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zeefaad
2026-06-01 09:19:46 +02:00
parent ee8940fae5
commit 7a47e62791
8 changed files with 36918 additions and 21563 deletions
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57386
main.pdf
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main.typ
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#import "composants.typ": *
#import "@preview/touying:0.5.2": *
// #import "@preview/touying:0.5.2": *
#import "code_slides.typ": generer_slides_code
#set page(
@ -26,6 +26,7 @@
#text(size: 3em, weight: "bold", fill: black)[#titre]
#text(size: 1.2em, weight: "bold", fill: black)[#auteur]
t
#h(0.5em)
@ -2161,7 +2162,11 @@
"src/rs/decoder.rs",
"src/rs/generator.rs",
"src/rs/channel.rs",
"src/rs/graph.rs",
"src/rs/matrix.rs",
"src/rs/benchmark.rs",
"src/rs/benchmark2.rs",
"src/rs/image_sim.rs",
"src/rs/lib.rs",
),
myslide,

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use crate::channel::{AwgnChannel, Channel};
use crate::code::{CodeTopology, GenerationMethod, LdpcCode, LdpcParams};
use crate::decoder::{build_decoder, DecoderConfig, DecoderMethod};
use crate::encoder::{build_encoder, EncodingMethod};
use crate::Result as LdpcResult;
use rand::Rng;
use rayon::prelude::*;
use std::fs::File;
use std::io::{Read, Write};
use std::path::Path;
use std::time::Instant;
pub fn run_simulation(mut code: LdpcCode) -> LdpcResult<()> {
println!("[*] Étape 1 : Construction Mathématique et Graphe de Tanner");
println!(
" - Dimensions : n={}, k={}, m={} (Taux R={:.3})",
code.n(),
code.k(),
code.m(),
code.rate()
);
let methode_nom = match code.params.generation {
GenerationMethod::MacKayNeal { .. } => "MacKay-Neal",
GenerationMethod::Gallager => "Gallager",
};
println!(" - Topologie : Régulier via {}", methode_nom);
println!(" - Densité H : {:.2}%", code.h.density() * 100.0);
println!(" - Girth : {}", code.girth());
println!(
" - Cycles-4 : {}",
if code.graph.has_4_cycle() {
"Présents (Problématique)"
} else {
"Aucun (Optimal)"
}
);
println!("\n[*] Étape 2 : Instanciation de l'Encodeur (SIMD Bit-Packing)");
let start_enc = Instant::now();
let encoder = build_encoder(&mut code, EncodingMethod::Systematic)?;
println!(" - Encodeur prêt en {:.2?}", start_enc.elapsed());
println!("\n[*] Étape 3 : Instanciation des Décodeurs sur Graphe");
let config = DecoderConfig {
max_iterations: 50,
early_stopping: true,
};
let dec_sp = build_decoder(&code, DecoderMethod::SumProduct, config.clone());
let dec_ms = build_decoder(
&code,
DecoderMethod::MinSum {
scaling_factor: 0.8,
},
config.clone(),
);
let dec_bf = build_decoder(&code, DecoderMethod::BitFlipping, config.clone());
println!(" - Moteurs prêts : Sum-Product, Min-Sum (α=0.8), Bit-Flipping");
let snr_range = [1.0, 1.25, 1.5, 1.75, 2.0, 2.25, 2.5, 3.0, 3.5, 4.0];
let n_trials = 1000;
println!(
"\n[*] Étape 4 : Simulation sur Canal AWGN ({} trames par SNR, Multi-threadé)",
n_trials
);
println!("{:-<115}", "");
println!(
"{:>8} | {:>9} || {:>10} | {:>10} || {:>10} | {:>10} || {:>10} | {:>10} |",
"SNR (dB)",
"Capacité",
"FER (SP)",
"BER (SP)",
"FER (MS)",
"BER (MS)",
"FER (BF)",
"BER (BF)"
);
println!("{:-<115}", "");
for &snr in &snr_range {
let channel = AwgnChannel::new(snr, code.rate())?;
let results: Vec<_> = (0..n_trials)
.into_par_iter()
.map(|_| {
let mut rng = rand::thread_rng();
let message: Vec<u8> = (0..code.k()).map(|_| rng.gen::<u8>() & 1).collect();
