
let d9 = c + h0 * r9 + h1 * r8 + h2 * r7 + h3 * r6 + h4 * r5;
c = d9 >>> 13;
d9 &= 0x1fff;
d9 += h5 * r4 + h6 * r3 + h7 * r2 + h8 * r1 + h9 * r0;
c += d9 >>> 13;
d9 &= 0x1fff;
c = ((c << 2) + c) | 0;
c = (c + d0) | 0;
d0 = c & 0x1fff;
c = c >>> 13;
d1 += c;
h[0] = d0;
h[1] = d1;
h[2] = d2;
h[3] = d3;
h[4] = d4;
h[5] = d5;
h[6] = d6;
h[7] = d7;
h[8] = d8;
h[9] = d9;
}
finalize() {
const { h, pad } = this;
const g = new Uint16Array(10);
let c = h[1] >>> 13;
h[1] &= 0x1fff;
for (let i = 2; i < 10; i++) {
h[i] += c;
c = h[i] >>> 13;
h[i] &= 0x1fff;
}
h[0] += c * 5;
c = h[0] >>> 13;
h[0] &= 0x1fff;
h[1] += c;
c = h[1] >>> 13;
h[1] &= 0x1fff;
h[2] += c;
g[0] = h[0] + 5;
c = g[0] >>> 13;
g[0] &= 0x1fff;
for (let i = 1; i < 10; i++) {
g[i] = h[i] + c;
c = g[i] >>> 13;
g[i] &= 0x1fff;
}
g[9] -= 1 << 13;
let mask = (c ^ 1) - 1;
for (let i = 0; i < 10; i++)
g[i] &= mask;
mask = ~mask;
for (let i = 0; i < 10; i++)
h[i] = (h[i] & mask) | g[i];
h[0] = (h[0] | (h[1] << 13)) & 0xffff;
h[1] = ((h[1] >>> 3) | (h[2] << 10)) & 0xffff;
h[2] = ((h[2] >>> 6) | (h[3] << 7)) & 0xffff;
h[3] = ((h[3] >>> 9) | (h[4] << 4)) & 0xffff;
h[4] = ((h[4] >>> 12) | (h[5] << 1) | (h[6] << 14)) & 0xffff;
h[5] = ((h[6] >>> 2) | (h[7] << 11)) & 0xffff;
h[6] = ((h[7] >>> 5) | (h[8] << 8)) & 0xffff;
h[7] = ((h[8] >>> 8) | (h[9] << 5)) & 0xffff;
let f = h[0] + pad[0];
h[0] = f & 0xffff;
for (let i = 1; i < 8; i++) {
f = (((h[i] + pad[i]) | 0) + (f >>> 16)) | 0;
h[i] = f & 0xffff;
}
}
update(data) {
aexists(this);
const { buffer, blockLen } = this;
data = toBytes(data);
const len = data.length;
for (let pos = 0; pos < len;) {
const take = Math.min(blockLen - this.pos, len - pos);
// Fast path: we have at least one block in input
if (take === blockLen) {
for (; blockLen <= len - pos; pos += blockLen)
this.process(data, pos);
continue;
}
buffer.set(data.subarray(pos, pos + take), this.pos);
this.pos += take;
pos += take;
if (this.pos === blockLen) {
this.process(buffer, 0, false);
this.pos = 0;
}
}
return this;
}
destroy() {
this.h.fill(0);
this.r.fill(0);
this.buffer.fill(0);
this.pad.fill(0);
}
digestInto(out) {
aexists(this);
aoutput(out, this);
this.finished = true;
const { buffer, h } = this;
let { pos } = this;
if (pos) {
buffer[pos++] = 1;
// buffer.subarray(pos).fill(0);
for (; pos < 16; pos++)
buffer[pos] = 0;
this.process(buffer, 0, true);
}
this.finalize();
let opos = 0;
for (let i = 0; i < 8; i++) {
out[opos++] = h[i] >>> 0;
out[opos++] = h[i] >>> 8;
}
return out;
}
digest() {
const { buffer, outputLen } = this;
this.digestInto(buffer);
const res = buffer.slice(0, outputLen);
this.destroy();
return res;
}
}
export function wrapConstructorWithKey(hashCons) {
const hashC = (msg, key) => hashCons(key).update(toBytes(msg)).digest();
const tmp = hashCons(new Uint8Array(32));
hashC.outputLen = tmp.outputLen;
hashC.blockLen = tmp.blockLen;
hashC.create = (key) => hashCons(key);
return hashC;
}
export const poly1305 = wrapConstructorWithKey((key) => new Poly1305(key));
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import { createView, toBytes, u32 } from './utils.js';
import { bytes as abytes, exists as aexists, output as aoutput } from './_assert.js';
// GHash from AES-GCM and its little-endian "mirror image" Polyval from AES-SIV.
// Implemented in terms of GHash with conversion function for keys
// GCM GHASH from NIST SP800-38d, SIV from RFC 8452.
// https://nvlpubs.nist.gov/nistpubs/Legacy/SP/nistspecialpublication800-38d.pdf
// GHASH modulo: x^128 + x^7 + x^2 + x + 1
// POLYVAL modulo: x^128 + x^127 + x^126 + x^121 + 1
const BLOCK_SIZE = 16;
// TODO: rewrite
// temporary padding buffer
const ZEROS16 = /* @__PURE__ */ new Uint8Array(16);
const ZEROS32 = u32(ZEROS16);
const POLY = 0xe1; // v = 2*v % POLY
// v = 2*v % POLY
// NOTE: because x + x = 0 (add/sub is same), mul2(x) != x+x
// We can multiply any number using montgomery ladder and this function (works as double, add is simple xor)
const mul2 = (s0, s1, s2, s3) => {
const hiBit = s3 & 1;
return {
s3: (s2 << 31) | (s3 >>> 1),
s2: (s1 << 31) | (s2 >>> 1),
s1: (s0 << 31) | (s1 >>> 1),
s0: (s0 >>> 1) ^ ((POLY << 24) & -(hiBit & 1)), // reduce % poly
};
};
const swapLE = (n) => (((n >>> 0) & 0xff) << 24) |
(((n >>> 8) & 0xff) << 16) |
(((n >>> 16) & 0xff) << 8) |
((n >>> 24) & 0xff) |
0;
/**
* `mulX_POLYVAL(ByteReverse(H))` from spec
* @param k mutated in place
*/
export function _toGHASHKey(k) {
k.reverse();
const hiBit = k[15] & 1;
// k >>= 1
let carry = 0;
for (let i = 0; i < k.length; i++) {
const t = k[i];
k[i] = (t >>> 1) | carry;
carry = (t & 1) << 7;
}
k[0] ^= -hiBit & 0xe1; // if (hiBit) n ^= 0xe1000000000000000000000000000000;
return k;
}
const estimateWindow = (bytes) => {
if (bytes > 64 * 1024)
return 8;
if (bytes > 1024)
return 4;
return 2;
};
class GHASH {
// We select bits per window adaptively based on expectedLength
constructor(key, expectedLength) {
this.blockLen = BLOCK_SIZE;
this.outputLen = BLOCK_SIZE;
this.s0 = 0;
this.s1 = 0;
this.s2 = 0;
this.s3 = 0;
this.finished = false;
key = toBytes(key);
abytes(key, 16);
const kView = createView(key);
let k0 = kView.getUint32(0, false);
let k1 = kView.getUint32(4, false);
let k2 = kView.getUint32(8, false);
let k3 = kView.getUint32(12, false);
// generate table of doubled keys (half of montgomery ladder)
const doubles = [];
for (let i = 0; i < 128; i++) {
doubles.push({ s0: swapLE(k0), s1: swapLE(k1), s2: swapLE(k2), s3: swapLE(k3) });
({ s0: k0, s1: k1, s2: k2, s3: k3 } = mul2(k0, k1, k2, k3));
}
const W = estimateWindow(expectedLength || 1024);
if (![1, 2, 4, 8].includes(W))
throw new Error(`ghash: wrong window size=${W}, should be 2, 4 or 8`);
this.W = W;
const bits = 128; // always 128 bits;
const windows = bits / W;
const windowSize = (this.windowSize = 2 ** W);
const items = [];
// Create precompute table for window of W bits
for (let w = 0; w < windows; w++) {
// truth table: 00, 01, 10, 11
for (let byte = 0; byte < windowSize; byte++) {
// prettier-ignore
let s0 = 0, s1 = 0, s2 = 0, s3 = 0;
for (let j = 0; j < W; j++) {
const bit = (byte >>> (W - j - 1)) & 1;
if (!bit)
continue;
const { s0: d0, s1: d1, s2: d2, s3: d3 } = doubles[W * w + j];
(s0 ^= d0), (s1 ^= d1), (s2 ^= d2), (s3 ^= d3);
}
items.push({ s0, s1, s2, s3 });
}
}
this.t = items;
}
_updateBlock(s0, s1, s2, s3) {
(s0 ^= this.s0), (s1 ^= this.s1), (s2 ^= this.s2), (s3 ^= this.s3);
const { W, t, windowSize } = this;
// prettier-ignore
let o0 = 0, o1 = 0, o2 = 0, o3 = 0;
const mask = (1 << W) - 1; // 2**W will kill performance.
let w = 0;
for (const num of [s0, s1, s2, s3]) {
for (let bytePos = 0; bytePos < 4; bytePos++) {
const byte = (num >>> (8 * bytePos)) & 0xff;
for (let bitPos = 8 / W - 1; bitPos >= 0; bitPos--) {
const bit = (byte >>> (W * bitPos)) & mask;
const { s0: e0, s1: e1, s2: e2, s3: e3 } = t[w * windowSize + bit];
(o0 ^= e0), (o1 ^= e1), (o2 ^= e2), (o3 ^= e3);
w += 1;
}
}
}
this.s0 = o0;
this.s1 = o1;
this.s2 = o2;
this.s3 = o3;
}
update(data) {
data = toBytes(data);
aexists(this);
const b32 = u32(data);
const blocks = Math.floor(data.length / BLOCK_SIZE);
const left = data.length % BLOCK_SIZE;
for (let i = 0; i < blocks; i++) {
this._updateBlock(b32[i * 4 + 0], b32[i * 4 + 1], b32[i * 4 + 2], b32[i * 4 + 3]);
}
if (left) {
ZEROS16.set(data.subarray(blocks * BLOCK_SIZE));
this._updateBlock(ZEROS32[0], ZEROS32[1], ZEROS32[2], ZEROS32[3]);
ZEROS32.fill(0); // clean tmp buffer
}
return this;
}
destroy() {
const { t } = this;
// clean precompute table
for (const elm of t) {
(elm.s0 = 0), (elm.s1 = 0), (elm.s2 = 0), (elm.s3 = 0);
}
}
digestInto(out) {
aexists(this);
aoutput(out, this);
this.finished = true;
const { s0, s1, s2, s3 } = this;
const o32 = u32(out);
o32[0] = s0;
o32[1] = s1;
o32[2] = s2;
o32[3] = s3;
return out;
}
digest() {
const res = new Uint8Array(BLOCK_SIZE);
this.digestInto(res);
this.destroy();
return res;
}
}
class Polyval extends GHASH {
constructor(key, expectedLength) {
key = toBytes(key);
const ghKey = _toGHASHKey(key.slice());
super(ghKey, expectedLength);
ghKey.fill(0);
}
update(data) {
data = toBytes(data);
aexists(this);
const b32 = u32(data);
const left = data.length % BLOCK_SIZE;
const blocks = Math.floor(data.length / BLOCK_SIZE);
for (let i = 0; i < blocks; i++) {
this._updateBlock(swapLE(b32[i * 4 + 3]), swapLE(b32[i * 4 + 2]), swapLE(b32[i * 4 + 1]), swapLE(b32[i * 4 + 0]));
}
if (left) {
ZEROS16.set(data.subarray(blocks * BLOCK_SIZE));
this._updateBlock(swapLE(ZEROS32[3]), swapLE(ZEROS32[2]), swapLE(ZEROS32[1]), swapLE(ZEROS32[0]));
ZEROS32.fill(0); // clean tmp buffer
}
return this;
}
digestInto(out) {
aexists(this);
aoutput(out, this);
this.finished = true;
// tmp ugly hack
const { s0, s1, s2, s3 } = this;
const o32 = u32(out);
o32[0] = s0;
o32[1] = s1;
o32[2] = s2;
o32[3] = s3;
return out.reverse();
}
}
function wrapConstructorWithKey(hashCons) {
const hashC = (msg, key) => hashCons(key, msg.length).update(toBytes(msg)).digest();
const tmp = hashCons(new Uint8Array(16), 0);
hashC.outputLen = tmp.outputLen;
hashC.blockLen = tmp.blockLen;
hashC.create = (key, expectedLength) => hashCons(key, expectedLength);
return hashC;
}
export const ghash = wrapConstructorWithKey((key, expectedLength) => new GHASH(key, expectedLength));
export const polyval = wrapConstructorWithKey((key, expectedLength) => new Polyval(key, expectedLength));
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// prettier-ignore
import { wrapCipher, createView, setBigUint64, equalBytes, u32, u8, } from './utils.js';
import { ghash, polyval } from './_polyval.js';
import { bytes as abytes } from './_assert.js';
/*
AES (Advanced Encryption Standard) aka Rijndael block cipher.
Data is split into 128-bit blocks. Encrypted in 10/12/14 rounds (128/192/256 bits). In every round:
1. **S-box**, table substitution
2. **Shift rows**, cyclic shift left of all rows of data array
3. **Mix columns**, multiplying every column by fixed polynomial
4. **Add round key**, round_key xor i-th column of array
Resources:
- FIPS-197 https://csrc.nist.gov/files/pubs/fips/197/final/docs/fips-197.pdf
- Original proposal: https://csrc.nist.gov/csrc/media/projects/cryptographic-standards-and-guidelines/documents/aes-development/rijndael-ammended.pdf
*/
const BLOCK_SIZE = 16;
const BLOCK_SIZE32 = 4;
const EMPTY_BLOCK = new Uint8Array(BLOCK_SIZE);
const POLY = 0x11b; // 1 + x + x**3 + x**4 + x**8
// TODO: remove multiplication, binary ops only
function mul2(n) {
return (n << 1) ^ (POLY & -(n >> 7));
}
function mul(a, b) {
let res = 0;
for (; b > 0; b >>= 1) {
// Montgomery ladder
res ^= a & -(b & 1); // if (b&1) res ^=a (but const-time).
a = mul2(a); // a = 2*a
}
return res;
}
// AES S-box is generated using finite field inversion,
// an affine transform, and xor of a constant 0x63.
const sbox = /* @__PURE__ */ (() => {
let t = new Uint8Array(256);
for (let i = 0, x = 1; i < 256; i++, x ^= mul2(x))
t[i] = x;
const box = new Uint8Array(256);
box[0] = 0x63; // first elm
for (let i = 0; i < 255; i++) {
let x = t[255 - i];
x |= x << 8;
box[t[i]] = (x ^ (x >> 4) ^ (x >> 5) ^ (x >> 6) ^ (x >> 7) ^ 0x63) & 0xff;
}
return box;
})();
// Inverted S-box
const invSbox = /* @__PURE__ */ sbox.map((_, j) => sbox.indexOf(j));
// Rotate u32 by 8
const rotr32_8 = (n) => (n << 24) | (n >>> 8);
const rotl32_8 = (n) => (n << 8) | (n >>> 24);
// T-table is optimization suggested in 5.2 of original proposal (missed from FIPS-197). Changes:
// - LE instead of BE
// - bigger tables: T0 and T1 are merged into T01 table and T2 & T3 into T23;
// so index is u16, instead of u8. This speeds up things, unexpectedly
function genTtable(sbox, fn) {
if (sbox.length !== 256)
throw new Error('Wrong sbox length');
const T0 = new Uint32Array(256).map((_, j) => fn(sbox[j]));
const T1 = T0.map(rotl32_8);
const T2 = T1.map(rotl32_8);
const T3 = T2.map(rotl32_8);
const T01 = new Uint32Array(256 * 256);
const T23 = new Uint32Array(256 * 256);
const sbox2 = new Uint16Array(256 * 256);
for (let i = 0; i < 256; i++) {
for (let j = 0; j < 256; j++) {
const idx = i * 256 + j;
T01[idx] = T0[i] ^ T1[j];
T23[idx] = T2[i] ^ T3[j];
sbox2[idx] = (sbox[i] << 8) | sbox[j];
}
}
return { sbox, sbox2, T0, T1, T2, T3, T01, T23 };
}
const tableEncoding = /* @__PURE__ */ genTtable(sbox, (s) => (mul(s, 3) << 24) | (s << 16) | (s << 8) | mul(s, 2));
const tableDecoding = /* @__PURE__ */ genTtable(invSbox, (s) => (mul(s, 11) << 24) | (mul(s, 13) << 16) | (mul(s, 9) << 8) | mul(s, 14));
const xPowers = /* @__PURE__ */ (() => {
const p = new Uint8Array(16);
for (let i = 0, x = 1; i < 16; i++, x = mul2(x))
p[i] = x;
return p;
})();
export function expandKeyLE(key) {
abytes(key);
const len = key.length;
if (![16, 24, 32].includes(len))
throw new Error(`aes: wrong key size: should be 16, 24 or 32, got: ${len}`);
const { sbox2 } = tableEncoding;
const k32 = u32(key);
const Nk = k32.length;
const subByte = (n) => applySbox(sbox2, n, n, n, n);
const xk = new Uint32Array(len + 28); // expanded key
xk.set(k32);
// 4.3.1 Key expansion
for (let i = Nk; i < xk.length; i++) {
let t = xk[i - 1];
if (i % Nk === 0)
t = subByte(rotr32_8(t)) ^ xPowers[i / Nk - 1];
else if (Nk > 6 && i % Nk === 4)
t = subByte(t);
xk[i] = xk[i - Nk] ^ t;
}
return xk;
}
export function expandKeyDecLE(key) {
const encKey = expandKeyLE(key);
const xk = encKey.slice();
const Nk = encKey.length;
const { sbox2 } = tableEncoding;
const { T0, T1, T2, T3 } = tableDecoding;
// Inverse key by chunks of 4 (rounds)
for (let i = 0; i < Nk; i += 4) {
for (let j = 0; j < 4; j++)
xk[i + j] = encKey[Nk - i - 4 + j];
}
encKey.fill(0);
// apply InvMixColumn except first & last round
for (let i = 4; i < Nk - 4; i++) {
const x = xk[i];
const w = applySbox(sbox2, x, x, x, x);
xk[i] = T0[w & 0xff] ^ T1[(w >>> 8) & 0xff] ^ T2[(w >>> 16) & 0xff] ^ T3[w >>> 24];
}
return xk;
}
// Apply tables
function apply0123(T01, T23, s0, s1, s2, s3) {
return (T01[((s0 << 8) & 0xff00) | ((s1 >>> 8) & 0xff)] ^
T23[((s2 >>> 8) & 0xff00) | ((s3 >>> 24) & 0xff)]);
}
function applySbox(sbox2, s0, s1, s2, s3) {
return (sbox2[(s0 & 0xff) | (s1 & 0xff00)] |
(sbox2[((s2 >>> 16) & 0xff) | ((s3 >>> 16) & 0xff00)] << 16));
}
function encrypt(xk, s0, s1, s2, s3) {
const { sbox2, T01, T23 } = tableEncoding;
let k = 0;
(s0 ^= xk[k++]), (s1 ^= xk[k++]), (s2 ^= xk[k++]), (s3 ^= xk[k++]);
const rounds = xk.length / 4 - 2;
for (let i = 0; i < rounds; i++) {
const t0 = xk[k++] ^ apply0123(T01, T23, s0, s1, s2, s3);
const t1 = xk[k++] ^ apply0123(T01, T23, s1, s2, s3, s0);
const t2 = xk[k++] ^ apply0123(T01, T23, s2, s3, s0, s1);
const t3 = xk[k++] ^ apply0123(T01, T23, s3, s0, s1, s2);
(s0 = t0), (s1 = t1), (s2 = t2), (s3 = t3);
}
// last round (without mixcolumns, so using SBOX2 table)
const t0 = xk[k++] ^ applySbox(sbox2, s0, s1, s2, s3);
const t1 = xk[k++] ^ applySbox(sbox2, s1, s2, s3, s0);
const t2 = xk[k++] ^ applySbox(sbox2, s2, s3, s0, s1);
const t3 = xk[k++] ^ applySbox(sbox2, s3, s0, s1, s2);
return { s0: t0, s1: t1, s2: t2, s3: t3 };
}
function decrypt(xk, s0, s1, s2, s3) {
const { sbox2, T01, T23 } = tableDecoding;
let k = 0;
(s0 ^= xk[k++]), (s1 ^= xk[k++]), (s2 ^= xk[k++]), (s3 ^= xk[k++]);
const rounds = xk.length / 4 - 2;
for (let i = 0; i < rounds; i++) {
const t0 = xk[k++] ^ apply0123(T01, T23, s0, s3, s2, s1);
const t1 = xk[k++] ^ apply0123(T01, T23, s1, s0, s3, s2);
const t2 = xk[k++] ^ apply0123(T01, T23, s2, s1, s0, s3);
const t3 = xk[k++] ^ apply0123(T01, T23, s3, s2, s1, s0);
(s0 = t0), (s1 = t1), (s2 = t2), (s3 = t3);
}
// Last round
const t0 = xk[k++] ^ applySbox(sbox2, s0, s3, s2, s1);
const t1 = xk[k++] ^ applySbox(sbox2, s1, s0, s3, s2);
const t2 = xk[k++] ^ applySbox(sbox2, s2, s1, s0, s3);
const t3 = xk[k++] ^ applySbox(sbox2, s3, s2, s1, s0);
return { s0: t0, s1: t1, s2: t2, s3: t3 };
}
function getDst(len, dst) {
if (!dst)
return new Uint8Array(len);
abytes(dst);
if (dst.length < len)
throw new Error(`aes: wrong destination length, expected at least ${len}, got: ${dst.length}`);
return dst;
}
// TODO: investigate merging with ctr32
function ctrCounter(xk, nonce, src, dst) {
abytes(nonce, BLOCK_SIZE);
abytes(src);
const srcLen = src.length;
dst = getDst(srcLen, dst);
const ctr = nonce;
const c32 = u32(ctr);
// Fill block (empty, ctr=0)
let { s0, s1, s2, s3 } = encrypt(xk, c32[0], c32[1], c32[2], c32[3]);
const src32 = u32(src);
const dst32 = u32(dst);
// process blocks
for (let i = 0; i + 4 <= src32.length; i += 4) {
dst32[i + 0] = src32[i + 0] ^ s0;
dst32[i + 1] = src32[i + 1] ^ s1;
dst32[i + 2] = src32[i + 2] ^ s2;
dst32[i + 3] = src32[i + 3] ^ s3;
// Full 128 bit counter with wrap around
let carry = 1;
for (let i = ctr.length - 1; i >= 0; i--) {
carry = (carry + (ctr[i] & 0xff)) | 0;
ctr[i] = carry & 0xff;
carry >>>= 8;
}
({ s0, s1, s2, s3 } = encrypt(xk, c32[0], c32[1], c32[2], c32[3]));
}
// leftovers (less than block)
// It's possible to handle > u32 fast, but is it worth it?
const start = BLOCK_SIZE * Math.floor(src32.length / BLOCK_SIZE32);
if (start < srcLen) {
const b32 = new Uint32Array([s0, s1, s2, s3]);
const buf = u8(b32);
for (let i = start, pos = 0; i < srcLen; i++, pos++)
dst[i] = src[i] ^ buf[pos];
}
return dst;
}
// AES CTR with overflowing 32 bit counter
// It's possible to do 32le significantly simpler (and probably faster) by using u32.
// But, we need both, and perf bottleneck is in ghash anyway.
function ctr32(xk, isLE, nonce, src, dst) {
abytes(nonce, BLOCK_SIZE);
abytes(src);
dst = getDst(src.length, dst);
const ctr = nonce; // write new value to nonce, so it can be re-used
const c32 = u32(ctr);
const view = createView(ctr);
const src32 = u32(src);
const dst32 = u32(dst);
const ctrPos = isLE ? 0 : 12;
const srcLen = src.length;
// Fill block (empty, ctr=0)
let ctrNum = view.getUint32(ctrPos, isLE); // read current counter value
let { s0, s1, s2, s3 } = encrypt(xk, c32[0], c32[1], c32[2], c32[3]);
// process blocks
for (let i = 0; i + 4 <= src32.length; i += 4) {
dst32[i + 0] = src32[i + 0] ^ s0;
dst32[i + 1] = src32[i + 1] ^ s1;
dst32[i + 2] = src32[i + 2] ^ s2;
dst32[i + 3] = src32[i + 3] ^ s3;
ctrNum = (ctrNum + 1) >>> 0; // u32 wrap
view.setUint32(ctrPos, ctrNum, isLE);
({ s0, s1, s2, s3 } = encrypt(xk, c32[0], c32[1], c32[2], c32[3]));
}
// leftovers (less than a block)
const start = BLOCK_SIZE * Math.floor(src32.length / BLOCK_SIZE32);
if (start < srcLen) {
const b32 = new Uint32Array([s0, s1, s2, s3]);
const buf = u8(b32);
for (let i = start, pos = 0; i < srcLen; i++, pos++)
dst[i] = src[i] ^ buf[pos];
}
return dst;
}
/**
* CTR: counter mode. Creates stream cipher.
* Requires good IV. Parallelizable. OK, but no MAC.
*/
export const ctr = wrapCipher({ blockSize: 16, nonceLength: 16 }, function ctr(key, nonce) {
abytes(key);
abytes(nonce, BLOCK_SIZE);
function processCtr(buf, dst) {
const xk = expandKeyLE(key);
const n = nonce.slice();
const out = ctrCounter(xk, n, buf, dst);
xk.fill(0);
n.fill(0);
return out;
}
return {
encrypt: (plaintext, dst) => processCtr(plaintext, dst),
decrypt: (ciphertext, dst) => processCtr(ciphertext, dst),
};
});
function validateBlockDecrypt(data) {
abytes(data);
if (data.length % BLOCK_SIZE !== 0) {
throw new Error(`aes/(cbc-ecb).decrypt ciphertext should consist of blocks with size ${BLOCK_SIZE}`);
}
}
function validateBlockEncrypt(plaintext, pcks5, dst) {
let outLen = plaintext.length;
const remaining = outLen % BLOCK_SIZE;
if (!pcks5 && remaining !== 0)
throw new Error('aec/(cbc-ecb): unpadded plaintext with disabled padding');
const b = u32(plaintext);
if (pcks5) {
let left = BLOCK_SIZE - remaining;
if (!left)
left = BLOCK_SIZE; // if no bytes left, create empty padding block
outLen = outLen + left;
}
const out = getDst(outLen, dst);
const o = u32(out);
return { b, o, out };
}
function validatePCKS(data, pcks5) {
if (!pcks5)
return data;
const len = data.length;
if (!len)
throw new Error(`aes/pcks5: empty ciphertext not allowed`);
const lastByte = data[len - 1];
if (lastByte <= 0 || lastByte > 16)
throw new Error(`aes/pcks5: wrong padding byte: ${lastByte}`);
const out = data.subarray(0, -lastByte);
for (let i = 0; i < lastByte; i++)
if (data[len - i - 1] !== lastByte)
throw new Error(`aes/pcks5: wrong padding`);
return out;
}
function padPCKS(left) {
const tmp = new Uint8Array(16);
const tmp32 = u32(tmp);
tmp.set(left);
const paddingByte = BLOCK_SIZE - left.length;
for (let i = BLOCK_SIZE - paddingByte; i < BLOCK_SIZE; i++)
tmp[i] = paddingByte;
return tmp32;
}
/**
* ECB: Electronic CodeBook. Simple deterministic replacement.
* Dangerous: always map x to y. See [AES Penguin](https://words.filippo.io/the-ecb-penguin/).
*/
export const ecb = wrapCipher({ blockSize: 16 }, function ecb(key, opts = {}) {
abytes(key);
const pcks5 = !opts.disablePadding;
return {
encrypt: (plaintext, dst) => {
abytes(plaintext);
const { b, o, out: _out } = validateBlockEncrypt(plaintext, pcks5, dst);
const xk = expandKeyLE(key);
let i = 0;
for (; i + 4 <= b.length;) {
const { s0, s1, s2, s3 } = encrypt(xk, b[i + 0], b[i + 1], b[i + 2], b[i + 3]);
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
if (pcks5) {
const tmp32 = padPCKS(plaintext.subarray(i * 4));
const { s0, s1, s2, s3 } = encrypt(xk, tmp32[0], tmp32[1], tmp32[2], tmp32[3]);
