Lib.rs

Parser implementationsLNMP
#text-parser #lnmp #parser

lnmp-codec

Parser and encoder for LNMP (LLM Native Minimal Protocol) text format

by LNMP Team. Owned by Madraka.

10 releases

0.5.16 Dec 19, 2025
0.5.14 Dec 18, 2025
0.5.12 Nov 25, 2025

#419 in Parser implementations


Used in 4 crates

MIT license

1MB
23K SLoC

lnmp-codec

Parser and encoder implementations for LNMP (LLM Native Minimal Protocol) v0.5 text format and binary format.

FID Registry: All examples in this documentation use official Field IDs from registry/fids.yaml.

Maintainers note: when shipping codec changes, remember to run the workspace Release workflow (see CONTRIBUTING.md) so the meta crate picks up the new version.

Features

Text Format (v0.3)

  • Deterministic serialization: Fields always sorted by FID for consistent output
  • Canonical format: Newline-separated, no extra whitespace (v0.2)
  • Type hints: Optional type annotations (:i, :f, :b, :s, :sa, :r, :ra)
  • Generic Array Support: IntArray, FloatArray, BoolArray handling in parsing/encoding
  • Strict Profile Integration: LnmpProfile (Loose, Standard, Strict) for validation and canonical enforcement
  • Nested structures: Parse and encode nested records and arrays (v0.3)
  • Semantic checksums: Optional SC32 checksums for drift prevention (v0.3)
  • Value normalization: Canonical value transformations (v0.3)
  • Equivalence mapping: Synonym recognition (v0.3)
  • Semantic dictionary (optional): Apply lnmp-sfe dictionaries during parse/encode to map values to canonical equivalents
  • Strict mode: Validates canonical format compliance
  • Loose mode: Accepts format variations (default)
  • Lenient sanitizer: Optional pre-parse repair layer shared with lnmp-sanitize for LLM-facing inputs
  • Round-trip stability: parse(encode(parse(x))) == parse(encode(x))

Binary Format (v0.4)

  • Efficient encoding: 30-50% size reduction compared to text format
  • Zero-copy design: Fast serialization and deserialization
  • Bidirectional conversion: Seamless text ↔ binary conversion
  • Canonical binary: Fields sorted by FID, deterministic encoding
  • VarInt encoding: Space-efficient integer representation
  • Type safety: Explicit type tags for all values
  • Version validation: Protocol version checking
  • Interoperability: Compatible with v0.3 text format for supported types

Quick Start

Text Format

use lnmp_codec::{Parser, Encoder};

// Parse LNMP text
let input = "F12=14532\nF7=1\nF23=[admin,dev]";
let mut parser = Parser::new(input).unwrap();
let record = parser.parse_record().unwrap();

// Encode to canonical format
let encoder = Encoder::new();
let output = encoder.encode(&record);
// Output: F7=1\nF12=14532\nF23=[admin,dev]  (sorted by FID)

Semantic Dictionary Normalization (optional)

use lnmp_codec::{Parser, Encoder};
use lnmp_sfe::SemanticDictionary;

// Build a dictionary: map Admin/ADMIN -> admin for field 23
let mut dict = SemanticDictionary::new();
dict.add_equivalence(23, "Admin".to_string(), "admin".to_string());

// Parse with dictionary (applies equivalence during parse)
let mut parser = Parser::with_config(
    "F23=[Admin]",
    lnmp_codec::config::ParserConfig {
        semantic_dictionary: Some(dict.clone()),
        ..Default::default()
    },
)
.unwrap();
let record = parser.parse_record().unwrap();

// Encode with the same dictionary (ensures canonical output)
let encoder = Encoder::with_config(
    lnmp_codec::config::EncoderConfig::new().with_semantic_dictionary(dict),
);
let output = encoder.encode(&record);
assert_eq!(output, "F23=[admin]");

Binary Format (v0.4)

use lnmp_codec::binary::{BinaryEncoder, BinaryDecoder};