let codeword = encoder.encode(&message).unwrap();
let received_llr = channel.transmit(&codeword, &mut rng);
let mut t_sp_f = 0;
let mut t_sp_b = 0;
let mut t_ms_f = 0;
let mut t_ms_b = 0;
let mut t_bf_f = 0;
let mut t_bf_b = 0;
// SP
let res_sp = dec_sp.decode(&received_llr);
if let Some(decoded) = res_sp.codeword() {
let errs = count_bit_errors(&codeword, decoded);
if errs > 0 {
t_sp_f = 1;
t_sp_b = errs;
}
} else {
t_sp_f = 1;
t_sp_b = code.n();
}
// MS
let res_ms = dec_ms.decode(&received_llr);
if let Some(decoded) = res_ms.codeword() {
let errs = count_bit_errors(&codeword, decoded);
if errs > 0 {
t_ms_f = 1;
t_ms_b = errs;
}
} else {
t_ms_f = 1;
t_ms_b = code.n();
}
// BF
let res_bf = dec_bf.decode(&received_llr);
if let Some(decoded) = res_bf.codeword() {
let errs = count_bit_errors(&codeword, decoded);
if errs > 0 {
t_bf_f = 1;
t_bf_b = errs;
}
} else {
t_bf_f = 1;
t_bf_b = code.n();
}
(t_sp_f, t_sp_b, t_ms_f, t_ms_b, t_bf_f, t_bf_b)
})
.collect();
// Agrégation
let mut err_sp_frames = 0;
let mut err_sp_bits = 0;
let mut err_ms_frames = 0;
let mut err_ms_bits = 0;
let mut err_bf_frames = 0;
let mut err_bf_bits = 0;
for res in results {
err_sp_frames += res.0;
err_sp_bits += res.1;
err_ms_frames += res.2;
err_ms_bits += res.3;
err_bf_frames += res.4;
err_bf_bits += res.5;
}
let total_bits = (n_trials * code.n()) as f64;
let total_frames = n_trials as f64;
println!(
"{:>8.2} | {:>9.4} || {:>9.2}% | {:>9.2}% || {:>9.2}% | {:>9.2}% || {:>9.2}% | {:>9.2}% |",
snr, channel.capacity(),
(err_sp_frames as f64 / total_frames) * 100.0, (err_sp_bits as f64 / total_bits) * 100.0,
(err_ms_frames as f64 / total_frames) * 100.0, (err_ms_bits as f64 / total_bits) * 100.0,
(err_bf_frames as f64 / total_frames) * 100.0, (err_bf_bits as f64 / total_bits) * 100.0
);
}
println!("{:-<115}", "");
Ok(())
}
#[inline]
fn count_bit_errors(transmitted: &[u8], decoded: &[u8]) -> usize {
transmitted
.iter()
.zip(decoded.iter())
.filter(|(a, b)| a != b)
.count()
}
// pub fn generate_valid_code(
// n: usize,
// k: usize,
// wc: usize,
// wr: usize,
// generation_method: GenerationMethod,
// ) -> LdpcResult<LdpcCode> {
// let mut attempt = 0;
// let start_gen = Instant::now();
// loop {
// attempt += 1;
// let params = LdpcParams {
// n,
// k,
// topology: CodeTopology::Regular { wc, wr },
// generation: generation_method.clone(),
// seed: Some(rand::random()),
// };
//
// if let Ok(mut code) = LdpcCode::new(params) {
// if code.compute_systematic_form().is_ok() {
// if attempt > 1 {
// println!(
// " -> Matrice inversible obtenue après {} tentatives.",
// attempt
// );
// }
// println!(" - Génération : Terminée en {:.2?}", start_gen.elapsed());
// return Ok(code);
// }
// }
// }
// }
pub fn get_or_generate_cached_code(
n: usize,
k: usize,
wc: usize,
wr: usize,
generation_method: GenerationMethod,
) -> LdpcResult<LdpcCode> {
let method_str = match generation_method {
GenerationMethod::MacKayNeal { .. } => "MN",
GenerationMethod::Gallager => "GAL",
};
let cache_filename = format!("cache_ldpc_{}_n{}_k{}.bin", method_str, n, k);
let path = Path::new(&cache_filename);
// Chargement
if path.exists() {
let start_load = Instant::now();
let mut file = File::open(&path).expect("Impossible d'ouvrir le fichier de cache");
let mut buffer = Vec::new();
file.read_to_end(&mut buffer).unwrap();
let mut code: LdpcCode = bincode::deserialize(&buffer).expect(