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
xk.fill(0);
return _out;
},
decrypt: (ciphertext, dst) => {
validateBlockDecrypt(ciphertext);
const xk = expandKeyDecLE(key);
const out = getDst(ciphertext.length, dst);
const b = u32(ciphertext);
const o = u32(out);
for (let i = 0; i + 4 <= b.length;) {
const { s0, s1, s2, s3 } = decrypt(xk, b[i + 0], b[i + 1], b[i + 2], b[i + 3]);
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
xk.fill(0);
return validatePCKS(out, pcks5);
},
};
});
/**
* CBC: Cipher-Block-Chaining. Key is previous rounds block.
* Fragile: needs proper padding. Unauthenticated: needs MAC.
*/
export const cbc = wrapCipher({ blockSize: 16, nonceLength: 16 }, function cbc(key, iv, opts = {}) {
abytes(key);
abytes(iv, 16);
const pcks5 = !opts.disablePadding;
return {
encrypt: (plaintext, dst) => {
const xk = expandKeyLE(key);
const { b, o, out: _out } = validateBlockEncrypt(plaintext, pcks5, dst);
const n32 = u32(iv);
// prettier-ignore
let s0 = n32[0], s1 = n32[1], s2 = n32[2], s3 = n32[3];
let i = 0;
for (; i + 4 <= b.length;) {
(s0 ^= b[i + 0]), (s1 ^= b[i + 1]), (s2 ^= b[i + 2]), (s3 ^= b[i + 3]);
({ s0, s1, s2, s3 } = encrypt(xk, s0, s1, s2, s3));
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
if (pcks5) {
const tmp32 = padPCKS(plaintext.subarray(i * 4));
(s0 ^= tmp32[0]), (s1 ^= tmp32[1]), (s2 ^= tmp32[2]), (s3 ^= tmp32[3]);
({ s0, s1, s2, s3 } = encrypt(xk, s0, s1, s2, s3));
(o[i++] = s0), (o[i++] = s1), (o[i++] = s2), (o[i++] = s3);
}
xk.fill(0);
return _out;
},
decrypt: (ciphertext, dst) => {
validateBlockDecrypt(ciphertext);
const xk = expandKeyDecLE(key);
const n32 = u32(iv);
const out = getDst(ciphertext.length, dst);
const b = u32(ciphertext);
const o = u32(out);
// prettier-ignore
let s0 = n32[0], s1 = n32[1], s2 = n32[2], s3 = n32[3];
for (let i = 0; i + 4 <= b.length;) {
// prettier-ignore
const ps0 = s0, ps1 = s1, ps2 = s2, ps3 = s3;
(s0 = b[i + 0]), (s1 = b[i + 1]), (s2 = b[i + 2]), (s3 = b[i + 3]);
const { s0: o0, s1: o1, s2: o2, s3: o3 } = decrypt(xk, s0, s1, s2, s3);
(o[i++] = o0 ^ ps0), (o[i++] = o1 ^ ps1), (o[i++] = o2 ^ ps2), (o[i++] = o3 ^ ps3);
}
xk.fill(0);
return validatePCKS(out, pcks5);
},
};
});
/**
* CFB: Cipher Feedback Mode. The input for the block cipher is the previous cipher output.
* Unauthenticated: needs MAC.
*/
export const cfb = wrapCipher({ blockSize: 16, nonceLength: 16 }, function cfb(key, iv) {
abytes(key);
abytes(iv, 16);
function processCfb(src, isEncrypt, dst) {
const xk = expandKeyLE(key);
const srcLen = src.length;
dst = getDst(srcLen, dst);
const src32 = u32(src);
const dst32 = u32(dst);
const next32 = isEncrypt ? dst32 : src32;
const n32 = u32(iv);
// prettier-ignore
let s0 = n32[0], s1 = n32[1], s2 = n32[2], s3 = n32[3];
for (let i = 0; i + 4 <= src32.length;) {
const { s0: e0, s1: e1, s2: e2, s3: e3 } = encrypt(xk, s0, s1, s2, s3);
dst32[i + 0] = src32[i + 0] ^ e0;
dst32[i + 1] = src32[i + 1] ^ e1;
dst32[i + 2] = src32[i + 2] ^ e2;
dst32[i + 3] = src32[i + 3] ^ e3;
(s0 = next32[i++]), (s1 = next32[i++]), (s2 = next32[i++]), (s3 = next32[i++]);
}
// leftovers (less than block)
const start = BLOCK_SIZE * Math.floor(src32.length / BLOCK_SIZE32);
if (start < srcLen) {
({ s0, s1, s2, s3 } = encrypt(xk, s0, s1, s2, s3));
const buf = u8(new Uint32Array([s0, s1, s2, s3]));
for (let i = start, pos = 0; i < srcLen; i++, pos++)
dst[i] = src[i] ^ buf[pos];
buf.fill(0);
}
xk.fill(0);
return dst;
}
return {
encrypt: (plaintext, dst) => processCfb(plaintext, true, dst),
decrypt: (ciphertext, dst) => processCfb(ciphertext, false, dst),
};
});
// TODO: merge with chacha, however gcm has bitLen while chacha has byteLen
function computeTag(fn, isLE, key, data, AAD) {
const h = fn.create(key, data.length + (AAD?.length || 0));
if (AAD)
h.update(AAD);
h.update(data);
const num = new Uint8Array(16);
const view = createView(num);
if (AAD)
setBigUint64(view, 0, BigInt(AAD.length * 8), isLE);
setBigUint64(view, 8, BigInt(data.length * 8), isLE);
h.update(num);
return h.digest();
}
/**
* GCM: Galois/Counter Mode.
* Good, modern version of CTR, parallel, with MAC.
* Be careful: MACs can be forged.
*/
export const gcm = wrapCipher({ blockSize: 16, nonceLength: 12, tagLength: 16 }, function gcm(key, nonce, AAD) {
abytes(nonce);
// Nonce can be pretty much anything (even 1 byte). But smaller nonces less secure.
if (nonce.length === 0)
throw new Error('aes/gcm: empty nonce');
const tagLength = 16;
function _computeTag(authKey, tagMask, data) {
const tag = computeTag(ghash, false, authKey, data, AAD);
for (let i = 0; i < tagMask.length; i++)
tag[i] ^= tagMask[i];
return tag;
}
function deriveKeys() {
const xk = expandKeyLE(key);
const authKey = EMPTY_BLOCK.slice();
const counter = EMPTY_BLOCK.slice();
ctr32(xk, false, counter, counter, authKey);
if (nonce.length === 12) {
counter.set(nonce);
}
else {
// Spec (NIST 800-38d) supports variable size nonce.
// Not supported for now, but can be useful.
const nonceLen = EMPTY_BLOCK.slice();
const view = createView(nonceLen);
setBigUint64(view, 8, BigInt(nonce.length * 8), false);
// ghash(nonce || u64be(0) || u64be(nonceLen*8))
ghash.create(authKey).update(nonce).update(nonceLen).digestInto(counter);
}
const tagMask = ctr32(xk, false, counter, EMPTY_BLOCK);
return { xk, authKey, counter, tagMask };
}
return {
encrypt: (plaintext) => {
abytes(plaintext);
const { xk, authKey, counter, tagMask } = deriveKeys();
const out = new Uint8Array(plaintext.length + tagLength);
ctr32(xk, false, counter, plaintext, out);
const tag = _computeTag(authKey, tagMask, out.subarray(0, out.length - tagLength));
out.set(tag, plaintext.length);
xk.fill(0);
return out;
},
decrypt: (ciphertext) => {
abytes(ciphertext);
if (ciphertext.length < tagLength)
throw new Error(`aes/gcm: ciphertext less than tagLen (${tagLength})`);
const { xk, authKey, counter, tagMask } = deriveKeys();
const data = ciphertext.subarray(0, -tagLength);
const passedTag = ciphertext.subarray(-tagLength);
const tag = _computeTag(authKey, tagMask, data);
if (!equalBytes(tag, passedTag))
throw new Error('aes/gcm: invalid ghash tag');
const out = ctr32(xk, false, counter, data);
authKey.fill(0);
tagMask.fill(0);
xk.fill(0);
return out;
},
};
});
const limit = (name, min, max) => (value) => {
if (!Number.isSafeInteger(value) || min > value || value > max)
throw new Error(`${name}: invalid value=${value}, must be [${min}..${max}]`);
};
/**
* AES-GCM-SIV: classic AES-GCM with nonce-misuse resistance.
* Guarantees that, when a nonce is repeated, the only security loss is that identical
* plaintexts will produce identical ciphertexts.
* RFC 8452, https://datatracker.ietf.org/doc/html/rfc8452
*/
export const siv = wrapCipher({ blockSize: 16, nonceLength: 12, tagLength: 16 }, function siv(key, nonce, AAD) {
const tagLength = 16;
// From RFC 8452: Section 6
const AAD_LIMIT = limit('AAD', 0, 2 ** 36);
const PLAIN_LIMIT = limit('plaintext', 0, 2 ** 36);
const NONCE_LIMIT = limit('nonce', 12, 12);
const CIPHER_LIMIT = limit('ciphertext', 16, 2 ** 36 + 16);
abytes(nonce);
NONCE_LIMIT(nonce.length);
if (AAD) {
abytes(AAD);
AAD_LIMIT(AAD.length);
}
function deriveKeys() {
const len = key.length;
if (len !== 16 && len !== 24 && len !== 32)
throw new Error(`key length must be 16, 24 or 32 bytes, got: ${len} bytes`);
const xk = expandKeyLE(key);
const encKey = new Uint8Array(len);
const authKey = new Uint8Array(16);
const n32 = u32(nonce);
// prettier-ignore
let s0 = 0, s1 = n32[0], s2 = n32[1], s3 = n32[2];
let counter = 0;
for (const derivedKey of [authKey, encKey].map(u32)) {
const d32 = u32(derivedKey);
for (let i = 0; i < d32.length; i += 2) {
// aes(u32le(0) || nonce)[:8] || aes(u32le(1) || nonce)[:8] ...
const { s0: o0, s1: o1 } = encrypt(xk, s0, s1, s2, s3);
d32[i + 0] = o0;
d32[i + 1] = o1;
s0 = ++counter; // increment counter inside state
}
}
xk.fill(0);
return { authKey, encKey: expandKeyLE(encKey) };
}
function _computeTag(encKey, authKey, data) {
const tag = computeTag(polyval, true, authKey, data, AAD);
// Compute the expected tag by XORing S_s and the nonce, clearing the
// most significant bit of the last byte and encrypting with the
// message-encryption key.
for (let i = 0; i < 12; i++)
tag[i] ^= nonce[i];
tag[15] &= 0x7f; // Clear the highest bit
// encrypt tag as block
const t32 = u32(tag);
// prettier-ignore
let s0 = t32[0], s1 = t32[1], s2 = t32[2], s3 = t32[3];
({ s0, s1, s2, s3 } = encrypt(encKey, s0, s1, s2, s3));
(t32[0] = s0), (t32[1] = s1), (t32[2] = s2), (t32[3] = s3);
return tag;
}
// actual decrypt/encrypt of message.
function processSiv(encKey, tag, input) {
let block = tag.slice();
block[15] |= 0x80; // Force highest bit
return ctr32(encKey, true, block, input);
}
return {
encrypt: (plaintext) => {
abytes(plaintext);
PLAIN_LIMIT(plaintext.length);
const { encKey, authKey } = deriveKeys();
const tag = _computeTag(encKey, authKey, plaintext);
const out = new Uint8Array(plaintext.length + tagLength);
out.set(tag, plaintext.length);
out.set(processSiv(encKey, tag, plaintext));
encKey.fill(0);
authKey.fill(0);
return out;
},
decrypt: (ciphertext) => {
abytes(ciphertext);
CIPHER_LIMIT(ciphertext.length);
const tag = ciphertext.subarray(-tagLength);
const { encKey, authKey } = deriveKeys();
const plaintext = processSiv(encKey, tag, ciphertext.subarray(0, -tagLength));
const expectedTag = _computeTag(encKey, authKey, plaintext);
encKey.fill(0);
authKey.fill(0);
if (!equalBytes(tag, expectedTag))
throw new Error('invalid polyval tag');
return plaintext;
},
};
});
function isBytes32(a) {
return (a != null &&
typeof a === 'object' &&
(a instanceof Uint32Array || a.constructor.name === 'Uint32Array'));
}
function encryptBlock(xk, block) {
abytes(block, 16);
if (!isBytes32(xk))
throw new Error('_encryptBlock accepts result of expandKeyLE');
const b32 = u32(block);
let { s0, s1, s2, s3 } = encrypt(xk, b32[0], b32[1], b32[2], b32[3]);
(b32[0] = s0), (b32[1] = s1), (b32[2] = s2), (b32[3] = s3);
return block;
}
function decryptBlock(xk, block) {
abytes(block, 16);
if (!isBytes32(xk))
throw new Error('_decryptBlock accepts result of expandKeyLE');
const b32 = u32(block);
let { s0, s1, s2, s3 } = decrypt(xk, b32[0], b32[1], b32[2], b32[3]);
(b32[0] = s0), (b32[1] = s1), (b32[2] = s2), (b32[3] = s3);
return block;
}
// Highly unsafe private functions for implementing new modes or ciphers based on AES
// Can change at any time, no API guarantees
export const unsafe = {
expandKeyLE,
expandKeyDecLE,
encrypt,
decrypt,
encryptBlock,
decryptBlock,
ctrCounter,
ctr32,
};
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// prettier-ignore
import { wrapCipher, createView, equalBytes, setBigUint64, } from './utils.js';
import { poly1305 } from './_poly1305.js';
import { createCipher, rotl } from './_arx.js';
import { bytes as abytes } from './_assert.js';
// ChaCha20 stream cipher was released in 2008. ChaCha aims to increase
// the diffusion per round, but had slightly less cryptanalysis.
// https://cr.yp.to/chacha.html, http://cr.yp.to/chacha/chacha-20080128.pdf
/**
* ChaCha core function.
*/
// prettier-ignore
function chachaCore(s, k, n, out, cnt, rounds = 20) {
let y00 = s[0], y01 = s[1], y02 = s[2], y03 = s[3], // "expa" "nd 3" "2-by" "te k"
y04 = k[0], y05 = k[1], y06 = k[2], y07 = k[3], // Key Key Key Key
y08 = k[4], y09 = k[5], y10 = k[6], y11 = k[7], // Key Key Key Key
y12 = cnt, y13 = n[0], y14 = n[1], y15 = n[2]; // Counter Counter Nonce Nonce
// Save state to temporary variables
let x00 = y00, x01 = y01, x02 = y02, x03 = y03, x04 = y04, x05 = y05, x06 = y06, x07 = y07, x08 = y08, x09 = y09, x10 = y10, x11 = y11, x12 = y12, x13 = y13, x14 = y14, x15 = y15;
for (let r = 0; r < rounds; r += 2) {
x00 = (x00 + x04) | 0;
x12 = rotl(x12 ^ x00, 16);
x08 = (x08 + x12) | 0;
x04 = rotl(x04 ^ x08, 12);
x00 = (x00 + x04) | 0;
x12 = rotl(x12 ^ x00, 8);
x08 = (x08 + x12) | 0;
x04 = rotl(x04 ^ x08, 7);
x01 = (x01 + x05) | 0;
x13 = rotl(x13 ^ x01, 16);
x09 = (x09 + x13) | 0;
x05 = rotl(x05 ^ x09, 12);
x01 = (x01 + x05) | 0;
x13 = rotl(x13 ^ x01, 8);
x09 = (x09 + x13) | 0;
x05 = rotl(x05 ^ x09, 7);
x02 = (x02 + x06) | 0;
x14 = rotl(x14 ^ x02, 16);
x10 = (x10 + x14) | 0;
x06 = rotl(x06 ^ x10, 12);
x02 = (x02 + x06) | 0;
x14 = rotl(x14 ^ x02, 8);
x10 = (x10 + x14) | 0;
x06 = rotl(x06 ^ x10, 7);
x03 = (x03 + x07) | 0;
x15 = rotl(x15 ^ x03, 16);
x11 = (x11 + x15) | 0;
x07 = rotl(x07 ^ x11, 12);
x03 = (x03 + x07) | 0;
x15 = rotl(x15 ^ x03, 8);
x11 = (x11 + x15) | 0;
x07 = rotl(x07 ^ x11, 7);
x00 = (x00 + x05) | 0;
x15 = rotl(x15 ^ x00, 16);
x10 = (x10 + x15) | 0;
x05 = rotl(x05 ^ x10, 12);
x00 = (x00 + x05) | 0;
x15 = rotl(x15 ^ x00, 8);
x10 = (x10 + x15) | 0;
x05 = rotl(x05 ^ x10, 7);
x01 = (x01 + x06) | 0;
x12 = rotl(x12 ^ x01, 16);
x11 = (x11 + x12) | 0;
x06 = rotl(x06 ^ x11, 12);
x01 = (x01 + x06) | 0;
x12 = rotl(x12 ^ x01, 8);
x11 = (x11 + x12) | 0;
x06 = rotl(x06 ^ x11, 7);
x02 = (x02 + x07) | 0;
x13 = rotl(x13 ^ x02, 16);
x08 = (x08 + x13) | 0;
x07 = rotl(x07 ^ x08, 12);
x02 = (x02 + x07) | 0;
x13 = rotl(x13 ^ x02, 8);
x08 = (x08 + x13) | 0;
x07 = rotl(x07 ^ x08, 7);
x03 = (x03 + x04) | 0;
x14 = rotl(x14 ^ x03, 16);
x09 = (x09 + x14) | 0;
x04 = rotl(x04 ^ x09, 12);
x03 = (x03 + x04) | 0;
x14 = rotl(x14 ^ x03, 8);
x09 = (x09 + x14) | 0;
x04 = rotl(x04 ^ x09, 7);
}
// Write output
let oi = 0;
out[oi++] = (y00 + x00) | 0;
out[oi++] = (y01 + x01) | 0;
out[oi++] = (y02 + x02) | 0;
out[oi++] = (y03 + x03) | 0;
out[oi++] = (y04 + x04) | 0;
out[oi++] = (y05 + x05) | 0;
out[oi++] = (y06 + x06) | 0;
out[oi++] = (y07 + x07) | 0;
out[oi++] = (y08 + x08) | 0;
out[oi++] = (y09 + x09) | 0;
out[oi++] = (y10 + x10) | 0;
out[oi++] = (y11 + x11) | 0;
out[oi++] = (y12 + x12) | 0;
out[oi++] = (y13 + x13) | 0;
out[oi++] = (y14 + x14) | 0;
out[oi++] = (y15 + x15) | 0;
}
/**
* hchacha helper method, used primarily in xchacha, to hash
* key and nonce into key' and nonce'.
* Same as chachaCore, but there doesn't seem to be a way to move the block
* out without 25% performance hit.
*/
// prettier-ignore
export function hchacha(s, k, i, o32) {
let x00 = s[0], x01 = s[1], x02 = s[2], x03 = s[3], x04 = k[0], x05 = k[1], x06 = k[2], x07 = k[3], x08 = k[4], x09 = k[5], x10 = k[6], x11 = k[7], x12 = i[0], x13 = i[1], x14 = i[2], x15 = i[3];
for (let r = 0; r < 20; r += 2) {
x00 = (x00 + x04) | 0;
x12 = rotl(x12 ^ x00, 16);
x08 = (x08 + x12) | 0;
x04 = rotl(x04 ^ x08, 12);
x00 = (x00 + x04) | 0;
x12 = rotl(x12 ^ x00, 8);
x08 = (x08 + x12) | 0;
x04 = rotl(x04 ^ x08, 7);
x01 = (x01 + x05) | 0;
x13 = rotl(x13 ^ x01, 16);
x09 = (x09 + x13) | 0;
x05 = rotl(x05 ^ x09, 12);
x01 = (x01 + x05) | 0;
x13 = rotl(x13 ^ x01, 8);
x09 = (x09 + x13) | 0;
x05 = rotl(x05 ^ x09, 7);
x02 = (x02 + x06) | 0;
x14 = rotl(x14 ^ x02, 16);
x10 = (x10 + x14) | 0;
x06 = rotl(x06 ^ x10, 12);
x02 = (x02 + x06) | 0;
x14 = rotl(x14 ^ x02, 8);
x10 = (x10 + x14) | 0;
x06 = rotl(x06 ^ x10, 7);
x03 = (x03 + x07) | 0;
x15 = rotl(x15 ^ x03, 16);
x11 = (x11 + x15) | 0;
x07 = rotl(x07 ^ x11, 12);
x03 = (x03 + x07) | 0;
x15 = rotl(x15 ^ x03, 8);
x11 = (x11 + x15) | 0;
x07 = rotl(x07 ^ x11, 7);
x00 = (x00 + x05) | 0;
x15 = rotl(x15 ^ x00, 16);
x10 = (x10 + x15) | 0;
x05 = rotl(x05 ^ x10, 12);
x00 = (x00 + x05) | 0;
x15 = rotl(x15 ^ x00, 8);
x10 = (x10 + x15) | 0;
x05 = rotl(x05 ^ x10, 7);
x01 = (x01 + x06) | 0;
x12 = rotl(x12 ^ x01, 16);
x11 = (x11 + x12) | 0;
x06 = rotl(x06 ^ x11, 12);
x01 = (x01 + x06) | 0;
x12 = rotl(x12 ^ x01, 8);
x11 = (x11 + x12) | 0;
x06 = rotl(x06 ^ x11, 7);
x02 = (x02 + x07) | 0;
x13 = rotl(x13 ^ x02, 16);
x08 = (x08 + x13) | 0;
x07 = rotl(x07 ^ x08, 12);
x02 = (x02 + x07) | 0;
x13 = rotl(x13 ^ x02, 8);
x08 = (x08 + x13) | 0;
x07 = rotl(x07 ^ x08, 7);
x03 = (x03 + x04) | 0;
x14 = rotl(x14 ^ x03, 16);
x09 = (x09 + x14) | 0;
x04 = rotl(x04 ^ x09, 12);
x03 = (x03 + x04) | 0;
x14 = rotl(x14 ^ x03, 8);
x09 = (x09 + x14) | 0;
x04 = rotl(x04 ^ x09, 7);
}
let oi = 0;
o32[oi++] = x00;
o32[oi++] = x01;
o32[oi++] = x02;
o32[oi++] = x03;
o32[oi++] = x12;
o32[oi++] = x13;
o32[oi++] = x14;
o32[oi++] = x15;
}
/**
* Original, non-RFC chacha20 from DJB. 8-byte nonce, 8-byte counter.
*/
export const chacha20orig = /* @__PURE__ */ createCipher(chachaCore, {
counterRight: false,
counterLength: 8,
allowShortKeys: true,
});
/**
* ChaCha stream cipher. Conforms to RFC 8439 (IETF, TLS). 12-byte nonce, 4-byte counter.
* With 12-byte nonce, it's not safe to use fill it with random (CSPRNG), due to collision chance.
*/
export const chacha20 = /* @__PURE__ */ createCipher(chachaCore, {
counterRight: false,
counterLength: 4,
allowShortKeys: false,
});
/**
* XChaCha eXtended-nonce ChaCha. 24-byte nonce.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
* https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha
*/
export const xchacha20 = /* @__PURE__ */ createCipher(chachaCore, {
counterRight: false,
counterLength: 8,
extendNonceFn: hchacha,
allowShortKeys: false,
});
/**
* Reduced 8-round chacha, described in original paper.
*/
export const chacha8 = /* @__PURE__ */ createCipher(chachaCore, {
counterRight: false,
counterLength: 4,
rounds: 8,
});
/**
* Reduced 12-round chacha, described in original paper.
*/
export const chacha12 = /* @__PURE__ */ createCipher(chachaCore, {
counterRight: false,
counterLength: 4,
rounds: 12,
});
const ZEROS16 = /* @__PURE__ */ new Uint8Array(16);
// Pad to digest size with zeros
const updatePadded = (h, msg) => {
h.update(msg);
const left = msg.length % 16;
if (left)
h.update(ZEROS16.subarray(left));
};
const ZEROS32 = /* @__PURE__ */ new Uint8Array(32);
function computeTag(fn, key, nonce, data, AAD) {
const authKey = fn(key, nonce, ZEROS32);
const h = poly1305.create(authKey);
if (AAD)
updatePadded(h, AAD);
updatePadded(h, data);
const num = new Uint8Array(16);
const view = createView(num);
setBigUint64(view, 0, BigInt(AAD ? AAD.length : 0), true);
setBigUint64(view, 8, BigInt(data.length), true);
h.update(num);
const res = h.digest();
authKey.fill(0);
return res;
}
/**
* AEAD algorithm from RFC 8439.
* Salsa20 and chacha (RFC 8439) use poly1305 differently.
* We could have composed them similar to:
* https://github.com/paulmillr/scure-base/blob/b266c73dde977b1dd7ef40ef7a23cc15aab526b3/index.ts#L250
* But it's hard because of authKey:
* In salsa20, authKey changes position in salsa stream.
* In chacha, authKey can't be computed inside computeTag, it modifies the counter.
*/
export const _poly1305_aead = (xorStream) => (key, nonce, AAD) => {
const tagLength = 16;
abytes(key, 32);
abytes(nonce);
return {
encrypt: (plaintext, output) => {
const plength = plaintext.length;
const clength = plength + tagLength;
if (output) {
abytes(output, clength);
}
else {
output = new Uint8Array(clength);
}
xorStream(key, nonce, plaintext, output, 1);
const tag = computeTag(xorStream, key, nonce, output.subarray(0, -tagLength), AAD);
output.set(tag, plength); // append tag
return output;
},
decrypt: (ciphertext, output) => {
const clength = ciphertext.length;
const plength = clength - tagLength;
if (clength < tagLength)
throw new Error(`encrypted data must be at least ${tagLength} bytes`);
if (output) {
abytes(output, plength);
}
else {
output = new Uint8Array(plength);
}
const data = ciphertext.subarray(0, -tagLength);
const passedTag = ciphertext.subarray(-tagLength);
const tag = computeTag(xorStream, key, nonce, data, AAD);
if (!equalBytes(passedTag, tag))
throw new Error('invalid tag');
xorStream(key, nonce, data, output, 1);
return output;
},
};
};
/**
* ChaCha20-Poly1305 from RFC 8439.
* With 12-byte nonce, it's not safe to use fill it with random (CSPRNG), due to collision chance.
*/
export const chacha20poly1305 = /* @__PURE__ */ wrapCipher({ blockSize: 64, nonceLength: 12, tagLength: 16 }, _poly1305_aead(chacha20));
/**
* XChaCha20-Poly1305 extended-nonce chacha.
* https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
*/
export const xchacha20poly1305 = /* @__PURE__ */ wrapCipher({ blockSize: 64, nonceLength: 24, tagLength: 16 }, _poly1305_aead(xchacha20));
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const cr = typeof globalThis === 'object' && 'crypto' in globalThis ? globalThis.crypto : undefined;
export function randomBytes(bytesLength = 32) {
if (cr && typeof cr.getRandomValues === 'function')
return cr.getRandomValues(new Uint8Array(bytesLength));
throw new Error('crypto.getRandomValues must be defined');
}
export function getWebcryptoSubtle() {
if (cr && typeof cr.subtle === 'object' && cr.subtle != null)
return cr.subtle;
throw new Error('crypto.subtle must be defined');
}
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{"version":3,"file":"crypto.js","sourceRoot":"","sources":["../src/crypto.ts"],"names":[],"mappings":"AAGA,MAAM,EAAE,GAAG,OAAO,UAAU,KAAK,QAAQ,IAAI,QAAQ,IAAI,UAAU,CAAC,CAAC,CAAC,UAAU,CAAC,MAAM,CAAC,CAAC,CAAC,SAAS,CAAC;AAEpG,MAAM,UAAU,WAAW,CAAC,WAAW,GAAG,EAAE;IAC1C,IAAI,EAAE,IAAI,OAAO,EAAE,CAAC,eAAe,KAAK,UAAU;QAChD,OAAO,EAAE,CAAC,eAAe,CAAC,IAAI,UAAU,CAAC,WAAW,CAAC,CAAC,CAAC;IACzD,MAAM,IAAI,KAAK,CAAC,wCAAwC,CAAC,CAAC;AAC5D,CAAC;AAED,MAAM,UAAU,kBAAkB;IAChC,IAAI,EAAE,IAAI,OAAO,EAAE,CAAC,MAAM,KAAK,QAAQ,IAAI,EAAE,CAAC,MAAM,IAAI,IAAI;QAAE,OAAO,EAAE,CAAC,MAAM,CAAC;IAC/E,MAAM,IAAI,KAAK,CAAC,+BAA+B,CAAC,CAAC;AACnD,CAAC"}

