mindnet/app/core/retrieval/retriever.py

"""
FILE: app/core/retrieval/retriever.py
DESCRIPTION: Haupt-Schnittstelle für die Suche. Orchestriert Vektorsuche und Graph-Expansion.
             WP-15c Update: Note-Level Diversity Pooling & Super-Edge Aggregation.
VERSION: 0.7.0
STATUS: Active
DEPENDENCIES: app.config, app.models.dto, app.core.database*, app.core.graph_adapter
"""
from __future__ import annotations

import os
import time
import logging
from typing import Any, Dict, List, Tuple, Iterable, Optional
from collections import defaultdict

from app.config import get_settings
from app.models.dto import (
    QueryRequest, QueryResponse, QueryHit, 
    Explanation, ScoreBreakdown, Reason, EdgeDTO
)

# MODULARISIERUNG: Neue Import-Pfade für die Datenbank-Ebene
import app.core.database.qdrant as qdr
import app.core.database.qdrant_points as qp

import app.services.embeddings_client as ec
import app.core.graph.graph_subgraph as ga

# Mathematische Engine importieren
from app.core.retrieval.retriever_scoring import get_weights, compute_wp22_score

logger = logging.getLogger(__name__)

# ==============================================================================
# 1. CORE HELPERS & CONFIG LOADERS
# ==============================================================================

def _get_client_and_prefix() -> Tuple[Any, str]:
    """Initialisiert Qdrant Client und lädt Collection-Prefix via database-Paket."""
    cfg = qdr.QdrantConfig.from_env()
    return qdr.get_client(cfg), cfg.prefix


def _get_query_vector(req: QueryRequest) -> List[float]:
    """
    Vektorisiert die Anfrage. 
    FIX: Enthält try-except Block für unterschiedliche Signaturen von ec.embed_text.
    """
    if req.query_vector:
        return list(req.query_vector)
    if not req.query:
        raise ValueError("Kein Text oder Vektor für die Suche angegeben.")
    
    settings = get_settings()
    
    try:
        # Versuch mit modernem Interface (WP-03 kompatibel)
        return ec.embed_text(req.query, model_name=settings.MODEL_NAME)
    except TypeError:
        # Fallback für Signaturen, die 'model_name' nicht als Keyword akzeptieren
        logger.debug("ec.embed_text does not accept 'model_name' keyword. Falling back.")
        return ec.embed_text(req.query)


def _semantic_hits(
    client: Any, 
    prefix: str, 
    vector: List[float], 
    top_k: int, 
    filters: Optional[Dict] = None
) -> List[Tuple[str, float, Dict[str, Any]]]:
    """Führt die Vektorsuche via database-Points-Modul durch."""
    raw_hits = qp.search_chunks_by_vector(client, prefix, vector, top=top_k, filters=filters)
    # Strikte Typkonvertierung für Stabilität
    return [(str(hit[0]), float(hit[1]), dict(hit[2] or {})) for hit in raw_hits]

# ==============================================================================
# 2. EXPLANATION LAYER (DEBUG & VERIFIABILITY)
# ==============================================================================

def _build_explanation(
    semantic_score: float,
    payload: Dict[str, Any],
    scoring_debug: Dict[str, Any],
    subgraph: Optional[ga.Subgraph],
    target_note_id: Optional[str],
    applied_boosts: Optional[Dict[str, float]] = None
) -> Explanation:
    """
    Transformiert mathematische Scores und Graph-Signale in eine menschenlesbare Erklärung.
    """
    _, edge_w_cfg, _ = get_weights()
    base_val = scoring_debug["base_val"]