// Encode text to binary
let text = "F7=1\nF12=14532\nF23=[admin,dev]";
let encoder = BinaryEncoder::new();
let binary = encoder.encode_text(text).unwrap();

// Decode binary to text
let decoder = BinaryDecoder::new();
let decoded_text = decoder.decode_to_text(&binary).unwrap();
// Output: F7=1\nF12=14532\nF23=[admin,dev]  (canonical format)

// Round-trip conversion maintains data integrity
assert_eq!(text, decoded_text);

v0.3 Quick Start - Nested Structures

use lnmp_codec::{Parser, Encoder};

// Parse nested record (F70=nested_data from registry)
let input = "F70={F12=1;F7=1}";
let mut parser = Parser::new(input).unwrap();
let record = parser.parse_record().unwrap();

// Parse record array (F71=record_list from registry)
let input = "F71=[{F20=alice},{F20=bob}]";
let mut parser = Parser::new(input).unwrap();
let record = parser.parse_record().unwrap();

// Encode with checksums
use lnmp_codec::EncoderConfig;
let config = EncoderConfig {
    enable_checksums: true,
    ..Default::default()
};
let encoder = Encoder::with_config(config);
let output = encoder.encode(&record);
// Output: F12=14532#36AAE667  (with checksum)

Lenient LLM-Friendly Parsing

use lnmp_codec::{Parser, TextInputMode, ParsingMode};
use lnmp_codec::binary::BinaryEncoder;

let messy = r#"F20=hello "world"; F40 = 3.14;F30=00042"#;

// Parser profile geared for LLM output
let mut parser = Parser::with_config(
    messy,
    lnmp_codec::config::ParserConfig {
        text_input_mode: TextInputMode::Lenient,
        mode: ParsingMode::Loose,
        normalize_values: true,
        ..Default::default()
    },
).unwrap();
let record = parser.parse_record().unwrap();

// Binary encoder also provides lenient/strict helpers
let encoder = BinaryEncoder::new();
let bytes = encoder.encode_text_llm_profile(messy).unwrap();

// For M2M strict flows use `Parser::new_strict` or `encode_text_strict_profile`.

LNMP v0.2 Features

Deterministic Serialization

Fields are always sorted by FID, ensuring consistent output:

let mut record = LnmpRecord::new();
record.add_field(LnmpField { fid: 30, value: LnmpValue::Int(3) });  // F30=count
record.add_field(LnmpField { fid: 7, value: LnmpValue::Int(1) });   // F7=is_active
record.add_field(LnmpField { fid: 12, value: LnmpValue::Int(2) });  // F12=user_id

let encoder = Encoder::new();
let output = encoder.encode(&record);
// Output: F7=1\nF12=2\nF30=3  (sorted by FID)
  • Arrays: [...]

    Note: Text parsing now honors typed hints—:ia, :fa, and :ba force integer, float, and boolean arrays respectively. Without a hint, the parser treats the array as StringArray, mirroring the binary encoder/decoder semantics.

Type Hints

Optional type annotations for explicit typing:

use lnmp_codec::{Encoder, EncoderConfig};

let config = EncoderConfig {
    include_type_hints: true,
    canonical: true,
};
let encoder = Encoder::with_config(config);
let output = encoder.encode(&record);
// Output: F12:i=14532\nF5:f=3.14\nF7:b=1

Strict vs Loose Parsing

use lnmp_codec::{Parser, ParsingMode};

// Loose mode (default): accepts format variations
let mut parser = Parser::new("F20=test;F7=1").unwrap();  // Unsorted, semicolons OK

// Strict mode: requires canonical format  
let mut parser = Parser::with_mode("F7=1\nF20=test", ParsingMode::Strict).unwrap();

// Strict input mode (no sanitizer)
let mut strict_input_parser = Parser::new_strict("F7=1\nF20=test").unwrap();

v0.3 Features

Nested Structures

Parse and encode hierarchical data:

use lnmp_codec::{Parser, Encoder};