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// We use WebCrypto aka globalThis.crypto, which exists in browsers and node.js 16+.
// See utils.ts for details.
// The file will throw on node.js 14 and earlier.
// @ts-ignore
import * as nc from 'node:crypto';
const cr = nc && typeof nc === 'object' && 'webcrypto' in nc ? nc.webcrypto : undefined;
export function randomBytes(bytesLength = 32) {
if (cr && typeof cr.getRandomValues === 'function')
return cr.getRandomValues(new Uint8Array(bytesLength));
throw new Error('crypto.getRandomValues must be defined');
}
export function getWebcryptoSubtle() {
if (cr && typeof cr.subtle === 'object' && cr.subtle != null)
return cr.subtle;
throw new Error('crypto.subtle must be defined');
}
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{"version":3,"file":"cryptoNode.js","sourceRoot":"","sources":["../src/cryptoNode.ts"],"names":[],"mappings":"AAAA,oFAAoF;AACpF,4BAA4B;AAC5B,iDAAiD;AACjD,aAAa;AACb,OAAO,KAAK,EAAE,MAAM,aAAa,CAAC;AAClC,MAAM,EAAE,GAAG,EAAE,IAAI,OAAO,EAAE,KAAK,QAAQ,IAAI,WAAW,IAAI,EAAE,CAAC,CAAC,CAAE,EAAE,CAAC,SAAiB,CAAC,CAAC,CAAC,SAAS,CAAC;AAEjG,MAAM,UAAU,WAAW,CAAC,WAAW,GAAG,EAAE;IAC1C,IAAI,EAAE,IAAI,OAAO,EAAE,CAAC,eAAe,KAAK,UAAU;QAChD,OAAO,EAAE,CAAC,eAAe,CAAC,IAAI,UAAU,CAAC,WAAW,CAAC,CAAC,CAAC;IACzD,MAAM,IAAI,KAAK,CAAC,wCAAwC,CAAC,CAAC;AAC5D,CAAC;AAED,MAAM,UAAU,kBAAkB;IAChC,IAAI,EAAE,IAAI,OAAO,EAAE,CAAC,MAAM,KAAK,QAAQ,IAAI,EAAE,CAAC,MAAM,IAAI,IAAI;QAAE,OAAO,EAAE,CAAC,MAAM,CAAC;IAC/E,MAAM,IAAI,KAAK,CAAC,+BAA+B,CAAC,CAAC;AACnD,CAAC"}