    # 1. Detaillierter mathematischer Breakdown
    breakdown = ScoreBreakdown(
        semantic_contribution=base_val,
        edge_contribution=base_val * scoring_debug["edge_impact_final"],
        centrality_contribution=base_val * scoring_debug["cent_impact_final"],
        raw_semantic=semantic_score,
        raw_edge_bonus=scoring_debug["edge_bonus"],
        raw_centrality=scoring_debug["cent_bonus"],
        node_weight=float(payload.get("retriever_weight", 1.0)),
        status_multiplier=scoring_debug["status_multiplier"],
        graph_boost_factor=scoring_debug["graph_boost_factor"]
    )

    reasons: List[Reason] = []
    edges_dto: List[EdgeDTO] = []

    # 2. Gründe für Semantik hinzufügen
    if semantic_score > 0.85:
        reasons.append(Reason(kind="semantic", message="Sehr hohe textuelle Übereinstimmung.", score_impact=base_val))
    elif semantic_score > 0.70:
        reasons.append(Reason(kind="semantic", message="Inhaltliche Übereinstimmung.", score_impact=base_val))

    # 3. Gründe für Typ und Lifecycle (WP-25 Vorbereitung)
    type_weight = float(payload.get("retriever_weight", 1.0))
    if type_weight != 1.0:
        msg = "Bevorzugt" if type_weight > 1.0 else "De-priorisiert"
        reasons.append(Reason(kind="type", message=f"{msg} durch Typ-Profil.", score_impact=base_val * (type_weight - 1.0)))

    # NEU: Explizite Ausweisung des Lifecycle-Status (WP-22)
    status_mult = scoring_debug.get("status_multiplier", 1.0)
    if status_mult != 1.0:
        status_msg = "Belohnt (Stable)" if status_mult > 1.0 else "De-priorisiert (Draft)"
        reasons.append(Reason(
            kind="status", 
            message=f"{status_msg} durch Content-Lifecycle.", 
            score_impact=semantic_score * (status_mult - 1.0)
        ))

    # 4. Kanten-Verarbeitung (Graph-Intelligence)
    if subgraph and target_note_id and scoring_debug["edge_bonus"] > 0:
        raw_edges = []
        if hasattr(subgraph, "get_incoming_edges"):
             raw_edges.extend(subgraph.get_incoming_edges(target_note_id) or [])
        if hasattr(subgraph, "get_outgoing_edges"):
             raw_edges.extend(subgraph.get_outgoing_edges(target_note_id) or [])
             
        for edge in raw_edges:
            src = str(edge.get("source") or "note_root")
            tgt = str(edge.get("target") or target_note_id or "unknown_target")
            kind = str(edge.get("kind", "related_to"))
            prov = str(edge.get("provenance", "rule"))
            conf = float(edge.get("confidence", 1.0))
            
            direction = "in" if tgt == target_note_id else "out"
            
            edge_obj = EdgeDTO(
                id=f"{src}->{tgt}:{kind}",
                kind=kind,
                source=src,
                target=tgt,
                weight=conf,
                direction=direction,
                provenance=prov,
                confidence=conf
            )
            edges_dto.append(edge_obj)

        # Die 3 wichtigsten Kanten als Begründung formulieren
        top_edges = sorted(edges_dto, key=lambda e: e.confidence, reverse=True)
        for e in top_edges[:3]:
            peer = e.source if e.direction == "in" else e.target
            prov_txt = "Bestätigte" if e.provenance == "explicit" else "KI-basierte"
            boost_txt = f" [Boost x{applied_boosts.get(e.kind)}]" if applied_boosts and e.kind in applied_boosts else ""
            
            reasons.append(Reason(
                kind="edge", 
                message=f"{prov_txt} Kante '{e.kind}'{boost_txt} von/zu '{peer}'.", 
                score_impact=edge_w_cfg * e.confidence
            ))

    if scoring_debug["cent_bonus"] > 0.01:
        reasons.append(Reason(kind="centrality", message="Die Notiz ist ein zentraler Informations-Hub.", score_impact=breakdown.centrality_contribution))

    return Explanation(
        breakdown=breakdown, 
        reasons=reasons, 
        related_edges=edges_dto if edges_dto else None,
        applied_boosts=applied_boosts
    )