"Erreur de désérialisation du cache LDPC. Supprimez le fichier .bin et réessayez.",
);
// Reconstruction du Graphe de Tanner
code.graph = crate::graph::TannerGraph::from_matrix(&code.h);
println!(
" -> Matrice chargée depuis le cache en {:.2?}",
start_load.elapsed()
);
return Ok(code);
}
// Génération
println!(" -> Aucun cache trouvé. Génération en cours ...");
let mut attempt = 0;
let start_gen = Instant::now();
loop {
attempt += 1;
let params = LdpcParams {
n,
k,
topology: CodeTopology::Regular { wc, wr },
generation: generation_method.clone(),
seed: Some(rand::random()),
};
if let Ok(mut code) = LdpcCode::new(params) {
if code.compute_systematic_form().is_ok() {
println!(
" - Génération et Pivot de Gauss terminés en {:.2?}",
start_gen.elapsed()
);
// sauvegarde cache
let encoded = bincode::serialize(&code).expect("Échec de la sérialisation");
let mut file =
File::create(&path).expect("Impossible de créer le fichier de cache");
file.write_all(&encoded)
.expect("Impossible d'écrire sur le disque");
println!(" -> Matrice sauvegardée ({})", cache_filename);
return Ok(code);
}
}
}
}

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use crate::benchmark::get_or_generate_cached_code;
use crate::channel::{AwgnChannel, Channel};
use crate::code::GenerationMethod;
use crate::decoder::{build_decoder, DecoderConfig, DecoderMethod};
use crate::encoder::{build_encoder, EncodingMethod};
use crate::Result as LdpcResult;
use indicatif::{ProgressBar, ProgressStyle};
use rand::Rng;
use rayon::prelude::*;
use std::fs::OpenOptions;
use std::io::Write;
use std::time::Instant;
#[derive(Clone)]
pub struct CodeScenario {
pub n: usize,
pub k: usize,
pub wc: usize,
pub wr: usize,
pub method: GenerationMethod,
pub name: String,
}
pub struct CampaignConfig {
pub scenarios: Vec<CodeScenario>,
pub snr_range: Vec<f64>,
pub n_trials: usize,
pub max_iterations: usize,
pub output_csv: String,
pub export_graph: bool,
}
pub fn run_massive_campaign(config: CampaignConfig) -> LdpcResult<()> {
println!("TEST)");
println!("Fichier de sortie : {}", config.output_csv);
println!("Scenarios a tester: {}", config.scenarios.len());
println!("SNRs par scenario : {}", config.snr_range.len());
println!("Trames par point : {}\n", config.n_trials);
let file_exists = std::path::Path::new(&config.output_csv).exists();
let mut file = OpenOptions::new()
.create(true)
.append(true)
.open(&config.output_csv)
.expect("Impossible d'ouvrir le fichier CSV");
if !file_exists {
writeln!(
file,
"Scenario,N,K,Rate,Wc,Wr,Method,Girth,Density_pct,SNR_dB,Capacity,Decoder,FER_pct,BER_pct,Frames,Time_ms"
).unwrap();
}
let total_steps = (config.scenarios.len() * config.snr_range.len()) as u64;
let pb = ProgressBar::new(total_steps);
pb.set_style(
ProgressStyle::default_bar()
.template("{spinner:.cyan} [{elapsed_precise}] [{bar:40.green/blue}] {pos}/{len} ({eta}) - {msg}")
.unwrap()
.progress_chars("=>-"),
);
for scenario in config.scenarios {
pb.set_message(format!("Generation Matrice: {}", scenario.name));
let mut code = get_or_generate_cached_code(
scenario.n,
scenario.k,
scenario.wc,
scenario.wr,
scenario.method.clone(),
)?;
if config.export_graph {
let dot_filename = format!("{}_tanner.dot", scenario.name);
let mut dot_file = std::fs::File::create(&dot_filename).expect("Erreur creation .dot");
writeln!(dot_file, "graph TannerGraph {{").unwrap();
writeln!(dot_file, " rankdir=TB;").unwrap();