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import { bytesToNumberBE, numberToBytesBE } from './utils.js';
import { unsafe } from './aes.js';
// NOTE: no point in inlining encrypt instead of encryptBlock, since BigInt stuff will be slow
const { expandKeyLE, encryptBlock } = unsafe;
// Format-preserving encryption algorithm (FPE-FF1) specified in NIST Special Publication 800-38G.
// https://nvlpubs.nist.gov/nistpubs/SpecialPublications/NIST.SP.800-38G.pdf
const BLOCK_LEN = 16;
function mod(a, b) {
const result = a % b;
return result >= 0 ? result : b + result;
}
function NUMradix(radix, data) {
let res = BigInt(0);
for (let i of data)
res = res * BigInt(radix) + BigInt(i);
return res;
}
function getRound(radix, key, tweak, x) {
if (radix > 2 ** 16 - 1)
throw new Error(`Invalid radix: ${radix}`);
// radix**minlen ≥ 100
const minLen = Math.ceil(Math.log(100) / Math.log(radix));
const maxLen = 2 ** 32 - 1;
// 2 ≤ minlen ≤ maxlen < 2**32
if (2 > minLen || minLen > maxLen || maxLen >= 2 ** 32)
throw new Error('Invalid radix: 2 ≤ minlen ≤ maxlen < 2**32');
if (x.length < minLen || x.length > maxLen)
throw new Error('X is outside minLen..maxLen bounds');
const u = Math.floor(x.length / 2);
const v = x.length - u;
const b = Math.ceil(Math.ceil(v * Math.log2(radix)) / 8);
const d = 4 * Math.ceil(b / 4) + 4;
const padding = mod(-tweak.length - b - 1, 16);
// P = [1]1 || [2]1 || [1]1 || [radix]3 || [10]1 || [u mod 256]1 || [n]4 || [t]4.
const P = new Uint8Array([1, 2, 1, 0, 0, 0, 10, u, 0, 0, 0, 0, 0, 0, 0, 0]);
const view = new DataView(P.buffer);
view.setUint16(4, radix, false);
view.setUint32(8, x.length, false);
view.setUint32(12, tweak.length, false);
// Q = T || [0](tb1) mod 16 || [i]1 || [NUMradix(B)]b.
const PQ = new Uint8Array(P.length + tweak.length + padding + 1 + b);
PQ.set(P);
P.fill(0);
PQ.set(tweak, P.length);
const xk = expandKeyLE(key);
const round = (A, B, i, decrypt = false) => {
// Q = ... || [i]1 || [NUMradix(B)]b.
PQ[PQ.length - b - 1] = i;
if (b)
PQ.set(numberToBytesBE(NUMradix(radix, B), b), PQ.length - b);
// PRF
let r = new Uint8Array(16);
for (let j = 0; j < PQ.length / BLOCK_LEN; j++) {
for (let i = 0; i < BLOCK_LEN; i++)
r[i] ^= PQ[j * BLOCK_LEN + i];
encryptBlock(xk, r);
}
// Let S be the first d bytes of the following string of ⎡d/16⎤ blocks:
// R || CIPHK(R ⊕[1]16) || CIPHK(R ⊕[2]16) ...CIPHK(R ⊕[⎡d / 16⎤ 1]16).
let s = Array.from(r);
for (let j = 1; s.length < d; j++) {
const block = numberToBytesBE(BigInt(j), 16);
for (let k = 0; k < BLOCK_LEN; k++)
block[k] ^= r[k];
s.push(...Array.from(encryptBlock(xk, block)));
}
let y = bytesToNumberBE(Uint8Array.from(s.slice(0, d)));
s.fill(0);
if (decrypt)
y = -y;
const m = i % 2 === 0 ? u : v;
let c = mod(NUMradix(radix, A) + y, BigInt(radix) ** BigInt(m));
// STR(radix, m, c)
const C = Array(m).fill(0);
for (let i = 0; i < m; i++, c /= BigInt(radix))
C[m - 1 - i] = Number(c % BigInt(radix));
A.fill(0);
A = B;
B = C;
return [A, B];
};
const destroy = () => {
xk.fill(0);
PQ.fill(0);
};
return { u, round, destroy };
}
const EMPTY_BUF = new Uint8Array([]);
export function FF1(radix, key, tweak = EMPTY_BUF) {
const PQ = getRound.bind(null, radix, key, tweak);
return {
encrypt(x) {
const { u, round, destroy } = PQ(x);
let [A, B] = [x.slice(0, u), x.slice(u)];
for (let i = 0; i < 10; i++)
[A, B] = round(A, B, i);
destroy();
const res = A.concat(B);
A.fill(0);
B.fill(0);
return res;
},
decrypt(x) {
const { u, round, destroy } = PQ(x);
// The FF1.Decrypt algorithm is similar to the FF1.Encrypt algorithm;
// the differences are in Step 6, where:
// 1) the order of the indices is reversed,
// 2) the roles of A and B are swapped
// 3) modular addition is replaced by modular subtraction, in Step 6vi.
let [B, A] = [x.slice(0, u), x.slice(u)];
for (let i = 9; i >= 0; i--)
[A, B] = round(A, B, i, true);
destroy();
const res = B.concat(A);
A.fill(0);
B.fill(0);
return res;
},
};
}
// Binary string which encodes each byte in little-endian byte order
const binLE = {
encode(bytes) {
const x = [];
for (let i = 0; i < bytes.length; i++) {
for (let j = 0, tmp = bytes[i]; j < 8; j++, tmp >>= 1)
x.push(tmp & 1);
}
return x;
},
decode(b) {
if (b.length % 8)
throw new Error('Invalid binary string');
const res = new Uint8Array(b.length / 8);
for (let i = 0, j = 0; i < res.length; i++) {
res[i] = b[j++] | (b[j++] << 1) | (b[j++] << 2) | (b[j++] << 3);
res[i] |= (b[j++] << 4) | (b[j++] << 5) | (b[j++] << 6) | (b[j++] << 7);
}
return res;
},
};
export function BinaryFF1(key, tweak = EMPTY_BUF) {
const ff1 = FF1(2, key, tweak);
return {
encrypt: (x) => binLE.decode(ff1.encrypt(binLE.encode(x))),
decrypt: (x) => binLE.decode(ff1.decrypt(binLE.encode(x))),
};
}
//# sourceMappingURL=ff1.js.map