// Nested record: F70={F12=1;F7=1} (F70=nested_data)
let input = "F70={F12=1;F7=1}";
let mut parser = Parser::new(input).unwrap();
let record = parser.parse_record().unwrap();

// Record array: F71=[{F20=alice},{F20=bob}] (F71=record_list, F20=name)
let input = "F71=[{F20=alice},{F20=bob}]";
let mut parser = Parser::new(input).unwrap();
let record = parser.parse_record().unwrap();

// Deep nesting (F70=nested_data)
let input = "F70={F20=user;F70={F30=nested;F31=data}}";
let mut parser = Parser::new(input).unwrap();
let record = parser.parse_record().unwrap();

Compliance & Lenient Test Suite

  • tests/compliance/rust contains the cross-language suite for strict flows.
  • tests/compliance/rust/test-cases-lenient.yaml mirrors the shared sanitizer behavior (auto-quote, comment trimming, nested repairs).
  • Run cargo test -p lnmp-codec --tests test-driver -- --nocapture to execute both strict and lenient suites.

The lenient path uses the lnmp-sanitize crate under the hood so SDKs (Rust/TS/Go/Python) can apply identical repair logic before calling strict parsers.

Profile Parser Config Binary Encoder Intended Use
LLM-facing text_input_mode = Lenient, mode = ParsingMode::Loose, normalize_values = true encode_text_llm_profile Repair user/LLM text before strict parsing
M2M strict Parser::new_strict() or ParserConfig { text_input_mode = Strict, mode = ParsingMode::Strict } encode_text_strict_profile Deterministic machine-to-machine pipelines
  • Rust exposes helpers (Parser::new_lenient, Parser::new_strict, binary profile methods).
  • TypeScript/Go/Python SDKs mirror the same defaults: LLMProfile (Lenient+Loose) for agent/model traffic and M2MProfile (Strict+Strict) for canonical pipelines.
  • All SDKs rely on the same sanitizer rules from lnmp-sanitize, ensuring identical repairs across languages.

Nested Structure Rules:

  • Nested records use {...} syntax with semicolon separators
  • Nested arrays use [{...},{...}] syntax
  • Fields sorted by FID at every nesting level
  • Arbitrary nesting depth supported

Semantic Checksums (SC32)

Enable checksums for drift prevention:

use lnmp_codec::{Encoder, EncoderConfig};

let config = EncoderConfig {
    enable_checksums: true,
    ..Default::default()
};
let encoder = Encoder::with_config(config);
let output = encoder.encode(&record);
// Output: F12:i=14532#36AAE667

// Parse and validate checksums
use lnmp_codec::{Parser, ParserConfig};
let config = ParserConfig {
    validate_checksums: true,
    ..Default::default()
};
let mut parser = Parser::with_config(input, config).unwrap();
let record = parser.parse_record().unwrap();  // Validates checksums

Value Normalization

Canonical value transformations:

use lnmp_codec::{ValueNormalizer, NormalizationConfig};

let config = NormalizationConfig {
    string_case: StringCaseRule::Lower,
    remove_trailing_zeros: true,
    ..Default::default()
};
let normalizer = ValueNormalizer::new(config);

// Normalizes: true → 1, -0.0 → 0.0, 3.140 → 3.14
let normalized = normalizer.normalize(&value);

Equivalence Mapping

Synonym recognition:

use lnmp_codec::EquivalenceMapper;

let mut mapper = EquivalenceMapper::new();
mapper.add_mapping(7, "yes".to_string(), "1".to_string());
mapper.add_mapping(7, "true".to_string(), "1".to_string());

// Maps "yes" → "1" for field 7
let canonical = mapper.map(7, "yes");  // Some("1")

Canonical Format Rules

v0.3 canonical format:

  • ✓ Fields sorted by FID at all nesting levels
  • ✓ Newline-separated (no semicolons at top level)
  • ✓ Semicolons required in nested records
  • ✓ No whitespace around equals signs
  • ✓ No spaces after commas in arrays
  • ✓ No comments (except in explain mode)
  • ✓ Checksums appended as #XXXXXXXX when enabled