writeln!(dot_file, " nodesep=0.5;").unwrap();
writeln!(dot_file, " ranksep=2.0;").unwrap();
writeln!(dot_file, " node [style=filled, fontname=\"Arial\"];").unwrap();
writeln!(dot_file, " {{ rank=same;").unwrap();
for v in 0..code.n() {
writeln!(
dot_file,
" v{} [shape=circle, fillcolor=lightblue, label=\"v{}\"];",
v, v
)
.unwrap();
}
writeln!(dot_file, " }}").unwrap();
writeln!(dot_file, " {{ rank=same;").unwrap();
for c in 0..code.m() {
writeln!(
dot_file,
" c{} [shape=square, fillcolor=lightcoral, label=\"c{}\"];",
c, c
)
.unwrap();
}
writeln!(dot_file, " }}").unwrap();
for c in 0..code.m() {
for &v in code.graph.chk_neighbors(c) {
writeln!(dot_file, " v{} -- c{};", v, c).unwrap();
}
}
writeln!(dot_file, "}}").unwrap();
}
let rate = code.rate();
let girth = code.girth();
let density = code.h.density() * 100.0;
let method_str = match scenario.method {
GenerationMethod::Gallager => "Gallager",
GenerationMethod::MacKayNeal { .. } => "MacKayNeal",
};
pb.set_message(format!("Initialisation DSP: {}", scenario.name));
let encoder = build_encoder(&mut code, EncodingMethod::Systematic)?;
let dec_config = DecoderConfig {
max_iterations: config.max_iterations,
early_stopping: true,
};
let dec_sp = build_decoder(&code, DecoderMethod::SumProduct, dec_config.clone());
let dec_ms = build_decoder(
&code,
DecoderMethod::MinSum {
scaling_factor: 0.8,
},
dec_config.clone(),
);
let dec_bf = build_decoder(&code, DecoderMethod::BitFlipping, dec_config);
for &snr in &config.snr_range {
pb.set_message(format!("Test: {} | SNR: {:.2} dB", scenario.name, snr));
let channel = AwgnChannel::new(snr, rate)?;
let cap = channel.capacity();
let start_snr_time = Instant::now();
let results: Vec<_> = (0..config.n_trials)
.into_par_iter()
.map(|_| {
let mut rng = rand::thread_rng();
let message: Vec<u8> = (0..scenario.k).map(|_| rng.gen::<u8>() & 1).collect();
let codeword = encoder.encode(&message).unwrap();
let rx_llr = channel.transmit(&codeword, &mut rng);
let eval_decoder = |decoder: &dyn crate::decoder::Decoder| -> (usize, usize) {
if let Some(decoded) = decoder.decode(&rx_llr).codeword() {
let errs = codeword
.iter()
.zip(decoded.iter())
.filter(|(a, b)| a != b)
.count();
(if errs > 0 { 1 } else { 0 }, errs)
} else {
(1, scenario.n)
}
};
let (sp_f, sp_b) = eval_decoder(&*dec_sp);
let (ms_f, ms_b) = eval_decoder(&*dec_ms);
let (bf_f, bf_b) = eval_decoder(&*dec_bf);
(sp_f, sp_b, ms_f, ms_b, bf_f, bf_b)
})
.collect();
let mut sp_err = (0, 0);
let mut ms_err = (0, 0);
let mut bf_err = (0, 0);
for r in results {
sp_err.0 += r.0;
sp_err.1 += r.1;
ms_err.0 += r.2;
ms_err.1 += r.3;
bf_err.0 += r.4;
bf_err.1 += r.5;
}
let elapsed_ms = start_snr_time.elapsed().as_millis();
let total_f = config.n_trials as f64;
let total_b = (config.n_trials * scenario.n) as f64;
let mut write_csv_line = |dec_name: &str, f_err: usize, b_err: usize| {
writeln!(
file,
"{},{},{},{:.3},{},{},{},{},{:.4},{:.2},{:.4},{},{:.4},{:.4e},{},{}",
scenario.name,
scenario.n,
scenario.k,
rate,
scenario.wc,
scenario.wr,
method_str,
girth,
density,
snr,
cap,
dec_name,
(f_err as f64 / total_f) * 100.0,
(b_err as f64 / total_b) * 100.0,
config.n_trials,
elapsed_ms
)
.unwrap();
};
write_csv_line("SumProduct", sp_err.0, sp_err.1);
write_csv_line("MinSum_0.8", ms_err.0, ms_err.1);
write_csv_line("BitFlipping", bf_err.0, bf_err.1);
file.flush().unwrap();
pb.inc(1);
}
}
pb.finish_with_message("Campagne terminee avec succes !");