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throw new Error('noble-ciphers have no entry-point: consult README for usage');
export {};
//# sourceMappingURL=index.js.map

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{"version":3,"file":"index.js","sourceRoot":"","sources":["../src/index.ts"],"names":[],"mappings":"AAAA,MAAM,IAAI,KAAK,CAAC,6DAA6D,CAAC,CAAC"}

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{
"type": "module",
"sideEffects": false,
"browser": {
"node:crypto": false
},
"node": {
"./crypto.js": "./esm/cryptoNode.js",
"./crypto": "./esm/cryptoNode.js"
}
}

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import { bytes as abytes } from './_assert.js';
import { createCipher, rotl } from './_arx.js';
import { poly1305 } from './_poly1305.js';
import { wrapCipher, equalBytes } from './utils.js';
// Salsa20 stream cipher was released in 2005.
// Salsa's goal was to implement AES replacement that does not rely on S-Boxes,
// which are hard to implement in a constant-time manner.
// https://cr.yp.to/snuffle.html, https://cr.yp.to/snuffle/salsafamily-20071225.pdf
/**
* Salsa20 core function.
*/
// prettier-ignore
function salsaCore(s, k, n, out, cnt, rounds = 20) {
// Based on https://cr.yp.to/salsa20.html
let y00 = s[0], y01 = k[0], y02 = k[1], y03 = k[2], // "expa" Key Key Key
y04 = k[3], y05 = s[1], y06 = n[0], y07 = n[1], // Key "nd 3" Nonce Nonce
y08 = cnt, y09 = 0, y10 = s[2], y11 = k[4], // Pos. Pos. "2-by" Key
y12 = k[5], y13 = k[6], y14 = k[7], y15 = s[3]; // Key Key Key "te k"
// Save state to temporary variables
let x00 = y00, x01 = y01, x02 = y02, x03 = y03, x04 = y04, x05 = y05, x06 = y06, x07 = y07, x08 = y08, x09 = y09, x10 = y10, x11 = y11, x12 = y12, x13 = y13, x14 = y14, x15 = y15;
for (let r = 0; r < rounds; r += 2) {
x04 ^= rotl(x00 + x12 | 0, 7);
x08 ^= rotl(x04 + x00 | 0, 9);
x12 ^= rotl(x08 + x04 | 0, 13);
x00 ^= rotl(x12 + x08 | 0, 18);
x09 ^= rotl(x05 + x01 | 0, 7);
x13 ^= rotl(x09 + x05 | 0, 9);
x01 ^= rotl(x13 + x09 | 0, 13);
x05 ^= rotl(x01 + x13 | 0, 18);
x14 ^= rotl(x10 + x06 | 0, 7);
x02 ^= rotl(x14 + x10 | 0, 9);
x06 ^= rotl(x02 + x14 | 0, 13);
x10 ^= rotl(x06 + x02 | 0, 18);
x03 ^= rotl(x15 + x11 | 0, 7);
x07 ^= rotl(x03 + x15 | 0, 9);
x11 ^= rotl(x07 + x03 | 0, 13);
x15 ^= rotl(x11 + x07 | 0, 18);
x01 ^= rotl(x00 + x03 | 0, 7);
x02 ^= rotl(x01 + x00 | 0, 9);
x03 ^= rotl(x02 + x01 | 0, 13);
x00 ^= rotl(x03 + x02 | 0, 18);
x06 ^= rotl(x05 + x04 | 0, 7);
x07 ^= rotl(x06 + x05 | 0, 9);
x04 ^= rotl(x07 + x06 | 0, 13);
x05 ^= rotl(x04 + x07 | 0, 18);
x11 ^= rotl(x10 + x09 | 0, 7);
x08 ^= rotl(x11 + x10 | 0, 9);
x09 ^= rotl(x08 + x11 | 0, 13);
x10 ^= rotl(x09 + x08 | 0, 18);
x12 ^= rotl(x15 + x14 | 0, 7);
x13 ^= rotl(x12 + x15 | 0, 9);
x14 ^= rotl(x13 + x12 | 0, 13);
x15 ^= rotl(x14 + x13 | 0, 18);
}
// Write output
let oi = 0;
out[oi++] = (y00 + x00) | 0;
out[oi++] = (y01 + x01) | 0;
out[oi++] = (y02 + x02) | 0;
out[oi++] = (y03 + x03) | 0;
out[oi++] = (y04 + x04) | 0;
out[oi++] = (y05 + x05) | 0;
out[oi++] = (y06 + x06) | 0;
out[oi++] = (y07 + x07) | 0;
out[oi++] = (y08 + x08) | 0;
out[oi++] = (y09 + x09) | 0;
out[oi++] = (y10 + x10) | 0;
out[oi++] = (y11 + x11) | 0;
out[oi++] = (y12 + x12) | 0;
out[oi++] = (y13 + x13) | 0;
out[oi++] = (y14 + x14) | 0;
out[oi++] = (y15 + x15) | 0;
}
/**
* hsalsa hashing function, used primarily in xsalsa, to hash
* key and nonce into key' and nonce'.
* Same as salsaCore, but there doesn't seem to be a way to move the block
* out without 25% performance hit.
*/
// prettier-ignore
export function hsalsa(s, k, i, o32) {
let x00 = s[0], x01 = k[0], x02 = k[1], x03 = k[2], x04 = k[3], x05 = s[1], x06 = i[0], x07 = i[1], x08 = i[2], x09 = i[3], x10 = s[2], x11 = k[4], x12 = k[5], x13 = k[6], x14 = k[7], x15 = s[3];
for (let r = 0; r < 20; r += 2) {
x04 ^= rotl(x00 + x12 | 0, 7);
x08 ^= rotl(x04 + x00 | 0, 9);
x12 ^= rotl(x08 + x04 | 0, 13);
x00 ^= rotl(x12 + x08 | 0, 18);
x09 ^= rotl(x05 + x01 | 0, 7);
x13 ^= rotl(x09 + x05 | 0, 9);
x01 ^= rotl(x13 + x09 | 0, 13);
x05 ^= rotl(x01 + x13 | 0, 18);
x14 ^= rotl(x10 + x06 | 0, 7);
x02 ^= rotl(x14 + x10 | 0, 9);
x06 ^= rotl(x02 + x14 | 0, 13);
x10 ^= rotl(x06 + x02 | 0, 18);
x03 ^= rotl(x15 + x11 | 0, 7);
x07 ^= rotl(x03 + x15 | 0, 9);
x11 ^= rotl(x07 + x03 | 0, 13);
x15 ^= rotl(x11 + x07 | 0, 18);
x01 ^= rotl(x00 + x03 | 0, 7);
x02 ^= rotl(x01 + x00 | 0, 9);
x03 ^= rotl(x02 + x01 | 0, 13);
x00 ^= rotl(x03 + x02 | 0, 18);
x06 ^= rotl(x05 + x04 | 0, 7);
x07 ^= rotl(x06 + x05 | 0, 9);
x04 ^= rotl(x07 + x06 | 0, 13);
x05 ^= rotl(x04 + x07 | 0, 18);
x11 ^= rotl(x10 + x09 | 0, 7);
x08 ^= rotl(x11 + x10 | 0, 9);
x09 ^= rotl(x08 + x11 | 0, 13);
x10 ^= rotl(x09 + x08 | 0, 18);
x12 ^= rotl(x15 + x14 | 0, 7);
x13 ^= rotl(x12 + x15 | 0, 9);
x14 ^= rotl(x13 + x12 | 0, 13);
x15 ^= rotl(x14 + x13 | 0, 18);
}
let oi = 0;
o32[oi++] = x00;
o32[oi++] = x05;
o32[oi++] = x10;
o32[oi++] = x15;
o32[oi++] = x06;
o32[oi++] = x07;
o32[oi++] = x08;
o32[oi++] = x09;
}
/**
* Salsa20 from original paper.
* With 12-byte nonce, it's not safe to use fill it with random (CSPRNG), due to collision chance.
*/
export const salsa20 = /* @__PURE__ */ createCipher(salsaCore, {
allowShortKeys: true,
counterRight: true,
});
/**
* xsalsa20 eXtended-nonce salsa.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
*/
export const xsalsa20 = /* @__PURE__ */ createCipher(salsaCore, {
counterRight: true,
extendNonceFn: hsalsa,
});
/**
* xsalsa20-poly1305 eXtended-nonce salsa.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
* Also known as secretbox from libsodium / nacl.
*/
export const xsalsa20poly1305 = /* @__PURE__ */ wrapCipher({ blockSize: 64, nonceLength: 24, tagLength: 16 }, (key, nonce) => {
const tagLength = 16;
abytes(key, 32);
abytes(nonce, 24);
return {
encrypt: (plaintext, output) => {
abytes(plaintext);
// This is small optimization (calculate auth key with same call as encryption itself) makes it hard
// to separate tag calculation and encryption itself, since 32 byte is half-block of salsa (64 byte)
const clength = plaintext.length + 32;
if (output) {
abytes(output, clength);
}
else {
output = new Uint8Array(clength);
}
output.set(plaintext, 32);
xsalsa20(key, nonce, output, output);
const authKey = output.subarray(0, 32);
const tag = poly1305(output.subarray(32), authKey);
// Clean auth key, even though JS provides no guarantees about memory cleaning
output.set(tag, tagLength);
output.subarray(0, tagLength).fill(0);
return output.subarray(tagLength);
},
decrypt: (ciphertext) => {
abytes(ciphertext);
const clength = ciphertext.length;
if (clength < tagLength)
throw new Error('encrypted data should be at least 16 bytes');
// Create new ciphertext array:
// auth tag auth tag from ciphertext ciphertext
// [bytes 0..16] [bytes 16..32] [bytes 32..]
// 16 instead of 32, because we already have 16 byte tag
const ciphertext_ = new Uint8Array(clength + tagLength); // alloc
ciphertext_.set(ciphertext, tagLength);
// Each xsalsa20 calls to hsalsa to calculate key, but seems not much perf difference
// Separate call to calculate authkey, since first bytes contains tag
const authKey = xsalsa20(key, nonce, new Uint8Array(32)); // alloc(32)
const tag = poly1305(ciphertext_.subarray(32), authKey);
if (!equalBytes(ciphertext_.subarray(16, 32), tag))
throw new Error('invalid tag');
const plaintext = xsalsa20(key, nonce, ciphertext_); // alloc
// Clean auth key, even though JS provides no guarantees about memory cleaning
plaintext.subarray(0, 32).fill(0);
authKey.fill(0);
return plaintext.subarray(32);
},
};
});
/**
* Alias to xsalsa20poly1305, for compatibility with libsodium / nacl
*/
export function secretbox(key, nonce) {
const xs = xsalsa20poly1305(key, nonce);
return { seal: xs.encrypt, open: xs.decrypt };
}
//# sourceMappingURL=salsa.js.map