Configuration Options

EncoderConfig

pub struct EncoderConfig {
    pub canonical: bool,              // Use canonical format
    pub include_type_hints: bool,     // Add type hints
    pub enable_checksums: bool,       // Append SC32 checksums (v0.3)
    pub normalization_config: Option<NormalizationConfig>,  // Value normalization (v0.3)
    pub equivalence_mapper: Option<EquivalenceMapper>,      // Synonym mapping (v0.3)
}

ParserConfig

pub struct ParserConfig {
    pub mode: ParsingMode,            // Strict or Loose
    pub validate_checksums: bool,     // Validate SC32 checksums (v0.3)
    pub equivalence_mapper: Option<EquivalenceMapper>,  // Synonym mapping (v0.3)
}

NormalizationConfig

pub struct NormalizationConfig {
    pub string_case: StringCaseRule,      // Lower, Upper, None
    pub float_precision: Option<usize>,   // Decimal places
    pub remove_trailing_zeros: bool,      // Remove trailing zeros
}

Migration from v0.2

v0.3 is backward compatible with v0.2. New features:

Feature v0.2 v0.3
Nested structures Not supported Supported
Checksums Not supported Optional SC32
Value normalization Not supported Configurable
Equivalence mapping Not supported Configurable
Type hints :i, :f, :b, :s, :sa + :r, :ra

Migration Guide

  1. Parsing: No changes needed - v0.3 parser accepts v0.2 format
  2. Encoding: New optional features (checksums, normalization)
  3. Nested structures: Use new NestedRecord and NestedArray variants
  4. Tests: Update for new value types if using nested structures
// v0.2 code (still works)
let encoder = Encoder::new();

// v0.3 code with new features
let config = EncoderConfig {
    enable_checksums: true,
    normalization_config: Some(NormalizationConfig::default()),
    ..Default::default()
};
let encoder = Encoder::with_config(config);

Performance Notes

  • Sorting overhead: Minimal - uses stable sort on encode
  • Memory: Sorted fields are cloned, original record unchanged
  • Parsing: Loose mode has same performance as v0.1

Binary Format Details (v0.4)

Binary Frame Structure

┌─────────┬─────────┬─────────────┬──────────────────────┐
│ VERSIONFLAGSENTRY_COUNTENTRIES...      │
│ (1 byte)(1 byte)(VarInt)(variable)       │
└─────────┴─────────┴─────────────┴──────────────────────┘

Each entry contains:

┌──────────┬──────────┬──────────────────┐
│   FIDTHTAGVALUE       │
│ (2 bytes)(1 byte)(variable)     │
└──────────┴──────────┴──────────────────┘

Supported Types

  • Integer (0x01): VarInt encoded signed 64-bit integers
  • Float (0x02): IEEE 754 double-precision (8 bytes, little-endian)
  • Boolean (0x03): Single byte (0x00 = false, 0x01 = true)
  • String (0x04): Length-prefixed UTF-8 (length as VarInt + bytes)
  • String Array (0x05): Count-prefixed array of length-prefixed strings

Binary Encoding Example

use lnmp_codec::binary::BinaryEncoder;
use lnmp_core::{LnmpRecord, LnmpField, LnmpValue};

let mut record = LnmpRecord::new();
record.add_field(LnmpField {
    fid: 7,
    value: LnmpValue::Bool(true),
});
record.add_field(LnmpField {
    fid: 12,
    value: LnmpValue::Int(14532),
});

let encoder = BinaryEncoder::new();
let binary = encoder.encode(&record).unwrap();
// Binary format: [0x04, 0x00, 0x02, ...] (version, flags, entry count, entries)

Configuration Options

use lnmp_codec::binary::{BinaryEncoder, BinaryDecoder, EncoderConfig, DecoderConfig};

// Encoder configuration
let encoder_config = EncoderConfig::new()
    .with_validate_canonical(true)
    .with_sort_fields(true);
let encoder = BinaryEncoder::with_config(encoder_config);