Ok(())
}

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use crate::matrix::SparseMatrixGF2;
use std::collections::VecDeque;
// Graphe de Tanner
#[derive(Debug, Clone)]
pub struct TannerGraph {
pub n_var: usize,
pub n_chk: usize,
var_to_chk: Vec<Vec<usize>>,
chk_to_var: Vec<Vec<usize>>,
}
impl TannerGraph {
pub fn from_matrix(h: &SparseMatrixGF2) -> Self {
let n_var = h.cols;
let n_chk = h.rows;
let chk_to_var: Vec<Vec<usize>> = (0..n_chk).map(|c| h.row_neighbors(c).to_vec()).collect();
let mut var_to_chk = vec![vec![]; n_var];
for c in 0..n_chk {
for &v in &chk_to_var[c] {
var_to_chk[v].push(c);
}
}
Self {
n_var,
n_chk,
var_to_chk,
chk_to_var,
}
}
pub fn var_neighbors(&self, v: usize) -> &[usize] {
&self.var_to_chk[v]
}
pub fn chk_neighbors(&self, c: usize) -> &[usize] {
&self.chk_to_var[c]
}
pub fn var_degree(&self, v: usize) -> usize {
self.var_to_chk[v].len()
}
pub fn chk_degree(&self, c: usize) -> usize {
self.chk_to_var[c].len()
}
// Calcule le girth par BFS depuis chaque noeud de variable
pub fn girth(&self) -> usize {
let mut min_girth = usize::MAX;
for start in 0..self.n_var {
if let Some(g) = self.bfs_girth_from_var(start) {
min_girth = min_girth.min(g);
if min_girth == 4 {
return 4;
} // minimum
}
}
min_girth
}
// Détection cycles-4, 2 varnodes partagent >= check-nodes
pub fn has_4_cycle(&self) -> bool {
for v1 in 0..self.n_var {
for v2 in (v1 + 1)..self.n_var {
let common = self.var_to_chk[v1]
.iter()
.filter(|c| self.var_to_chk[v2].contains(c))
.count();
if common >= 2 {
return true;
}
}
}
false
}
pub fn local_girth_from_var(&self, v: usize) -> usize {
self.bfs_girth_from_var(v).unwrap_or(usize::MAX)
}
// retourne la longueur du court cycle passant par ce noeud (None si pas cycle)
fn bfs_girth_from_var(&self, start: usize) -> Option<usize> {
let mut dist_var = vec![usize::MAX; self.n_var];
let mut dist_chk = vec![usize::MAX; self.n_chk];
dist_var[start] = 0;
// File (is_var, index, distance, parent_index)
let mut queue: VecDeque<(bool, usize, usize, usize)> = VecDeque::new();
queue.push_back((true, start, 0, usize::MAX));
let mut shortest = None;
while let Some((is_var, node, dist, parent)) = queue.pop_front() {
if is_var {
for &c in self.var_neighbors(node) {
if c == parent {
continue;
} // aller retour immédiat impossible
if dist_chk[c] == usize::MAX {
dist_chk[c] = dist + 1;
queue.push_back((false, c, dist + 1, node));
} else {
let cycle_len = dist + 1 + dist_chk[c];
shortest = Some(shortest.map_or(cycle_len, |s: usize| s.min(cycle_len)));
}
}
} else {
for &v in self.chk_neighbors(node) {
if v == parent {
continue;
} // aller retour immédiat impossible
if v == start {
let cycle_len = dist + 1;
shortest = Some(shortest.map_or(cycle_len, |s: usize| s.min(cycle_len)));
continue;
}
if dist_var[v] == usize::MAX {
dist_var[v] = dist + 1;
queue.push_back((true, v, dist + 1, node));
}
}
}
}
shortest
}
pub fn var_degree_distribution(&self) -> Vec<f64> {
let max_deg = self.var_to_chk.iter().map(|v| v.len()).max().unwrap_or(0);
let mut counts = vec![0usize; max_deg + 1];
for v in 0..self.n_var {
counts[self.var_degree(v)] += 1;
}
counts
.iter()
.map(|&c| c as f64 / self.n_var as f64)
.collect()
}
pub fn is_regular(&self) -> bool {
let d0 = self.var_degree(0);
let c0 = self.chk_degree(0);
self.var_to_chk.iter().all(|v| v.len() == d0)
&& self.chk_to_var.iter().all(|c| c.len() == c0)
}
}