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/*! noble-ciphers - MIT License (c) 2023 Paul Miller (paulmillr.com) */
import { bytes as abytes, isBytes } from './_assert.js';
// Cast array to different type
export const u8 = (arr) => new Uint8Array(arr.buffer, arr.byteOffset, arr.byteLength);
export const u16 = (arr) => new Uint16Array(arr.buffer, arr.byteOffset, Math.floor(arr.byteLength / 2));
export const u32 = (arr) => new Uint32Array(arr.buffer, arr.byteOffset, Math.floor(arr.byteLength / 4));
// Cast array to view
export const createView = (arr) => new DataView(arr.buffer, arr.byteOffset, arr.byteLength);
// big-endian hardware is rare. Just in case someone still decides to run ciphers:
// early-throw an error because we don't support BE yet.
export const isLE = new Uint8Array(new Uint32Array([0x11223344]).buffer)[0] === 0x44;
if (!isLE)
throw new Error('Non little-endian hardware is not supported');
// Array where index 0xf0 (240) is mapped to string 'f0'
const hexes = /* @__PURE__ */ Array.from({ length: 256 }, (_, i) => i.toString(16).padStart(2, '0'));
/**
* @example bytesToHex(Uint8Array.from([0xca, 0xfe, 0x01, 0x23])) // 'cafe0123'
*/
export function bytesToHex(bytes) {
abytes(bytes);
// pre-caching improves the speed 6x
let hex = '';
for (let i = 0; i < bytes.length; i++) {
hex += hexes[bytes[i]];
}
return hex;
}
// We use optimized technique to convert hex string to byte array
const asciis = { _0: 48, _9: 57, _A: 65, _F: 70, _a: 97, _f: 102 };
function asciiToBase16(char) {
if (char >= asciis._0 && char <= asciis._9)
return char - asciis._0;
if (char >= asciis._A && char <= asciis._F)
return char - (asciis._A - 10);
if (char >= asciis._a && char <= asciis._f)
return char - (asciis._a - 10);
return;
}
/**
* @example hexToBytes('cafe0123') // Uint8Array.from([0xca, 0xfe, 0x01, 0x23])
*/
export function hexToBytes(hex) {
if (typeof hex !== 'string')
throw new Error('hex string expected, got ' + typeof hex);
const hl = hex.length;
const al = hl / 2;
if (hl % 2)
throw new Error('padded hex string expected, got unpadded hex of length ' + hl);
const array = new Uint8Array(al);
for (let ai = 0, hi = 0; ai < al; ai++, hi += 2) {
const n1 = asciiToBase16(hex.charCodeAt(hi));
const n2 = asciiToBase16(hex.charCodeAt(hi + 1));
if (n1 === undefined || n2 === undefined) {
const char = hex[hi] + hex[hi + 1];
throw new Error('hex string expected, got non-hex character "' + char + '" at index ' + hi);
}
array[ai] = n1 * 16 + n2;
}
return array;
}
export function hexToNumber(hex) {
if (typeof hex !== 'string')
throw new Error('hex string expected, got ' + typeof hex);
// Big Endian
return BigInt(hex === '' ? '0' : `0x${hex}`);
}
// BE: Big Endian, LE: Little Endian
export function bytesToNumberBE(bytes) {
return hexToNumber(bytesToHex(bytes));
}
export function numberToBytesBE(n, len) {
return hexToBytes(n.toString(16).padStart(len * 2, '0'));
}
// There is no setImmediate in browser and setTimeout is slow.
// call of async fn will return Promise, which will be fullfiled only on
// next scheduler queue processing step and this is exactly what we need.
export const nextTick = async () => { };
// Returns control to thread each 'tick' ms to avoid blocking
export async function asyncLoop(iters, tick, cb) {
let ts = Date.now();
for (let i = 0; i < iters; i++) {
cb(i);
// Date.now() is not monotonic, so in case if clock goes backwards we return return control too
const diff = Date.now() - ts;
if (diff >= 0 && diff < tick)
continue;
await nextTick();
ts += diff;
}
}
/**
* @example utf8ToBytes('abc') // new Uint8Array([97, 98, 99])
*/
export function utf8ToBytes(str) {
if (typeof str !== 'string')
throw new Error(`string expected, got ${typeof str}`);
return new Uint8Array(new TextEncoder().encode(str)); // https://bugzil.la/1681809
}
/**
* @example bytesToUtf8(new Uint8Array([97, 98, 99])) // 'abc'
*/
export function bytesToUtf8(bytes) {
return new TextDecoder().decode(bytes);
}
/**
* Normalizes (non-hex) string or Uint8Array to Uint8Array.
* Warning: when Uint8Array is passed, it would NOT get copied.
* Keep in mind for future mutable operations.
*/
export function toBytes(data) {
if (typeof data === 'string')
data = utf8ToBytes(data);
else if (isBytes(data))
data = data.slice();
else
throw new Error(`Uint8Array expected, got ${typeof data}`);
return data;
}
/**
* Copies several Uint8Arrays into one.
*/
export function concatBytes(...arrays) {
let sum = 0;
for (let i = 0; i < arrays.length; i++) {
const a = arrays[i];
abytes(a);
sum += a.length;
}
const res = new Uint8Array(sum);
for (let i = 0, pad = 0; i < arrays.length; i++) {
const a = arrays[i];
res.set(a, pad);
pad += a.length;
}
return res;
}
export function checkOpts(defaults, opts) {
if (opts == null || typeof opts !== 'object')
throw new Error('options must be defined');
const merged = Object.assign(defaults, opts);
return merged;
}
// Compares 2 u8a-s in kinda constant time
export function equalBytes(a, b) {
if (a.length !== b.length)
return false;
let diff = 0;
for (let i = 0; i < a.length; i++)
diff |= a[i] ^ b[i];
return diff === 0;
}
// For runtime check if class implements interface
export class Hash {
}
/**
* @__NO_SIDE_EFFECTS__
*/
export const wrapCipher = (params, c) => {
Object.assign(c, params);
return c;
};
// Polyfill for Safari 14
export function setBigUint64(view, byteOffset, value, isLE) {
if (typeof view.setBigUint64 === 'function')
return view.setBigUint64(byteOffset, value, isLE);
const _32n = BigInt(32);
const _u32_max = BigInt(0xffffffff);
const wh = Number((value >> _32n) & _u32_max);
const wl = Number(value & _u32_max);
const h = isLE ? 4 : 0;
const l = isLE ? 0 : 4;
view.setUint32(byteOffset + h, wh, isLE);
view.setUint32(byteOffset + l, wl, isLE);
}
export function u64Lengths(ciphertext, AAD) {
const num = new Uint8Array(16);
const view = createView(num);
setBigUint64(view, 0, BigInt(AAD ? AAD.length : 0), true);
setBigUint64(view, 8, BigInt(ciphertext.length), true);
return num;
}
//# sourceMappingURL=utils.js.map

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// We use WebCrypto aka globalThis.crypto, which exists in browsers and node.js 16+.
// node.js versions earlier than v19 don't declare it in global scope.
// For node.js, package.js on#exports field mapping rewrites import
// from `crypto` to `cryptoNode`, which imports native module.
// Makes the utils un-importable in browsers without a bundler.
// Once node.js 18 is deprecated, we can just drop the import.
//
// Use full path so that Node.js can rewrite it to `cryptoNode.js`.
import { randomBytes, getWebcryptoSubtle } from '@noble/ciphers/crypto';
import { concatBytes } from './utils.js';
import { number, bytes as abytes } from './_assert.js';
/**
* Secure PRNG. Uses `crypto.getRandomValues`, which defers to OS.
*/
export { randomBytes, getWebcryptoSubtle };
// Uses CSPRG for nonce, nonce injected in ciphertext
export function managedNonce(fn) {
number(fn.nonceLength);
return ((key, ...args) => ({
encrypt: (plaintext, ...argsEnc) => {
const { nonceLength } = fn;
const nonce = randomBytes(nonceLength);
const ciphertext = fn(key, nonce, ...args).encrypt(plaintext, ...argsEnc);
const out = concatBytes(nonce, ciphertext);
ciphertext.fill(0);
return out;
},
decrypt: (ciphertext, ...argsDec) => {
const { nonceLength } = fn;
const nonce = ciphertext.subarray(0, nonceLength);
const data = ciphertext.subarray(nonceLength);
return fn(key, nonce, ...args).decrypt(data, ...argsDec);
},
}));
}
// Overridable
export const utils = {
async encrypt(key, keyParams, cryptParams, plaintext) {
const cr = getWebcryptoSubtle();
const iKey = await cr.importKey('raw', key, keyParams, true, ['encrypt']);
const ciphertext = await cr.encrypt(cryptParams, iKey, plaintext);
return new Uint8Array(ciphertext);
},
async decrypt(key, keyParams, cryptParams, ciphertext) {
const cr = getWebcryptoSubtle();
const iKey = await cr.importKey('raw', key, keyParams, true, ['decrypt']);
const plaintext = await cr.decrypt(cryptParams, iKey, ciphertext);
return new Uint8Array(plaintext);
},
};
const mode = {
CBC: 'AES-CBC',
CTR: 'AES-CTR',
GCM: 'AES-GCM',
};
function getCryptParams(algo, nonce, AAD) {
if (algo === mode.CBC)
return { name: mode.CBC, iv: nonce };
if (algo === mode.CTR)
return { name: mode.CTR, counter: nonce, length: 64 };
if (algo === mode.GCM) {
if (AAD)
return { name: mode.GCM, iv: nonce, additionalData: AAD };
else
return { name: mode.GCM, iv: nonce };
}
throw new Error('unknown aes block mode');
}
function generate(algo) {
return (key, nonce, AAD) => {
abytes(key);
abytes(nonce);
const keyParams = { name: algo, length: key.length * 8 };
const cryptParams = getCryptParams(algo, nonce, AAD);
return {
// keyLength,
encrypt(plaintext) {
abytes(plaintext);
return utils.encrypt(key, keyParams, cryptParams, plaintext);
},
decrypt(ciphertext) {
abytes(ciphertext);
return utils.decrypt(key, keyParams, cryptParams, ciphertext);
},
};
};
}
export const cbc = generate(mode.CBC);
export const ctr = generate(mode.CTR);
export const gcm = generate(mode.GCM);
// // Type tests
// import { siv, gcm, ctr, ecb, cbc } from '../aes.js';
// import { xsalsa20poly1305 } from '../salsa.js';
// import { chacha20poly1305, xchacha20poly1305 } from '../chacha.js';
// const wsiv = managedNonce(siv);
// const wgcm = managedNonce(gcm);
// const wctr = managedNonce(ctr);
// const wcbc = managedNonce(cbc);
// const wsalsapoly = managedNonce(xsalsa20poly1305);
// const wchacha = managedNonce(chacha20poly1305);
// const wxchacha = managedNonce(xchacha20poly1305);
// // should fail
// const wcbc2 = managedNonce(managedNonce(cbc));
// const wecb = managedNonce(ecb);
//# sourceMappingURL=webcrypto.js.map

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import { Cipher } from './utils.js';
export declare function FF1(radix: number, key: Uint8Array, tweak?: Uint8Array): {
encrypt(x: number[]): number[];
decrypt(x: number[]): number[];
};
export declare function BinaryFF1(key: Uint8Array, tweak?: Uint8Array): Cipher;
//# sourceMappingURL=ff1.d.ts.map

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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.BinaryFF1 = exports.FF1 = void 0;
const utils_js_1 = require("./utils.js");
const aes_js_1 = require("./aes.js");
// NOTE: no point in inlining encrypt instead of encryptBlock, since BigInt stuff will be slow
const { expandKeyLE, encryptBlock } = aes_js_1.unsafe;
// Format-preserving encryption algorithm (FPE-FF1) specified in NIST Special Publication 800-38G.
// https://nvlpubs.nist.gov/nistpubs/SpecialPublications/NIST.SP.800-38G.pdf
const BLOCK_LEN = 16;
function mod(a, b) {
const result = a % b;
return result >= 0 ? result : b + result;
}
function NUMradix(radix, data) {
let res = BigInt(0);
for (let i of data)
res = res * BigInt(radix) + BigInt(i);
return res;
}
function getRound(radix, key, tweak, x) {
if (radix > 2 ** 16 - 1)
throw new Error(`Invalid radix: ${radix}`);
// radix**minlen ≥ 100
const minLen = Math.ceil(Math.log(100) / Math.log(radix));
const maxLen = 2 ** 32 - 1;
// 2 ≤ minlen ≤ maxlen < 2**32
if (2 > minLen || minLen > maxLen || maxLen >= 2 ** 32)
throw new Error('Invalid radix: 2 ≤ minlen ≤ maxlen < 2**32');
if (x.length < minLen || x.length > maxLen)
throw new Error('X is outside minLen..maxLen bounds');
const u = Math.floor(x.length / 2);
const v = x.length - u;
const b = Math.ceil(Math.ceil(v * Math.log2(radix)) / 8);
const d = 4 * Math.ceil(b / 4) + 4;
const padding = mod(-tweak.length - b - 1, 16);
// P = [1]1 || [2]1 || [1]1 || [radix]3 || [10]1 || [u mod 256]1 || [n]4 || [t]4.
const P = new Uint8Array([1, 2, 1, 0, 0, 0, 10, u, 0, 0, 0, 0, 0, 0, 0, 0]);
const view = new DataView(P.buffer);
view.setUint16(4, radix, false);
view.setUint32(8, x.length, false);
view.setUint32(12, tweak.length, false);
// Q = T || [0](tb1) mod 16 || [i]1 || [NUMradix(B)]b.
const PQ = new Uint8Array(P.length + tweak.length + padding + 1 + b);
PQ.set(P);
P.fill(0);
PQ.set(tweak, P.length);
const xk = expandKeyLE(key);
const round = (A, B, i, decrypt = false) => {
// Q = ... || [i]1 || [NUMradix(B)]b.
PQ[PQ.length - b - 1] = i;
if (b)
PQ.set((0, utils_js_1.numberToBytesBE)(NUMradix(radix, B), b), PQ.length - b);
// PRF
let r = new Uint8Array(16);
for (let j = 0; j < PQ.length / BLOCK_LEN; j++) {
for (let i = 0; i < BLOCK_LEN; i++)
r[i] ^= PQ[j * BLOCK_LEN + i];
encryptBlock(xk, r);
}
// Let S be the first d bytes of the following string of ⎡d/16⎤ blocks:
// R || CIPHK(R ⊕[1]16) || CIPHK(R ⊕[2]16) ...CIPHK(R ⊕[⎡d / 16⎤ 1]16).
let s = Array.from(r);
for (let j = 1; s.length < d; j++) {
const block = (0, utils_js_1.numberToBytesBE)(BigInt(j), 16);
for (let k = 0; k < BLOCK_LEN; k++)
block[k] ^= r[k];
s.push(...Array.from(encryptBlock(xk, block)));
}
let y = (0, utils_js_1.bytesToNumberBE)(Uint8Array.from(s.slice(0, d)));
s.fill(0);
if (decrypt)
y = -y;
const m = i % 2 === 0 ? u : v;
let c = mod(NUMradix(radix, A) + y, BigInt(radix) ** BigInt(m));
// STR(radix, m, c)
const C = Array(m).fill(0);
for (let i = 0; i < m; i++, c /= BigInt(radix))
C[m - 1 - i] = Number(c % BigInt(radix));
A.fill(0);
A = B;
B = C;
return [A, B];
};
const destroy = () => {
xk.fill(0);
PQ.fill(0);
};
return { u, round, destroy };
}
const EMPTY_BUF = new Uint8Array([]);
function FF1(radix, key, tweak = EMPTY_BUF) {
const PQ = getRound.bind(null, radix, key, tweak);
return {
encrypt(x) {
const { u, round, destroy } = PQ(x);
let [A, B] = [x.slice(0, u), x.slice(u)];
for (let i = 0; i < 10; i++)
[A, B] = round(A, B, i);
destroy();
const res = A.concat(B);
A.fill(0);
B.fill(0);
return res;
},
decrypt(x) {
const { u, round, destroy } = PQ(x);
// The FF1.Decrypt algorithm is similar to the FF1.Encrypt algorithm;
// the differences are in Step 6, where:
// 1) the order of the indices is reversed,
// 2) the roles of A and B are swapped
// 3) modular addition is replaced by modular subtraction, in Step 6vi.
let [B, A] = [x.slice(0, u), x.slice(u)];
for (let i = 9; i >= 0; i--)
[A, B] = round(A, B, i, true);
destroy();
const res = B.concat(A);
A.fill(0);
B.fill(0);
return res;
},
};
}
exports.FF1 = FF1;
// Binary string which encodes each byte in little-endian byte order
const binLE = {
encode(bytes) {
const x = [];
for (let i = 0; i < bytes.length; i++) {
for (let j = 0, tmp = bytes[i]; j < 8; j++, tmp >>= 1)
x.push(tmp & 1);
}
return x;
},
decode(b) {
if (b.length % 8)
throw new Error('Invalid binary string');
const res = new Uint8Array(b.length / 8);
for (let i = 0, j = 0; i < res.length; i++) {
res[i] = b[j++] | (b[j++] << 1) | (b[j++] << 2) | (b[j++] << 3);
res[i] |= (b[j++] << 4) | (b[j++] << 5) | (b[j++] << 6) | (b[j++] << 7);
}
return res;
},
};
function BinaryFF1(key, tweak = EMPTY_BUF) {
const ff1 = FF1(2, key, tweak);
return {
encrypt: (x) => binLE.decode(ff1.encrypt(binLE.encode(x))),
decrypt: (x) => binLE.decode(ff1.decrypt(binLE.encode(x))),
};
}
exports.BinaryFF1 = BinaryFF1;
//# sourceMappingURL=ff1.js.map