# ==============================================================================
# 3. CORE RETRIEVAL PIPELINE
# ==============================================================================

def _build_hits_from_semantic(
    hits: Iterable[Tuple[str, float, Dict[str, Any]]],
    top_k: int,
    used_mode: str,
    subgraph: ga.Subgraph | None = None,
    explain: bool = False,
    dynamic_edge_boosts: Dict[str, float] = None
) -> QueryResponse:
    """
    Wandelt semantische Roh-Treffer in bewertete QueryHits um.
    WP-15c: Implementiert Note-Level Diversity Pooling.
    """
    t0 = time.time()
    enriched = []

    # Erstes Scoring für alle Kandidaten
    for pid, semantic_score, payload in hits:
        edge_bonus, cent_bonus = 0.0, 0.0
        target_id = payload.get("note_id")
        
        if subgraph and target_id:
            try:
                edge_bonus = float(subgraph.edge_bonus(target_id))
                cent_bonus = float(subgraph.centrality_bonus(target_id))
            except Exception:
                pass

        debug_data = compute_wp22_score(
            semantic_score, payload, edge_bonus, cent_bonus, dynamic_edge_boosts
        )
        enriched.append((pid, semantic_score, payload, debug_data))

    # 1. Sortierung nach finalem mathematischen Score
    enriched_sorted = sorted(enriched, key=lambda h: h[3]["total"], reverse=True)

    # 2. WP-15c: Note-Level Diversity Pooling
    # Wir behalten pro note_id nur den Hit mit dem höchsten total_score.
    # Dies verhindert, dass 10 Chunks derselben Note andere KeyNotes verdrängen.
    unique_note_hits = []
    seen_notes = set()
    
    for item in enriched_sorted:
        _, _, payload, _ = item
        note_id = str(payload.get("note_id", "unknown"))
        
        if note_id not in seen_notes:
            unique_note_hits.append(item)
            seen_notes.add(note_id)
            
    # 3. Begrenzung auf top_k nach dem Diversity-Pooling
    limited_hits = unique_note_hits[: max(1, top_k)]

    results: List[QueryHit] = []
    for pid, s_score, pl, dbg in limited_hits:
        explanation_obj = None
        if explain:
            explanation_obj = _build_explanation(
                semantic_score=float(s_score),
                payload=pl,
                scoring_debug=dbg,
                subgraph=subgraph,
                target_note_id=pl.get("note_id"),
                applied_boosts=dynamic_edge_boosts
            )

        text_content = pl.get("page_content") or pl.get("text") or pl.get("content", "[Kein Text]")

        results.append(QueryHit(
            node_id=str(pid),
            note_id=str(pl.get("note_id", "unknown")),
            semantic_score=float(s_score),
            edge_bonus=dbg["edge_bonus"],
            centrality_bonus=dbg["cent_bonus"],
            total_score=dbg["total"],
            source={
                "path": pl.get("path"),
                "section": pl.get("section") or pl.get("section_title"),
                "text": text_content
            },
            payload=pl, 
            explanation=explanation_obj
        ))

    return QueryResponse(results=results, used_mode=used_mode, latency_ms=int((time.time() - t0) * 1000))


def hybrid_retrieve(req: QueryRequest) -> QueryResponse:
    """
    Die Haupt-Einstiegsfunktion für die hybride Suche.
    WP-15c: Implementiert Edge-Aggregation (Super-Kanten).
    """
    client, prefix = _get_client_and_prefix()
    vector = list(req.query_vector) if req.query_vector else _get_query_vector(req)
    top_k = req.top_k or 10
    
    # 1. Semantische Seed-Suche (Wir laden etwas mehr für das Pooling)
    hits = _semantic_hits(client, prefix, vector, top_k=top_k * 3, filters=req.filters)