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use crate::{
channel::{AwgnChannel, Channel},
decoder::Decoder,
encoder::Encoder,
Gf2, Result,
};
use image::{ImageBuffer, Rgb};
use indicatif::{ProgressBar, ProgressStyle};
use rayon::prelude::*;
use std::time::Instant;
// Convertit un tableau d'octets en un flux de bits
pub fn bytes_to_bits(bytes: &[u8]) -> Vec<Gf2> {
let mut bits = Vec::with_capacity(bytes.len() * 8);
for &byte in bytes {
for i in (0..8).rev() {
bits.push((byte >> i) & 1);
}
}
bits
}
// Convertit un flux de bits en tableau d'octets
pub fn bits_to_bytes(bits: &[Gf2]) -> Vec<u8> {
let mut bytes = Vec::with_capacity(bits.len() / 8);
for chunk in bits.chunks(8) {
let mut byte = 0u8;
for (i, &bit) in chunk.iter().enumerate() {
byte |= bit << (7 - i);
}
bytes.push(byte);
}
bytes
}
// Transmet une image à travers le canal avec codage LDPC
// pub fn transmit_image(
// input_path: &str,
// noisy_out_path: &str,
// decoded_out_path: &str,
// encoder: &dyn Encoder,
// decoder: &dyn Decoder,
// channel: &AwgnChannel,
// ) -> Result<()> {
// println!("[*] Chargement de l'image : {}", input_path);
// let img = image::open(input_path)
// .expect("Erreur de chargement de l'image")
// .to_rgb8();
// let (width, height) = img.dimensions();
// let raw_bytes = img.into_raw();
//
// let mut bits = bytes_to_bits(&raw_bytes);
// let original_bit_len = bits.len();
//
// // Padding
// let k = encoder.message_len();
// let remainder = bits.len() % k;
// if remainder != 0 {
// bits.resize(bits.len() + (k - remainder), 0);
// }
//
// let num_blocks = bits.len() / k;
// println!(" - Taille: {}x{} pixels", width, height);
// println!(" - Blocs à transmettre (k={}): {}", k, num_blocks);
//
// let mut rng = rand::rngs::StdRng::seed_from_u64(42);
//
// let mut noisy_bits = Vec::with_capacity(num_blocks * k);
// let mut decoded_bits = Vec::with_capacity(num_blocks * k);
//
// let mut frame_errors = 0;
//
// println!("[*] Transmission et Décodage en cours...");
//
// for (i, block) in bits.chunks(k).enumerate() {
// if i % 100 == 0 && i > 0 {
// println!(" - Progession: {} / {} blocs...", i, num_blocks);
// }
//
// let codeword = encoder.encode(block)?;
//
// let rx_llr = channel.transmit(&codeword, &mut rng);
//
// // Sans correction LDPC
// let hard_codeword: Vec<Gf2> = rx_llr
// .iter()
// .map(|&l| if l < 0.0 { 1 } else { 0 })
// .collect();
// let noisy_block = encoder.extract_message(&hard_codeword);
// noisy_bits.extend_from_slice(&noisy_block);
//
// // Décodage LDPC
// let res = decoder.decode(&rx_llr);
// if let Some(decoded_codeword) = res.codeword() {
// let decoded_msg = encoder.extract_message(decoded_codeword);
// decoded_bits.extend_from_slice(&decoded_msg);
//
// if decoded_msg != block {
// frame_errors += 1;
// }
// } else {
// decoded_bits.extend_from_slice(&noisy_block);
// frame_errors += 1;
// }
// }
//
// println!(
// "[*] Transmission terminée. FER : {:.2}%",
// (frame_errors as f64 / num_blocks as f64) * 100.0
// );
//
// // Suppression du padding
// noisy_bits.truncate(original_bit_len);
// decoded_bits.truncate(original_bit_len);
//
// // Reconstitution des images
// let noisy_bytes = bits_to_bytes(&noisy_bits);
// let decoded_bytes = bits_to_bytes(&decoded_bits);
//
// let noisy_img = ImageBuffer::<Rgb<u8>, _>::from_raw(width, height, noisy_bytes)
// .expect("Erreur de reconstruction de l'image bruitée");