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node_modules/@noble/ciphers/index.d.ts generated vendored Normal file
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//# sourceMappingURL=index.d.ts.map

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{"version":3,"file":"index.d.ts","sourceRoot":"","sources":["src/index.ts"],"names":[],"mappings":""}

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"use strict";
throw new Error('noble-ciphers have no entry-point: consult README for usage');
//# sourceMappingURL=index.js.map

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{
"name": "@noble/ciphers",
"version": "0.5.3",
"description": "Auditable & minimal JS implementation of Salsa20, ChaCha and AES",
"files": ["esm", "src", "*.js", "*.js.map", "*.d.ts", "*.d.ts.map"],
"scripts": {
"bench": "node benchmark/aead.js noble && node benchmark/ciphers.js noble",
"bench:all": "node benchmark/{aead,ciphers,poly}.js",
"bench:install": "cd benchmark && npm install && cd ../../",
"build": "npm run build:clean; tsc && tsc -p tsconfig.esm.json",
"build:release": "cd build && npm i && npm run build",
"build:clean": "rm *.{js,d.ts,js.map,d.ts.map} esm/*.{js,d.ts,js.map,d.ts.map} 2> /dev/null",
"lint": "prettier --check 'src/**/*.{js,ts}' 'test/**/*.{js,ts,mjs}'",
"format": "prettier --write 'src/**/*.{js,ts}' 'test/**/*.{js,ts,mjs}'",
"test": "node test/index.js"
},
"author": "Paul Miller (https://paulmillr.com)",
"homepage": "https://paulmillr.com/noble/",
"repository": {
"type": "git",
"url": "git+https://github.com/paulmillr/noble-ciphers.git"
},
"license": "MIT",
"sideEffects": false,
"devDependencies": {
"@paulmillr/jsbt": "0.1.0",
"@scure/base": "1.1.3",
"fast-check": "3.0.0",
"micro-bmark": "0.3.1",
"micro-should": "0.4.0",
"prettier": "3.1.1",
"typescript": "5.3.2"
},
"main": "index.js",
"exports": {
".": {
"types": "./index.d.ts",
"import": "./esm/index.js",
"default": "./index.js"
},
"./_micro": {
"types": "./_micro.d.ts",
"import": "./esm/_micro.js",
"default": "./_micro.js"
},
"./_poly1305": {
"types": "./_poly1305.d.ts",
"import": "./esm/_poly1305.js",
"default": "./_poly1305.js"
},
"./_polyval": {
"types": "./_polyval.d.ts",
"import": "./esm/_polyval.js",
"default": "./_polyval.js"
},
"./crypto": {
"types": "./crypto.d.ts",
"node": {
"import": "./esm/cryptoNode.js",
"default": "./cryptoNode.js"
},
"import": "./esm/crypto.js",
"default": "./crypto.js"
},
"./aes": {
"types": "./aes.d.ts",
"import": "./esm/aes.js",
"default": "./aes.js"
},
"./chacha": {
"types": "./chacha.d.ts",
"import": "./esm/chacha.js",
"default": "./chacha.js"
},
"./salsa": {
"types": "./salsa.d.ts",
"import": "./esm/salsa.js",
"default": "./salsa.js"
},
"./ff1": {
"types": "./ff1.d.ts",
"import": "./esm/ff1.js",
"default": "./ff1.js"
},
"./utils": {
"types": "./utils.d.ts",
"import": "./esm/utils.js",
"default": "./utils.js"
},
"./index": {
"types": "./index.d.ts",
"import": "./esm/index.js",
"default": "./index.js"
},
"./webcrypto": {
"types": "./webcrypto.d.ts",
"import": "./esm/webcrypto.js",
"default": "./webcrypto.js"
}
},
"browser": {
"node:crypto": false,
"./crypto": "./crypto.js"
},
"keywords": [
"salsa20",
"chacha",
"aes",
"cryptography",
"crypto",
"noble",
"cipher",
"ciphers",
"xsalsa20",
"xchacha20",
"poly1305",
"xsalsa20poly1305",
"chacha20poly1305",
"xchacha20poly1305",
"secretbox",
"rijndael",
"siv",
"ff1"
],
"funding": "https://paulmillr.com/funding/"
}

36
node_modules/@noble/ciphers/salsa.d.ts generated vendored Normal file
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import { Cipher } from './utils.js';
/**
* hsalsa hashing function, used primarily in xsalsa, to hash
* key and nonce into key' and nonce'.
* Same as salsaCore, but there doesn't seem to be a way to move the block
* out without 25% performance hit.
*/
export declare function hsalsa(s: Uint32Array, k: Uint32Array, i: Uint32Array, o32: Uint32Array): void;
/**
* Salsa20 from original paper.
* With 12-byte nonce, it's not safe to use fill it with random (CSPRNG), due to collision chance.
*/
export declare const salsa20: import("./utils.js").XorStream;
/**
* xsalsa20 eXtended-nonce salsa.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
*/
export declare const xsalsa20: import("./utils.js").XorStream;
/**
* xsalsa20-poly1305 eXtended-nonce salsa.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
* Also known as secretbox from libsodium / nacl.
*/
export declare const xsalsa20poly1305: ((key: Uint8Array, nonce: Uint8Array) => Cipher) & {
blockSize: number;
nonceLength: number;
tagLength: number;
};
/**
* Alias to xsalsa20poly1305, for compatibility with libsodium / nacl
*/
export declare function secretbox(key: Uint8Array, nonce: Uint8Array): {
seal: (plaintext: Uint8Array) => Uint8Array;
open: (ciphertext: Uint8Array) => Uint8Array;
};
//# sourceMappingURL=salsa.d.ts.map

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node_modules/@noble/ciphers/salsa.d.ts.map generated vendored Normal file
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@@ -0,0 +1 @@
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"use strict";
Object.defineProperty(exports, "__esModule", { value: true });
exports.secretbox = exports.xsalsa20poly1305 = exports.xsalsa20 = exports.salsa20 = exports.hsalsa = void 0;
const _assert_js_1 = require("./_assert.js");
const _arx_js_1 = require("./_arx.js");
const _poly1305_js_1 = require("./_poly1305.js");
const utils_js_1 = require("./utils.js");
// Salsa20 stream cipher was released in 2005.
// Salsa's goal was to implement AES replacement that does not rely on S-Boxes,
// which are hard to implement in a constant-time manner.
// https://cr.yp.to/snuffle.html, https://cr.yp.to/snuffle/salsafamily-20071225.pdf
/**
* Salsa20 core function.
*/
// prettier-ignore
function salsaCore(s, k, n, out, cnt, rounds = 20) {
// Based on https://cr.yp.to/salsa20.html
let y00 = s[0], y01 = k[0], y02 = k[1], y03 = k[2], // "expa" Key Key Key
y04 = k[3], y05 = s[1], y06 = n[0], y07 = n[1], // Key "nd 3" Nonce Nonce
y08 = cnt, y09 = 0, y10 = s[2], y11 = k[4], // Pos. Pos. "2-by" Key
y12 = k[5], y13 = k[6], y14 = k[7], y15 = s[3]; // Key Key Key "te k"
// Save state to temporary variables
let x00 = y00, x01 = y01, x02 = y02, x03 = y03, x04 = y04, x05 = y05, x06 = y06, x07 = y07, x08 = y08, x09 = y09, x10 = y10, x11 = y11, x12 = y12, x13 = y13, x14 = y14, x15 = y15;
for (let r = 0; r < rounds; r += 2) {
x04 ^= (0, _arx_js_1.rotl)(x00 + x12 | 0, 7);
x08 ^= (0, _arx_js_1.rotl)(x04 + x00 | 0, 9);
x12 ^= (0, _arx_js_1.rotl)(x08 + x04 | 0, 13);
x00 ^= (0, _arx_js_1.rotl)(x12 + x08 | 0, 18);
x09 ^= (0, _arx_js_1.rotl)(x05 + x01 | 0, 7);
x13 ^= (0, _arx_js_1.rotl)(x09 + x05 | 0, 9);
x01 ^= (0, _arx_js_1.rotl)(x13 + x09 | 0, 13);
x05 ^= (0, _arx_js_1.rotl)(x01 + x13 | 0, 18);
x14 ^= (0, _arx_js_1.rotl)(x10 + x06 | 0, 7);
x02 ^= (0, _arx_js_1.rotl)(x14 + x10 | 0, 9);
x06 ^= (0, _arx_js_1.rotl)(x02 + x14 | 0, 13);
x10 ^= (0, _arx_js_1.rotl)(x06 + x02 | 0, 18);
x03 ^= (0, _arx_js_1.rotl)(x15 + x11 | 0, 7);
x07 ^= (0, _arx_js_1.rotl)(x03 + x15 | 0, 9);
x11 ^= (0, _arx_js_1.rotl)(x07 + x03 | 0, 13);
x15 ^= (0, _arx_js_1.rotl)(x11 + x07 | 0, 18);
x01 ^= (0, _arx_js_1.rotl)(x00 + x03 | 0, 7);
x02 ^= (0, _arx_js_1.rotl)(x01 + x00 | 0, 9);
x03 ^= (0, _arx_js_1.rotl)(x02 + x01 | 0, 13);
x00 ^= (0, _arx_js_1.rotl)(x03 + x02 | 0, 18);
x06 ^= (0, _arx_js_1.rotl)(x05 + x04 | 0, 7);
x07 ^= (0, _arx_js_1.rotl)(x06 + x05 | 0, 9);
x04 ^= (0, _arx_js_1.rotl)(x07 + x06 | 0, 13);
x05 ^= (0, _arx_js_1.rotl)(x04 + x07 | 0, 18);
x11 ^= (0, _arx_js_1.rotl)(x10 + x09 | 0, 7);
x08 ^= (0, _arx_js_1.rotl)(x11 + x10 | 0, 9);
x09 ^= (0, _arx_js_1.rotl)(x08 + x11 | 0, 13);
x10 ^= (0, _arx_js_1.rotl)(x09 + x08 | 0, 18);
x12 ^= (0, _arx_js_1.rotl)(x15 + x14 | 0, 7);
x13 ^= (0, _arx_js_1.rotl)(x12 + x15 | 0, 9);
x14 ^= (0, _arx_js_1.rotl)(x13 + x12 | 0, 13);
x15 ^= (0, _arx_js_1.rotl)(x14 + x13 | 0, 18);
}
// Write output
let oi = 0;
out[oi++] = (y00 + x00) | 0;
out[oi++] = (y01 + x01) | 0;
out[oi++] = (y02 + x02) | 0;
out[oi++] = (y03 + x03) | 0;
out[oi++] = (y04 + x04) | 0;
out[oi++] = (y05 + x05) | 0;
out[oi++] = (y06 + x06) | 0;
out[oi++] = (y07 + x07) | 0;
out[oi++] = (y08 + x08) | 0;
out[oi++] = (y09 + x09) | 0;
out[oi++] = (y10 + x10) | 0;
out[oi++] = (y11 + x11) | 0;
out[oi++] = (y12 + x12) | 0;
out[oi++] = (y13 + x13) | 0;
out[oi++] = (y14 + x14) | 0;
out[oi++] = (y15 + x15) | 0;
}
/**
* hsalsa hashing function, used primarily in xsalsa, to hash
* key and nonce into key' and nonce'.
* Same as salsaCore, but there doesn't seem to be a way to move the block
* out without 25% performance hit.
*/
// prettier-ignore
function hsalsa(s, k, i, o32) {
let x00 = s[0], x01 = k[0], x02 = k[1], x03 = k[2], x04 = k[3], x05 = s[1], x06 = i[0], x07 = i[1], x08 = i[2], x09 = i[3], x10 = s[2], x11 = k[4], x12 = k[5], x13 = k[6], x14 = k[7], x15 = s[3];
for (let r = 0; r < 20; r += 2) {
x04 ^= (0, _arx_js_1.rotl)(x00 + x12 | 0, 7);
x08 ^= (0, _arx_js_1.rotl)(x04 + x00 | 0, 9);
x12 ^= (0, _arx_js_1.rotl)(x08 + x04 | 0, 13);
x00 ^= (0, _arx_js_1.rotl)(x12 + x08 | 0, 18);
x09 ^= (0, _arx_js_1.rotl)(x05 + x01 | 0, 7);
x13 ^= (0, _arx_js_1.rotl)(x09 + x05 | 0, 9);
x01 ^= (0, _arx_js_1.rotl)(x13 + x09 | 0, 13);
x05 ^= (0, _arx_js_1.rotl)(x01 + x13 | 0, 18);
x14 ^= (0, _arx_js_1.rotl)(x10 + x06 | 0, 7);
x02 ^= (0, _arx_js_1.rotl)(x14 + x10 | 0, 9);
x06 ^= (0, _arx_js_1.rotl)(x02 + x14 | 0, 13);
x10 ^= (0, _arx_js_1.rotl)(x06 + x02 | 0, 18);
x03 ^= (0, _arx_js_1.rotl)(x15 + x11 | 0, 7);
x07 ^= (0, _arx_js_1.rotl)(x03 + x15 | 0, 9);
x11 ^= (0, _arx_js_1.rotl)(x07 + x03 | 0, 13);
x15 ^= (0, _arx_js_1.rotl)(x11 + x07 | 0, 18);
x01 ^= (0, _arx_js_1.rotl)(x00 + x03 | 0, 7);
x02 ^= (0, _arx_js_1.rotl)(x01 + x00 | 0, 9);
x03 ^= (0, _arx_js_1.rotl)(x02 + x01 | 0, 13);
x00 ^= (0, _arx_js_1.rotl)(x03 + x02 | 0, 18);
x06 ^= (0, _arx_js_1.rotl)(x05 + x04 | 0, 7);
x07 ^= (0, _arx_js_1.rotl)(x06 + x05 | 0, 9);
x04 ^= (0, _arx_js_1.rotl)(x07 + x06 | 0, 13);
x05 ^= (0, _arx_js_1.rotl)(x04 + x07 | 0, 18);
x11 ^= (0, _arx_js_1.rotl)(x10 + x09 | 0, 7);
x08 ^= (0, _arx_js_1.rotl)(x11 + x10 | 0, 9);
x09 ^= (0, _arx_js_1.rotl)(x08 + x11 | 0, 13);
x10 ^= (0, _arx_js_1.rotl)(x09 + x08 | 0, 18);
x12 ^= (0, _arx_js_1.rotl)(x15 + x14 | 0, 7);
x13 ^= (0, _arx_js_1.rotl)(x12 + x15 | 0, 9);
x14 ^= (0, _arx_js_1.rotl)(x13 + x12 | 0, 13);
x15 ^= (0, _arx_js_1.rotl)(x14 + x13 | 0, 18);
}
let oi = 0;
o32[oi++] = x00;
o32[oi++] = x05;
o32[oi++] = x10;
o32[oi++] = x15;
o32[oi++] = x06;
o32[oi++] = x07;
o32[oi++] = x08;
o32[oi++] = x09;
}
exports.hsalsa = hsalsa;
/**
* Salsa20 from original paper.
* With 12-byte nonce, it's not safe to use fill it with random (CSPRNG), due to collision chance.
*/
exports.salsa20 = (0, _arx_js_1.createCipher)(salsaCore, {
allowShortKeys: true,
counterRight: true,
});
/**
* xsalsa20 eXtended-nonce salsa.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
*/
exports.xsalsa20 = (0, _arx_js_1.createCipher)(salsaCore, {
counterRight: true,
extendNonceFn: hsalsa,
});
/**
* xsalsa20-poly1305 eXtended-nonce salsa.
* With 24-byte nonce, it's safe to use fill it with random (CSPRNG).
* Also known as secretbox from libsodium / nacl.
*/
exports.xsalsa20poly1305 = (0, utils_js_1.wrapCipher)({ blockSize: 64, nonceLength: 24, tagLength: 16 }, (key, nonce) => {
const tagLength = 16;
(0, _assert_js_1.bytes)(key, 32);
(0, _assert_js_1.bytes)(nonce, 24);
return {
encrypt: (plaintext, output) => {
(0, _assert_js_1.bytes)(plaintext);
// This is small optimization (calculate auth key with same call as encryption itself) makes it hard
// to separate tag calculation and encryption itself, since 32 byte is half-block of salsa (64 byte)
const clength = plaintext.length + 32;
if (output) {
(0, _assert_js_1.bytes)(output, clength);
}
else {
output = new Uint8Array(clength);
}
output.set(plaintext, 32);
(0, exports.xsalsa20)(key, nonce, output, output);
const authKey = output.subarray(0, 32);
const tag = (0, _poly1305_js_1.poly1305)(output.subarray(32), authKey);
// Clean auth key, even though JS provides no guarantees about memory cleaning
output.set(tag, tagLength);
output.subarray(0, tagLength).fill(0);
return output.subarray(tagLength);
},
decrypt: (ciphertext) => {
(0, _assert_js_1.bytes)(ciphertext);
const clength = ciphertext.length;
if (clength < tagLength)
throw new Error('encrypted data should be at least 16 bytes');
// Create new ciphertext array:
// auth tag auth tag from ciphertext ciphertext
// [bytes 0..16] [bytes 16..32] [bytes 32..]
// 16 instead of 32, because we already have 16 byte tag
const ciphertext_ = new Uint8Array(clength + tagLength); // alloc
ciphertext_.set(ciphertext, tagLength);
// Each xsalsa20 calls to hsalsa to calculate key, but seems not much perf difference
// Separate call to calculate authkey, since first bytes contains tag
const authKey = (0, exports.xsalsa20)(key, nonce, new Uint8Array(32)); // alloc(32)
const tag = (0, _poly1305_js_1.poly1305)(ciphertext_.subarray(32), authKey);
if (!(0, utils_js_1.equalBytes)(ciphertext_.subarray(16, 32), tag))
throw new Error('invalid tag');
const plaintext = (0, exports.xsalsa20)(key, nonce, ciphertext_); // alloc
// Clean auth key, even though JS provides no guarantees about memory cleaning
plaintext.subarray(0, 32).fill(0);
authKey.fill(0);
return plaintext.subarray(32);
},
};
});
/**
* Alias to xsalsa20poly1305, for compatibility with libsodium / nacl
*/
function secretbox(key, nonce) {
const xs = (0, exports.xsalsa20poly1305)(key, nonce);
return { seal: xs.encrypt, open: xs.decrypt };
}
exports.secretbox = secretbox;
//# sourceMappingURL=salsa.js.map