    # 2. Graph Expansion Konfiguration
    expand_cfg = req.expand if isinstance(req.expand, dict) else {}
    depth = int(expand_cfg.get("depth", 1))
    boost_edges = getattr(req, "boost_edges", {}) or {}

    subgraph: ga.Subgraph | None = None
    if depth > 0 and hits:
        seed_ids = list({h[2].get("note_id") for h in hits if h[2].get("note_id")})
        
        if seed_ids:
            try:
                subgraph = ga.expand(client, prefix, seed_ids, depth=depth, edge_types=expand_cfg.get("edge_types"))
                
                # --- WP-15c: Edge-Aggregation & Deduplizierung (Super-Kanten) ---
                # Verhindert Score-Explosion durch multiple Links auf versch. Abschnitte.
                # Logik: 1. Kante zählt voll, weitere dämpfen auf Faktor 0.1.
                if subgraph and hasattr(subgraph, "adj"):
                    for src, edge_list in subgraph.adj.items():
                        # Gruppiere Kanten nach Ziel-Note (Deduplizierung ID_A -> ID_B)
                        by_target = defaultdict(list)
                        for e in edge_list:
                            by_target[e["target"]].append(e)
                        
                        aggregated_list = []
                        for tgt, edges in by_target.items():
                            if len(edges) > 1:
                                # Sortiere: Stärkste Kante zuerst
                                sorted_edges = sorted(edges, key=lambda x: x.get("weight", 0.0), reverse=True)
                                primary = sorted_edges[0]
                                
                                # Aggregiertes Gewicht berechnen (Sättigungs-Logik)
                                total_w = primary.get("weight", 0.0)
                                for secondary in sorted_edges[1:]:
                                    total_w += secondary.get("weight", 0.0) * 0.1
                                
                                primary["weight"] = total_w
                                primary["is_super_edge"] = True # Flag für Explanation Layer
                                primary["edge_count"] = len(edges)
                                aggregated_list.append(primary)
                            else:
                                aggregated_list.append(edges[0])
                        
                        # In-Place Update der Adjazenzliste des Graphen
                        subgraph.adj[src] = aggregated_list

                    # Re-Sync der In-Degrees für Centrality-Bonus (Aggregation konsistent halten)
                    subgraph.in_degree = defaultdict(int)
                    for src, edges in subgraph.adj.items():
                        for e in edges:
                            subgraph.in_degree[e["target"]] += 1

                # --- WP-22: Kanten-Gewichtung (Provenance & Intent Boost) ---
                if subgraph and hasattr(subgraph, "adj"):
                    for src, edges in subgraph.adj.items():
                        for e in edges:
                            # A. Provenance Weighting
                            prov = e.get("provenance", "rule")
                            prov_w = 1.0 if prov == "explicit" else (0.9 if prov == "smart" else 0.7)
                            
                            # B. Intent Boost Multiplikator
                            kind = e.get("kind")
                            intent_multiplier = boost_edges.get(kind, 1.0)
                            
                            # Gewichtung anpassen
                            e["weight"] = e.get("weight", 1.0) * prov_w * intent_multiplier

            except Exception as e:
                logger.error(f"Graph Expansion failed: {e}")
                subgraph = None

    # 3. Scoring & Explanation Generierung
    # top_k wird erst hier final angewandt
    return _build_hits_from_semantic(hits, top_k, "hybrid", subgraph, req.explain, boost_edges)


def semantic_retrieve(req: QueryRequest) -> QueryResponse:
    """Standard Vektorsuche ohne Graph-Einfluss."""
    client, prefix = _get_client_and_prefix()
    vector = _get_query_vector(req)
    hits = _semantic_hits(client, prefix, vector, req.top_k or 10, req.filters)
    return _build_hits_from_semantic(hits, req.top_k or 10, "semantic", explain=req.explain)


class Retriever:
    """Schnittstelle für die asynchrone Suche."""
    async def search(self, request: QueryRequest) -> QueryResponse:
        return hybrid_retrieve(request)