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from rich import print
import glob
import os
import re
import shutil
import subprocess
from typing import Dict, List, Tuple, Iterable, Set
import random
from iv2_utils.iv2 import json_read, json_write
import tempfile
def ensure_dir(p: str):
os.makedirs(p, exist_ok=True)
def read_edgelist(path: str) -> Iterable[Tuple[int, int]]:
with open(path, 'r') as f:
for line in f:
s = line.strip()
if not s or s.startswith('#'):
continue
parts = s.split()
if len(parts) < 2:
continue
try:
u = int(parts[0]); v = int(parts[1])
except ValueError:
continue
if u == v:
continue
a, b = (u, v) if u < v else (v, u)
yield a, b
def write_edgelist(path: str, edges: Iterable[Tuple[int, int]]):
with open(path, 'w') as f:
for u, v in edges:
f.write(f"{u} {v}\n")
def parse_seeds(path: str) -> Tuple[Dict[int, int], List[int]]:
"""
Return (node_to_cluster_index, sorted_cluster_ids).
The cluster indices are 0..C-1, sorted by cluster_id.
- On overlapping membership, choose the cluster with higher 'score', then smaller cluster_id.
"""
js = json_read(path)
clusters = js.get('clusters', [])
# Sort clusters by cluster_id for stable indexing
clusters_sorted = sorted(clusters, key=lambda c: c.get('cluster_id', 0))
cluster_id_list = [c.get('cluster_id', i) for i, c in enumerate(clusters_sorted)]
cluster_id_to_idx = {cid: i for i, cid in enumerate(cluster_id_list)}
# Build node->(best_cluster_idx, best_score, best_cid)
node_choice: Dict[int, Tuple[int, float, int]] = {}
for c in clusters_sorted:
cid = c.get('cluster_id', None)
if cid is None:
continue
idx = cluster_id_to_idx[cid]
members = c.get('members')
if members is None:
members = c.get('seed_nodes', [])
score = float(c.get('score', 0.0))
for u in members:
prev = node_choice.get(u, None)
if prev is None or (score > prev[1]) or (score == prev[1] and cid < prev[2]):
node_choice[u] = (idx, score, cid)
node_to_cluster = {u: idx for u, (idx, score, cid) in node_choice.items()}
return node_to_cluster, cluster_id_list
def coarsen_edgelist(prev_edgelist: str, seeds_json: str, out_edgelist: str) -> int:
node_to_cluster, cluster_id_list = parse_seeds(seeds_json)
edges_set: Set[Tuple[int, int]] = set()
missing_nodes = 0
for u, v in read_edgelist(prev_edgelist):
cu = node_to_cluster.get(u, None)
cv = node_to_cluster.get(v, None)
if cu is None or cv is None:
# If a node isn't present in any cluster JSON, skip or count as missing
missing_nodes += 1
continue
if cu == cv:
continue
a, b = (cu, cv) if cu < cv else (cv, cu)
edges_set.add((a, b))
write_edgelist(out_edgelist, sorted(edges_set))
return missing_nodes
def run_java(
java_exec: str,
class_name: str,
edgelist_path: str,
out_json_path: str,
epsilon: str,
java_opts: List[str],
quiet: bool = False,
) -> None:
java_file = class_name + '.java'
compile_cmd = ['javac', '-cp', '.', java_file]
if not quiet:
print(f"[blue]Compiling:[/blue] {' '.join(compile_cmd)}")
try:
_ = subprocess.run(
compile_cmd, check=True, capture_output=True, text=True, encoding='utf-8'
)
except FileNotFoundError:
if not quiet:
print("[red]Error: `javac` command not found. Is JDK installed and in your PATH?[/red]")
raise
except subprocess.CalledProcessError as e:
if not quiet:
print(f"[red]Java compilation failed. Return code: {e.returncode}[/red]")
print("[red]stdout:[/red]\n" + e.stdout)
print("[red]stderr:[/red]\n" + e.stderr)
raise
cmd = [java_exec] + java_opts + [class_name, edgelist_path, out_json_path, epsilon]
if not quiet:
print("[blue]Running:[/blue]", " ".join(cmd))
run_kwargs = {'check': True}
if quiet:
run_kwargs['stdout'] = subprocess.DEVNULL
run_kwargs['stderr'] = subprocess.DEVNULL
subprocess.run(cmd, **run_kwargs)
def generate_lrmc_cluster(edges: List[Tuple[int, int]], epsilon: float, java_exec: str = 'java', java_opts: List[str] = None, quiet: bool = True) -> Dict:
"""
Generates a single cluster from an edge list using the L-RMC algorithm.
Args:
edges: A list of 0-indexed integer tuples representing the graph edges.
epsilon: The epsilon value for the L-RMC algorithm.
java_exec: Path to the java executable.
java_opts: A list of options for the java executable.
quiet: If True, suppress stdout from this function and subprocesses.
Returns:
A dictionary containing the 'seed_nodes' and 'score' of the found cluster.
Node IDs in 'seed_nodes' are 0-indexed.
