# PyLCG > Ultra-fast Linear Congruential Generator for IP Sharding PyLCG is a high-performance Python implementation of a memory-efficient IP address sharding system using Linear Congruential Generators (LCG) for deterministic random number generation. This tool enables distributed scanning & network reconnaissance by efficiently dividing IP ranges across multiple machines while maintaining pseudo-random ordering. ## Features - Memory-efficient IP range processing - Deterministic pseudo-random IP generation - High-performance LCG implementation - Support for sharding across multiple machines - Zero dependencies beyond Python standard library - Simple command-line interface ## Installation ### From PyPI ```bash pip install pylcg ``` ### From Source ```bash git clone https://github.com/acidvegas/pylcg cd pylcg chmod +x pylcg.py ``` ## Usage ### Command Line ```bash ./pylcg.py 192.168.0.0/16 --shard-num 1 --total-shards 4 --seed 12345 ``` ### As a Library ```python from pylcg import ip_stream # Generate IPs for the first shard of 4 total shards for ip in ip_stream('192.168.0.0/16', shard_num=1, total_shards=4, seed=12345): print(ip) ``` ## How It Works ### Linear Congruential Generator PyLCG uses an optimized LCG implementation with carefully chosen parameters: | Name | Variable | Value | |------------|----------|--------------| | Multiplier | `a` | `1664525` | | Increment | `c` | `1013904223` | | Modulus | `m` | `2^32` | This generates a deterministic sequence of pseudo-random numbers using the formula: ``` next = (a * current + c) mod m ``` ### Memory-Efficient IP Processing Instead of loading entire IP ranges into memory, PyLCG: 1. Converts CIDR ranges to start/end integers 2. Uses generator functions for lazy evaluation 3. Calculates IPs on-demand using index mapping 4. Maintains constant memory usage regardless of range size ### Sharding Algorithm The sharding system uses an interleaved approach: 1. Each shard is assigned a subset of indices based on modulo arithmetic 2. The LCG randomizes the order within each shard 3. Work is distributed evenly across shards 4. No sequential scanning patterns ## Performance PyLCG is designed for maximum performance: - Generates millions of IPs per second - Constant memory usage (~100KB) - Minimal CPU overhead - No disk I/O required Benchmark results on a typical system: - IP Generation: ~5-10 million IPs/second - Memory Usage: < 1MB for any range size - LCG Operations: < 1 microsecond per number ## Contributing ### Performance Optimization We welcome contributions that improve PyLCG's performance. When submitting optimizations: 1. Run the included benchmark suite: ```bash python3 unit_test.py ``` 2. Include before/after benchmark results for: - IP generation speed - Memory usage - LCG sequence generation - Shard distribution metrics 3. Consider optimizing: - Number generation algorithms - Memory access patterns - CPU cache utilization - Python-specific optimizations 4. Document any tradeoffs between: - Speed vs memory usage - Randomness vs performance - Complexity vs maintainability ### Benchmark Guidelines When running benchmarks: 1. Use consistent hardware/environment 2. Run multiple iterations 3. Test with various CIDR ranges 4. Measure both average and worst-case performance 5. Profile memory usage patterns 6. Test shard distribution uniformity ## Roadmap - [ ] IPv6 support - [ ] Custom LCG parameters - [ ] Configurable chunk sizes - [ ] State persistence - [ ] Resume capability - [ ] S3/URL input support - [ ] Extended benchmark suite --- ###### Mirrors: [acid.vegas](https://git.acid.vegas/pylcg) • [SuperNETs](https://git.supernets.org/acidvegas/pylcg) • [GitHub](https://github.com/acidvegas/pylcg) • [GitLab](https://gitlab.com/acidvegas/pylcg) • [Codeberg](https://codeberg.org/acidvegas/pylcg)