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// Basic utils for ARX (add-rotate-xor) salsa and chacha ciphers.
import { number as anumber, bytes as abytes, bool as abool } from './_assert.js';
import { XorStream, checkOpts, u32 } from './utils.js';
/*
RFC8439 requires multi-step cipher stream, where
authKey starts with counter: 0, actual msg with counter: 1.
For this, we need a way to re-use nonce / counter:
const counter = new Uint8Array(4);
chacha(..., counter, ...); // counter is now 1
chacha(..., counter, ...); // counter is now 2
This is complicated:
- 32-bit counters are enough, no need for 64-bit: max ArrayBuffer size in JS is 4GB
- Original papers don't allow mutating counters
- Counter overflow is undefined [^1]
- Idea A: allow providing (nonce | counter) instead of just nonce, re-use it
- Caveat: Cannot be re-used through all cases:
- * chacha has (counter | nonce)
- * xchacha has (nonce16 | counter | nonce16)
- Idea B: separate nonce / counter and provide separate API for counter re-use
- Caveat: there are different counter sizes depending on an algorithm.
- salsa & chacha also differ in structures of key & sigma:
salsa20: s[0] | k(4) | s[1] | nonce(2) | ctr(2) | s[2] | k(4) | s[3]
chacha: s(4) | k(8) | ctr(1) | nonce(3)
chacha20orig: s(4) | k(8) | ctr(2) | nonce(2)
- Idea C: helper method such as `setSalsaState(key, nonce, sigma, data)`
- Caveat: we can't re-use counter array
xchacha [^2] uses the subkey and remaining 8 byte nonce with ChaCha20 as normal
(prefixed by 4 NUL bytes, since [RFC8439] specifies a 12-byte nonce).
[^1]: https://mailarchive.ietf.org/arch/msg/cfrg/gsOnTJzcbgG6OqD8Sc0GO5aR_tU/
[^2]: https://datatracker.ietf.org/doc/html/draft-irtf-cfrg-xchacha#appendix-A.2
*/
// We can't make top-level var depend on utils.utf8ToBytes
// because it's not present in all envs. Creating a similar fn here
const _utf8ToBytes = (str: string) => Uint8Array.from(str.split('').map((c) => c.charCodeAt(0)));
const sigma16 = _utf8ToBytes('expand 16-byte k');
const sigma32 = _utf8ToBytes('expand 32-byte k');
const sigma16_32 = u32(sigma16);
const sigma32_32 = u32(sigma32);
export const sigma = sigma32_32.slice();
export function rotl(a: number, b: number): number {
return (a << b) | (a >>> (32 - b));
}
export type CipherCoreFn = (
sigma: Uint32Array,
key: Uint32Array,
nonce: Uint32Array,
output: Uint32Array,
counter: number,
rounds?: number
) => void;
export type ExtendNonceFn = (
sigma: Uint32Array,
key: Uint32Array,
input: Uint32Array,
output: Uint32Array
) => void;
export type CipherOpts = {
allowShortKeys?: boolean; // Original salsa / chacha allow 16-byte keys
extendNonceFn?: ExtendNonceFn;
counterLength?: number;
counterRight?: boolean; // right: nonce|counter; left: counter|nonce
rounds?: number;
};
// Is byte array aligned to 4 byte offset (u32)?
function isAligned32(b: Uint8Array) {
return b.byteOffset % 4 === 0;
}
// Salsa and Chacha block length is always 512-bit
const BLOCK_LEN = 64;
const BLOCK_LEN32 = 16;
// new Uint32Array([2**32]) // => Uint32Array(1) [ 0 ]
// new Uint32Array([2**32-1]) // => Uint32Array(1) [ 4294967295 ]
const MAX_COUNTER = 2 ** 32 - 1;
const U32_EMPTY = new Uint32Array();
function runCipher(
core: CipherCoreFn,
sigma: Uint32Array,
key: Uint32Array,
nonce: Uint32Array,
data: Uint8Array,
output: Uint8Array,
counter: number,
rounds: number
): void {
const len = data.length;
const block = new Uint8Array(BLOCK_LEN);
const b32 = u32(block);
// Make sure that buffers aligned to 4 bytes
const isAligned = isAligned32(data) && isAligned32(output);
const d32 = isAligned ? u32(data) : U32_EMPTY;
const o32 = isAligned ? u32(output) : U32_EMPTY;
for (let pos = 0; pos < len; counter++) {
core(sigma, key, nonce, b32, counter, rounds);
if (counter >= MAX_COUNTER) throw new Error('arx: counter overflow');
const take = Math.min(BLOCK_LEN, len - pos);
// aligned to 4 bytes
if (isAligned && take === BLOCK_LEN) {
const pos32 = pos / 4;
if (pos % 4 !== 0) throw new Error('arx: invalid block position');
for (let j = 0, posj: number; j < BLOCK_LEN32; j++) {
posj = pos32 + j;
o32[posj] = d32[posj] ^ b32[j];
}
pos += BLOCK_LEN;
continue;
}
for (let j = 0, posj; j < take; j++) {
posj = pos + j;
output[posj] = data[posj] ^ block[j];
}
pos += take;
}
}
export function createCipher(core: CipherCoreFn, opts: CipherOpts): XorStream {
const { allowShortKeys, extendNonceFn, counterLength, counterRight, rounds } = checkOpts(
{ allowShortKeys: false, counterLength: 8, counterRight: false, rounds: 20 },
opts
);
if (typeof core !== 'function') throw new Error('core must be a function');
anumber(counterLength);
anumber(rounds);
abool(counterRight);
abool(allowShortKeys);
return (
key: Uint8Array,
nonce: Uint8Array,
data: Uint8Array,
output?: Uint8Array,
counter = 0
): Uint8Array => {
abytes(key);
abytes(nonce);
abytes(data);
const len = data.length;
if (!output) output = new Uint8Array(len);
abytes(output);
anumber(counter);
if (counter < 0 || counter >= MAX_COUNTER) throw new Error('arx: counter overflow');
if (output.length < len)
throw new Error(`arx: output (${output.length}) is shorter than data (${len})`);
const toClean = [];
// Key & sigma
// key=16 -> sigma16, k=key|key
// key=32 -> sigma32, k=key
let l = key.length,
k: Uint8Array,
sigma: Uint32Array;
if (l === 32) {
k = key.slice();
toClean.push(k);
sigma = sigma32_32;
} else if (l === 16 && allowShortKeys) {
k = new Uint8Array(32);
k.set(key);
k.set(key, 16);
sigma = sigma16_32;
toClean.push(k);
} else {
throw new Error(`arx: invalid 32-byte key, got length=${l}`);
}
// Nonce
// salsa20: 8 (8-byte counter)
// chacha20orig: 8 (8-byte counter)
// chacha20: 12 (4-byte counter)
// xsalsa20: 24 (16 -> hsalsa, 8 -> old nonce)
// xchacha20: 24 (16 -> hchacha, 8 -> old nonce)
// Align nonce to 4 bytes
if (!isAligned32(nonce)) {
nonce = nonce.slice();
toClean.push(nonce);
}
const k32 = u32(k);
// hsalsa & hchacha: handle extended nonce
if (extendNonceFn) {
if (nonce.length !== 24) throw new Error(`arx: extended nonce must be 24 bytes`);
extendNonceFn(sigma, k32, u32(nonce.subarray(0, 16)), k32);
nonce = nonce.subarray(16);
}
// Handle nonce counter
const nonceNcLen = 16 - counterLength;
if (nonceNcLen !== nonce.length)
throw new Error(`arx: nonce must be ${nonceNcLen} or 16 bytes`);
// Pad counter when nonce is 64 bit
if (nonceNcLen !== 12) {
const nc = new Uint8Array(12);
nc.set(nonce, counterRight ? 0 : 12 - nonce.length);
nonce = nc;
toClean.push(nonce);
}
const n32 = u32(nonce);
runCipher(core, sigma, k32, n32, data, output, counter, rounds);
while (toClean.length > 0) toClean.pop()!.fill(0);
return output;
};
}

50
node_modules/@noble/ciphers/src/_assert.ts generated vendored Normal file
View File

@@ -0,0 +1,50 @@
function number(n: number) {
if (!Number.isSafeInteger(n) || n < 0) throw new Error(`positive integer expected, not ${n}`);
}
function bool(b: boolean) {
if (typeof b !== 'boolean') throw new Error(`boolean expected, not ${b}`);
}
export function isBytes(a: unknown): a is Uint8Array {
return (
a instanceof Uint8Array ||
(a != null && typeof a === 'object' && a.constructor.name === 'Uint8Array')
);
}
function bytes(b: Uint8Array | undefined, ...lengths: number[]) {
if (!isBytes(b)) throw new Error('Uint8Array expected');
if (lengths.length > 0 && !lengths.includes(b.length))
throw new Error(`Uint8Array expected of length ${lengths}, not of length=${b.length}`);
}
export type Hash = {
(data: Uint8Array): Uint8Array;
blockLen: number;
outputLen: number;
create: any;
};
function hash(hash: Hash) {
if (typeof hash !== 'function' || typeof hash.create !== 'function')
throw new Error('hash must be wrapped by utils.wrapConstructor');
number(hash.outputLen);
number(hash.blockLen);
}
function exists(instance: any, checkFinished = true) {
if (instance.destroyed) throw new Error('Hash instance has been destroyed');
if (checkFinished && instance.finished) throw new Error('Hash#digest() has already been called');
}
function output(out: any, instance: any) {
bytes(out);
const min = instance.outputLen;
if (out.length < min) {
throw new Error(`digestInto() expects output buffer of length at least ${min}`);
}
}
export { number, bool, bytes, hash, exists, output };
const assert = { number, bool, bytes, hash, exists, output };
export default assert;

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