// Decoder configuration
let decoder_config = DecoderConfig::new()
    .with_validate_ordering(true)  // Enforce canonical field order
    .with_strict_parsing(true);    // Detect trailing data
let decoder = BinaryDecoder::with_config(decoder_config);

Performance Characteristics

  • Space Efficiency: 30-50% size reduction compared to text format
  • Encoding Speed: < 1μs per field for simple types
  • Decoding Speed: < 1μs per field for simple types
  • Round-trip: < 10μs for typical 10-field record

Zero-Copy Decoding (v0.5)

The decode_view() API enables zero-copy parsing for high-throughput scenarios like routing, filtering, and logging. Instead of allocating owned values, it borrows directly from the input buffer.

When to Use

Use Case API Reason
Routing/Filtering decode_view() Decision based on field values without full parse
Logging/Monitoring decode_view() Extract trace ID, timestamps without allocation
Proxying/Forwarding decode_view() Inspect headers, forward payload unchanged
Processing/Storage decode() Need to mutate, persist, or own the data

Performance Comparison

Based on cargo bench --bench zero_copy_bench (v0.5.15):

Payload Type decode() decode_view() Speedup
Small (3 fields, ~22 bytes) ~248 ns ~92 ns 2.70x
Medium (strings + ints, ~100 bytes) ~610 ns ~164 ns 3.71x
Large (10KB string + embedding) ~18.3 μs ~2.1 μs 8.91x

Throughput Comparison:

Scenario Standard Zero-Copy Improvement
Small records 0.09 GiB/s 0.24 GiB/s +170%
Medium records 0.16 GiB/s 0.59 GiB/s +271%
Large records 0.12 GiB/s 1.04 GiB/s +791%

Batch Processing (1000 records):

  • Standard decode: 165 μs
  • Zero-copy view: 55 μs
  • 3x faster batch throughput

Basic Usage

use lnmp_codec::binary::BinaryDecoder;
use lnmp_core::LnmpValueView;

let decoder = BinaryDecoder::new();
let bytes = vec![...]; // From network/file

// Create zero-copy view (borrows from 'bytes')
let view = decoder.decode_view(&bytes).unwrap();

// Access fields without allocation
for field in view.fields() {
    match &field.value {
        LnmpValueView::String(s) => {
            println!("String: {}", s);  // s is &str (borrowed!)
        }
        LnmpValueView::Embedding(raw) => {
            println!("Embedding: {} bytes", raw.len());  // raw is &[u8]
        }
        _ => {}
    }
}

Example: High-Throughput Router

use lnmp_codec::binary::BinaryDecoder;
use lnmp_core::LnmpValueView;

let decoder = BinaryDecoder::new();

// Process 1M+ messages/sec without allocation
for payload in incoming_messages {
    let view = decoder.decode_view(&payload)?;
    
    // Zero-copy field inspection
    if let Some(field) = view.get_field(50) { // F50: status
        match &field.value {
            LnmpValueView::String(status) if *status == "critical" => {
                route_to_llm(&payload)?;
            }
            _ => route_locally(&payload)?
        }
    }
}

Example: Trace ID Extraction

use lnmp_codec::binary::BinaryDecoder;
use lnmp_core::LnmpValueView;

fn extract_trace_id(bytes: &[u8]) -> Option<&str> {
    let decoder = BinaryDecoder::new();
    let view = decoder.decode_view(bytes).ok()?;
    
    // Zero-copy trace ID access (F80)
    if let Some(field) = view.get_field(80) {
        if let LnmpValueView::String(trace_id) = &field.value {
            return Some(trace_id);  // Returns &str (zero-copy!)
        }
    }
    None
}

// Usage in HTTP middleware
let trace_id = extract_trace_id(&request_body)?;
println!("Trace-ID: {}", trace_id);  // No allocation