// noisy_img.save(noisy_out_path).unwrap();
//
// let decoded_img = ImageBuffer::<Rgb<u8>, _>::from_raw(width, height, decoded_bytes)
// .expect("Erreur de reconstruction de l'image décodée");
// decoded_img.save(decoded_out_path).unwrap();
//
// println!(
// "[*] Images sauvegardées : {} et {}",
// noisy_out_path, decoded_out_path
// );
// Ok(())
// }
pub fn transmit_image(
input_path: &str,
noisy_out_path: &str,
decoded_out_path: &str,
encoder: &dyn Encoder,
decoder: &dyn Decoder,
channel: &AwgnChannel,
) -> Result<()> {
println!("\n[*] Chargement de l'image : {}", input_path);
let img = image::open(input_path)
.expect("Erreur : Impossible de trouver ou lire l'image")
.to_rgb8();
let (width, height) = img.dimensions();
let raw_bytes = img.into_raw();
let mut bits = bytes_to_bits(&raw_bytes);
let original_bit_len = bits.len();
let k = encoder.message_len();
let remainder = bits.len() % k;
if remainder != 0 {
bits.resize(bits.len() + (k - remainder), 0);
}
let num_blocks = bits.len() / k;
println!(" - Résolution : {}x{} pixels", width, height);
println!(
" - Poids total : {:.2} Mo",
raw_bytes.len() as f64 / 1_048_576.0
);
println!(" - Découpage en : {} blocs de {} bits\n", num_blocks, k);
let start_time = Instant::now();
let pb = ProgressBar::new(num_blocks as u64);
pb.set_style(
ProgressStyle::default_bar()
.template("{spinner:.green} [{elapsed_precise}] [{bar:40.cyan/blue}] {pos}/{len} blocs ({eta})")
.unwrap()
.progress_chars("=>-")
);
let results: Vec<_> = bits
.par_chunks(k)
.map(|block| {
let mut rng = rand::thread_rng();
let codeword = encoder.encode(block).unwrap();
let rx_llr = channel.transmit(&codeword, &mut rng);
let hard_codeword: Vec<Gf2> = rx_llr
.iter()
.map(|&l| if l < 0.0 { 1 } else { 0 })
.collect();
let noisy_block = encoder.extract_message(&hard_codeword);
let res = decoder.decode(&rx_llr);
let (decoded_block, has_error) = if let Some(decoded_codeword) = res.codeword() {
let decoded_msg = encoder.extract_message(decoded_codeword);
let err = if decoded_msg != block { 1 } else { 0 };
(decoded_msg, err)
} else {
(noisy_block.clone(), 1)
};
pb.inc(1);
(noisy_block, decoded_block, has_error)
})
.collect();
pb.finish_with_message("Décodage terminé !");
let mut noisy_bits = Vec::with_capacity(num_blocks * k);
let mut decoded_bits = Vec::with_capacity(num_blocks * k);
let mut frame_errors = 0;
for (n_block, d_block, err) in results {
noisy_bits.extend_from_slice(&n_block);
decoded_bits.extend_from_slice(&d_block);
frame_errors += err;
}
let duration = start_time.elapsed();
let fer = (frame_errors as f64 / num_blocks as f64) * 100.0;
println!("[*] Transmission terminée en {:.2?}", duration);
println!(" - Taux d'Erreur Trame (FER) : {:.2}%", fer);
noisy_bits.truncate(original_bit_len);
decoded_bits.truncate(original_bit_len);
let noisy_bytes = bits_to_bytes(&noisy_bits);
let decoded_bytes = bits_to_bytes(&decoded_bits);
let noisy_img = ImageBuffer::<Rgb<u8>, _>::from_raw(width, height, noisy_bytes)
.expect("Erreur de reconstruction de l'image bruitée");
noisy_img.save(noisy_out_path).unwrap();
let decoded_img = ImageBuffer::<Rgb<u8>, _>::from_raw(width, height, decoded_bytes)
.expect("Erreur de reconstruction de l'image décodée");
decoded_img.save(decoded_out_path).unwrap();
println!(
"[*] Succès ! Images sauvegardées : {} et {}",
noisy_out_path, decoded_out_path
);
Ok(())
}

1
src/rs/lib.rs
View File

@ -1,6 +1,5 @@
pub mod benchmark;