"""
class_name = 'LRMCGenerateSingleCluster'
# Create temporary files for communication with the Java subprocess
with tempfile.NamedTemporaryFile(mode='w', delete=False, suffix='.txt', encoding='utf-8') as edge_file, \
tempfile.NamedTemporaryFile(mode='r', delete=False, suffix='.json', encoding='utf-8') as json_file:
edge_file_path = edge_file.name
json_file_path = json_file.name
try:
# Write 0-indexed edgelist for the Java code to consume
with open(edge_file_path, 'w', encoding='utf-8') as f:
for u, v in edges:
f.write(f"{u} {v}\n")
# Run the Java process which reads the edge file and writes the JSON output
run_java(java_exec, class_name, edge_file_path, json_file_path, str(epsilon), java_opts or [], quiet=quiet)
# Read and parse the JSON output from the temporary file
json_output = json_read(json_file_path)
finally:
# Ensure temporary files are cleaned up
os.remove(edge_file_path)
os.remove(json_file_path)
# Extract results from the first cluster
cluster = json_output['clusters'][0]
# The Java code returns 1-based node IDs, so convert them to 0-based
seed_nodes_1_based = cluster['seed_nodes']
seed_nodes_0_based = [node - 1 for node in seed_nodes_1_based]
return {
"seed_nodes": seed_nodes_0_based,
"score": cluster['score']
}
def generate_random_seeds(edgelist_path: str, num_nodes: int, out_json_path: str):
"""Generates a seeds file with a single cluster of randomly selected nodes."""
nodes = set()
for u, v in read_edgelist(edgelist_path):
nodes.add(u)
nodes.add(v)
if num_nodes > len(nodes):
print(f"[yellow]Warning: requested {num_nodes} random nodes, but only {len(nodes)} unique nodes exist. Selecting all nodes.[/yellow]")
selected_nodes = list(nodes)
else:
selected_nodes = random.sample(list(nodes), num_nodes)
# The downstream script expects 1-indexed nodes under "seed_nodes"
selected_nodes_1_indexed = [n + 1 for n in selected_nodes]
seed_data = {
"clusters": [
{
"cluster_id": 1,
"seed_nodes": selected_nodes_1_indexed,
"score": 1.0
}
]
}
json_write(seed_data, out_json_path)
print(f"[green]Generated random seeds with {len(selected_nodes)} nodes at {out_json_path}[/green]")
def build_single_graph_levels(args):
if args.baseline == 'random':
if not args.num_nodes:
raise SystemExit("--num_nodes is required for --baseline random")
stage_dir = os.path.join(args.out_dir, "stage0_rand")
ensure_dir(stage_dir)
if args.levels != 1:
print("[yellow]Warning: For random baseline, only one level is generated. Ignoring --levels setting.[/yellow]")
seeds_out = os.path.join(stage_dir, f"seeds_{args.num_nodes}.json")
generate_random_seeds(args.input_edgelist, args.num_nodes, seeds_out)
return
ensure_dir(args.out_dir)
# Stage 0 edgelist is the input; optionally copy for record
stage0_dir = os.path.join(args.out_dir, "stage0")
ensure_dir(stage0_dir)
e0_copy = os.path.join(stage0_dir, "edgelist_0.txt")
if args.copy_inputs:
shutil.copyfile(args.input_edgelist, e0_copy)
prev_edgelist = args.input_edgelist
for lvl in range(args.levels):
stage_dir = os.path.join(args.out_dir, f"stage{lvl}")
ensure_dir(stage_dir)
seeds_out = os.path.join(stage_dir, "seeds_"+str(args.epsilon)+".json")
# Run Java to produce seeds at this level
run_java(args.java, args.class_name, prev_edgelist, seeds_out, args.epsilon, args.java_opts)
# Prepare next-level edgelist (unless last level)
if lvl < args.levels - 1:
next_stage_dir = os.path.join(args.out_dir, f"stage{lvl+1}")
ensure_dir(next_stage_dir)
next_edgelist = os.path.join(next_stage_dir, f"edgelist_{lvl+1}.txt")
missing = coarsen_edgelist(prev_edgelist, seeds_out, next_edgelist)
if missing > 0:
print(f"[yellow]stage{lvl}: {missing} edges had nodes missing from seeds; skipped.[/yellow]")
prev_edgelist = next_edgelist
def build_multigraph_levels(args):
ensure_dir(args.out_dir)
# Enumerate graph files
graph_files = sorted(glob.glob(os.path.join(args.graphs_dir, args.glob)))
if not graph_files:
raise SystemExit(f"No graph files found in {args.graphs_dir} with pattern {args.glob}")
pattern = re.compile(r'(.*?)(\d+)(\.\w+)$') # capture numeric id
def graph_id_from_path(p: str) -> str:
base = os.path.basename(p)
m = pattern.match(base)
if m:
return m.group(2).zfill(6) # zero-pad to 6 for consistency
# fallback: strip extension
stem = os.path.splitext(base)[0]
m2 = re.search(r'(\d+)$', stem)
return (m2.group(1).zfill(6) if m2 else stem)
# Stage 0: run Java for each graph
prev_stage_edgelists: Dict[str, str] = {}
for lvl in range(args.levels):