Zero-Copy Limitations

Type Zero-Copy Notes
String ✅ Full Returns &str borrowed from input
StringArray ✅ Full Returns Vec<&str> (only refs allocated)
Embedding ✅ Lazy Returns &[u8] raw bytes (parse on demand)
Int/Float/Bool ✅ Natural Scalars copied (4-8 bytes, negligible)
IntArray ❌ Allocates VarInt encoding requires parse → Vec<i64>
FloatArray ❌ Allocates VarInt length + values → Vec<f64>
BoolArray ❌ Allocates Byte-per-bool → Vec<bool>
Nested ⚠️ Partial Currently allocates (future: zero-copy traversal)

Why IntArray allocates:
VarInt encoding stores integers as variable-length sequences. To access [1, 2, 3], the decoder must parse each VarInt, which requires allocation. Future versions will support packed (fixed-width) arrays for zero-copy access.

Advanced: Content-Based Routing

See examples/zero_copy_routing.rs for a complete routing example with benchmarks.

cargo run -p lnmp-codec --example zero_copy_routing

Expected Output:

=== Zero-Copy Routing Demo ===
Critical message → ROUTE_TO_LLM
Normal message → ROUTE_LOCALLY

=== Performance (100k iterations) ===
Standard decode: 210ms (2.10 μs/iter)
Zero-copy view:  90ms (0.90 μs/iter)
Speedup: 2.33x faster

Migration Guide

Before (Standard decode):

let record = decoder.decode(&bytes)?;
if let Some(field) = record.get_field(50) {
    match &field.value {
        LnmpValue::String(s) => process(s),  // s is String (owned)
        _ => {}
    }
}

After (Zero-copy view):

let view = decoder.decode_view(&bytes)?;
if let Some(field) = view.get_field(50) {
    match &field.value {
        LnmpValueView::String(s) => process(s),  // s is &str (borrowed)
        _ => {}
    }
}

Key Difference:

  • LnmpValue::String(String)LnmpValueView::String(&str)
  • Must convert to owned if needed: s.to_string()

Future Enhancements (v0.6+)

  • Sparse array encoding: Compressed storage for sparse vectors
  • Nested zero-copy: Traverse nested structures without allocation
  • SIMD similarity: Direct cosine similarity on embedding views

Use decode_view() for maximum throughput. Use decode() when you need to own/mutate the data.

v0.5.14 Features

Dynamic FID Discovery Protocol

Query and synchronize FID registries between peers at runtime:

use lnmp_codec::binary::{SchemaNegotiator, FidDefinition, FidDefStatus, TypeTag};

// Create registry-aware negotiator
let mut negotiator = SchemaNegotiator::v0_5()
    .with_registry_version("1.0.0".into());

// Request peer's FID registry
let request = negotiator.request_registry(None);

// Handle registry response
let fids = vec![
    FidDefinition {
        fid: 12,
        name: "user_id".into(),
        type_tag: TypeTag::Int,
        status: FidDefStatus::Active,
        since: "0.1.0".into(),
    },
];
negotiator.handle_registry_response("1.0.0".into(), fids);

// Check FID support
if negotiator.peer_supports_fid(12) {
    println!("Peer understands user_id field");
}

New Message Types:

  • RequestRegistry - Query peer FID definitions
  • RegistryResponse - Full registry response
  • RegistryDelta - Incremental sync

Encoder FID Validation

Validate fields before encoding:

use lnmp_codec::{Encoder, EncoderConfig};
use lnmp_core::registry::{embedded_registry, ValidationMode};

let config = EncoderConfig::new()
    .with_fid_registry(embedded_registry())
    .with_fid_validation_mode(ValidationMode::Error);

let encoder = Encoder::with_config(config);
let result = encoder.encode_validated(&record);  // Returns error on invalid FID

Examples

This crate includes several examples in the examples/ directory:

Run examples with:

cargo run --example parse_simple -p lnmp-codec
cargo run --example encode_with_hints -p lnmp-codec

See the root examples/ directory for integration examples and v0.4 binary format demos.

License

MIT OR Apache-2.0

Dependencies

~2.7–4MB
~74K SLoC