pub mod benchmark2;
pub mod benchmark3;
pub mod channel;
pub mod code;
pub mod decoder;

144
src/rs/main.rs Normal file
View File

@ -0,0 +1,144 @@
use ldpc::benchmark::get_or_generate_cached_code;
use ldpc::channel::AwgnChannel;
use ldpc::code::GenerationMethod;
use ldpc::decoder::{build_decoder, DecoderConfig, DecoderMethod};
use ldpc::encoder::{build_encoder, EncodingMethod};
use ldpc::image_sim::transmit_image;
// fn main() -> ldpc::Result<()> {
// let n = 1944;
// let k = 972;
// let wc = 3;
// let wr = 6;
//
// println!("Transmission d'image via code LDPC");
//
// let code_mn = get_or_generate_cached_code(
// n,
// k,
// wc,
// wr,
// GenerationMethod::MacKayNeal { max_attempts: 5000 },
// )?;
//
// let mut code = code_mn;
// let encoder = build_encoder(&mut code, EncodingMethod::Systematic)?;
//
// let config = DecoderConfig {
// max_iterations: 50,
// early_stopping: true,
// };
//
// // Sum-Product
// let decoder = build_decoder(&code, DecoderMethod::SumProduct, config);
//
// let channel = AwgnChannel::new(2.0, code.rate())?;
//
// transmit_image(
// "test.png",
// "noisy_out.png",
// "decoded_out.png",
// &*encoder,
// &*decoder,
// &channel,
// )?;
//
// Ok(())
// }
use clap::Parser;
use ldpc::benchmark2::{run_massive_campaign, CampaignConfig, CodeScenario};
#[derive(Parser, Debug)]
#[command(author, version, about = "Laboratoire de test LDPC - TIPE")]
struct Args {
#[arg(short, long, default_value_t = 1000)]
trials: usize,
/// Générer les fichiers .dot pour visualiser les graphes de Tanner
#[arg(long, default_value_t = false)]
export_graph: bool,
}
fn main() -> ldpc::Result<()> {
let args = Args::parse();
let snrs = vec![1.0, 1.25, 1.5, 1.75, 2.0, 2.25, 2.5, 2.75, 3.0, 3.5, 4.0];
let mut scenarios = Vec::new();
// -------------------------------------------------------------------------
// SCÉNARIO "TOY MODEL" : Spécial pour ton document Typst
// Un code minuscule R=1/2 avec n=24, k=12, m=12.
// Lisible sur une feuille A4.
// -------------------------------------------------------------------------
if args.export_graph {
scenarios.push(CodeScenario {
name: "ToyModel_Typst_N24".into(),
n: 24,
k: 12,
wc: 3,
wr: 6,
method: GenerationMethod::Gallager,
});
}
// Les vrais tests pour tes courbes de performances
scenarios.push(CodeScenario {
name: "Gallager_N1296_R05".into(),
n: 1296,
k: 648,
wc: 3,
wr: 6,
method: GenerationMethod::Gallager,
});
scenarios.push(CodeScenario {
name: "MacKay_N1296_R05".into(),
n: 1296,
k: 648,
wc: 3,
wr: 6,
method: GenerationMethod::MacKayNeal { max_attempts: 1000 },
});
let config = CampaignConfig {
scenarios,
snr_range: snrs,
n_trials: args.trials,
max_iterations: 50,
output_csv: "tipe_results.csv".into(),
export_graph: args.export_graph,
};
run_massive_campaign(config)?;
Ok(())
}
// use ldpc::benchmark::run_simulation;
//
// fn main() -> ldpc::Result<()> {
// let n = 1944;
// let k = 972;
// let wc = 3;
// let wr = 6;
//
// println!("Benchmark: MacKayNeal vs Gallager");
// println!();
//
// println!("Test 1: Génération MacKayNeal\n");
// let code_mn = get_or_generate_cached_code(
// n,
// k,
// wc,
// wr,
// GenerationMethod::MacKayNeal { max_attempts: 5000 },
// )?;
//
// run_simulation(code_mn)?;
//
// println!("\nTest 2 : Génération Gallager\n");
// let code_gal = get_or_generate_cached_code(n, k, wc, wr, GenerationMethod::Gallager)?;
// run_simulation(code_gal)?;
//
// Ok(())
// }