stage_dir = os.path.join(args.out_dir, f"stage{lvl}")
ensure_dir(stage_dir)
if lvl == 0:
for gpath in graph_files:
gid = graph_id_from_path(gpath)
seeds_out = os.path.join(stage_dir, f"graph_{gid}.json")
run_java(args.java, args.class_name, gpath, seeds_out, args.epsilon, args.java_opts)
prev_stage_edgelists[gid] = gpath
else:
# For each graph, coarsen previous edgelist using previous seeds, then run Java
for gpath in graph_files:
gid = graph_id_from_path(gpath)
prev_edgelist = prev_stage_edgelists[gid]
prev_seeds = os.path.join(args.out_dir, f"stage{lvl-1}", f"graph_{gid}.json")
next_edgelist = os.path.join(stage_dir, f"graph_{gid}.txt")
missing = coarsen_edgelist(prev_edgelist, prev_seeds, next_edgelist)
if missing > 0:
print(f"[yellow]stage{lvl-1} graph_{gid}: {missing} edges had nodes missing from seeds; skipped.[/yellow]")
seeds_out = os.path.join(stage_dir, f"graph_{gid}.json")
run_java(args.java, args.class_name, next_edgelist, seeds_out, args.epsilon, args.java_opts)
prev_stage_edgelists[gid] = next_edgelist
def main():
ap = argparse.ArgumentParser(description="Build LRMC seeds across multiple levels by invoking the Java LRMC tool and coarsening between levels.")
mode = ap.add_mutually_exclusive_group(required=True)
mode.add_argument('--input_edgelist', type=str, help='Single-graph mode: path to original edgelist.txt')
mode.add_argument('--graphs_dir', type=str, help='Multi-graph mode: directory containing per-graph edgelist files (e.g., graph_000000.txt)')
ap.add_argument('--glob', type=str, default='graph_*.txt', help='Multi-graph mode: glob pattern for graph files (default: graph_*.txt)')
ap.add_argument('--out_dir', type=str, required=True, help='Output directory (stages will be created here)')
ap.add_argument('--levels', type=int, required=True, help='Number of levels to build (e.g., 3)')
# Baseline arguments
ap.add_argument('--baseline', type=str, choices=['random'], help='Use a baseline method for seed generation.')
ap.add_argument('--num_nodes', type=int, help='Number of random nodes to select for random baseline.')
# Java settings
ap.add_argument('--java', type=str, default='java', help='Java executable (default: java)')
ap.add_argument('--class_name', type=str, default='LRMCGenerateSingleCluster', help='Fully qualified Java class name')
ap.add_argument('--epsilon', type=str, default='1e6', help='Epsilon argument for the Java tool (default: 1e6)')
ap.add_argument('--java_opts', type=str, default='', help='Extra options for java (e.g., "-Xmx16g -cp my.jar")')
ap.add_argument('--copy_inputs', action='store_true', help='Copy original edgelist under stage0 for record (single-graph mode)')
args = ap.parse_args()
# Parse java_opts into a list if provided
args.java_opts = args.java_opts.split() if args.java_opts else []
if args.input_edgelist:
build_single_graph_levels(args)
else:
if args.baseline == 'random':
raise SystemExit("--baseline random is only supported in single-graph mode (--input_edgelist)")
build_multigraph_levels(args)
class Args:
def __init__(self):
self.input_edgelist = None
self.graphs_dir = None
self.glob = 'graph_*.txt'
self.out_dir = ''
self.levels = 0
self.java = 'java'
self.class_name = 'LRMCGenerateSingleCluster'
self.epsilon = '1e6'
self.java_opts = []
self.copy_inputs = False
self.baseline = None
self.num_nodes = None
def build_lrmc_single_graph(input_edgelist: str, out_dir: str, levels: int, epsilon: str = '1e6',
java_exec: str = 'java', class_name: str = 'LRMCGenerateSingleCluster',
java_opts: List[str] = None, copy_inputs: bool = False) -> str:
"""
Build LRMC levels for a single graph.
Args:
input_edgelist: Path to input edgelist file
out_dir: Output directory
levels: Number of levels to build
epsilon: Epsilon value for Java tool
java_exec: Java executable path
class_name: Fully qualified Java class name
java_opts: Extra options for Java
copy_inputs: Whether to copy input edgelist to stage0
Returns:
Path to the generated seeds JSON file
"""
args = Args()
args.input_edgelist = input_edgelist
args.out_dir = out_dir
args.levels = levels
args.epsilon = epsilon
args.java = java_exec
args.class_name = class_name
args.java_opts = java_opts or []
args.copy_inputs = copy_inputs
build_single_graph_levels(args)
# Return path to the seeds file from stage0
return os.path.join(out_dir, "stage0", f"seeds_{epsilon}.json")
if __name__ == '__main__':
main()
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