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"""
Faz 5 — SmartCore V1 eval baseline (STANDALONE / kendine yeten).

Çoktan seçmeli log-likelihood: her şık için modelin koşullu log-olasılığını hesapla →
en yükseği seç → altın cevapla karşılaştır. acc=ham toplam, acc_norm=token-uzunluğa bölünmüş.

Model tanımı GÖMÜLÜ (faz3_train.py ile birebir) → hiçbir yerel import'a bağlı DEĞİL.
Ortam: Colab GPU + mamba-og fork. Veri: HF datasets (Faz1'de dekontamine → adil).

Kullanım (fork kurulu + HF login'li):
  HF_TOKEN=hf_xxx python faz5_eval.py --tasks xcopa --limit 100
  HF_TOKEN=hf_xxx python faz5_eval.py --tasks xcopa,belebele,hellaswag --limit 200
"""
import os, sys, argparse
import torch, torch.nn as nn, torch.nn.functional as F
from functools import partial

try:
    from mamba_ssm.modules.block import Block
    from mamba_ssm.modules.mamba3 import Mamba3
    from mamba_ssm.modules.mlp import GatedMLP
    from mamba_ssm.ops.triton.layer_norm import RMSNorm
except Exception as e:
    sys.exit(f"[hata] mamba-og fork yok ({e!r}). Önce wheel kurulum hücresini çalıştır (CUDA gerekir).")


# ───────────── model (faz3_train.py ile BİREBİR AYNI) ─────────────
def _rms(x, w, eps=1e-5):
    return (x * torch.rsqrt(x.pow(2).mean(-1, keepdim=True) + eps)) * w


def _rot_half(x):
    a, b = x.chunk(2, -1)
    return torch.cat((-b, a), -1)


class GQAMixer(nn.Module):
    def __init__(self, dim, n_heads=12, n_kv=3, base=10000.0, layer_idx=None, device=None, dtype=None):
        super().__init__()
        self.nh, self.nkv, self.hd = n_heads, n_kv, dim // n_heads
        self.rep = n_heads // n_kv
        fk = {"device": device, "dtype": dtype}
        self.q_proj = nn.Linear(dim, n_heads * self.hd, bias=False, **fk)
        self.k_proj = nn.Linear(dim, n_kv * self.hd, bias=False, **fk)
        self.v_proj = nn.Linear(dim, n_kv * self.hd, bias=False, **fk)
        self.out_proj = nn.Linear(n_heads * self.hd, dim, bias=False, **fk)
        self.qn = nn.Parameter(torch.ones(self.hd, **fk))
        self.kn = nn.Parameter(torch.ones(self.hd, **fk))
        self.register_buffer(
            "inv", 1.0 / (base ** (torch.arange(0, self.hd, 2, device=device).float() / self.hd)),
            persistent=False)

    def _rope(self, x, T):
        f = torch.outer(torch.arange(T, device=x.device, dtype=torch.float32), self.inv)
        e = torch.cat((f, f), -1)
        return (x * e.cos()[None, None] + _rot_half(x) * e.sin()[None, None]).to(x.dtype)

    def forward(self, x, **kw):
        B, T, _ = x.shape
        q = self.q_proj(x).view(B, T, self.nh, self.hd).transpose(1, 2)
        k = self.k_proj(x).view(B, T, self.nkv, self.hd).transpose(1, 2)
        v = self.v_proj(x).view(B, T, self.nkv, self.hd).transpose(1, 2)
        q = _rms(q.float(), self.qn.float()).to(x.dtype)
        k = _rms(k.float(), self.kn.float()).to(x.dtype)
        q, k = self._rope(q, T), self._rope(k, T)
        k = k.repeat_interleave(self.rep, 1)
        v = v.repeat_interleave(self.rep, 1)
        y = F.scaled_dot_product_attention(q, k, v, is_causal=True)
        return self.out_proj(y.transpose(1, 2).contiguous().view(B, T, -1))


class HybridLM(nn.Module):
    def __init__(self, cfg, device=None, dtype=None):
        super().__init__()
        self.cfg = cfg
        self.vocab = cfg["vocab_size"]
        self.scaled_embed = cfg.get("scaled_embed", False)
        d = cfg["d_model"]
        self.embedding = nn.Embedding(self.vocab, d, device=device, dtype=dtype)
        self.layers = nn.ModuleList()
        self.attn_idx = []
        for i in range(cfg["n_layers"]):
            is_attn = ((i + 1) % cfg["attn_every"] == 0) and i != 0 and i != cfg["n_layers"] - 1
            fk = {"device": device, "dtype": dtype}
            if is_attn:
                mixer_cls = partial(GQAMixer, n_heads=cfg["n_heads"], n_kv=cfg["n_kv_heads"],
                                    layer_idx=i, **fk)
                self.attn_idx.append(i)
            else:
                ssm = dict(d_state=cfg["d_state"], expand=cfg["expand"], headdim=cfg["head_dim"],
                           ngroups=cfg["ngroups"], rope_fraction=cfg["rope_fraction"],
                           is_outproj_norm=False, is_mimo=cfg["is_mimo"], mimo_rank=cfg["mimo_rank"],
                           chunk_size=cfg["chunk_size"])
                mixer_cls = partial(Mamba3, layer_idx=i, **ssm, **fk)
            blk = Block(d, mixer_cls,
                        partial(GatedMLP, hidden_features=cfg["d_intermediate"], out_features=d, **fk),
                        norm_cls=partial(RMSNorm, eps=1e-5, **fk),
                        fused_add_norm=True, residual_in_fp32=True)
            blk.layer_idx = i
            self.layers.append(blk)
        self.norm_f = RMSNorm(d, eps=1e-5, device=device, dtype=dtype)
        self.lm_head = nn.Linear(d, self.vocab, bias=False, device=device, dtype=dtype)
        self.lm_head.weight = self.embedding.weight   # tied

    def forward(self, ids):
        h = self.embedding(ids)
        if self.scaled_embed:
            h = h * (self.cfg["d_model"] ** 0.5)
        res = None
        for l in self.layers:
            h, res = l(h, res)
        h = self.norm_f((h + res) if res is not None else h)
        return self.lm_head(h.to(self.lm_head.weight.dtype))


# ───────────── tokenizer + checkpoint ─────────────
def load_tok(token):
    import sentencepiece as spm
    from huggingface_hub import hf_hub_download
    p = hf_hub_download("kdirgul/smartcore-v1", "tokenizer/tokenizer.model", repo_type="model", token=token)
    sp = spm.SentencePieceProcessor(model_file=p)
    print(f"[tok] vocab={sp.get_piece_size()}", flush=True)
    return sp


def latest_ckpt(token):
    from huggingface_hub import HfApi, hf_hub_download
    api = HfApi(token=token)
    fs = [f for f in api.list_repo_files("kdirgul/smartcore-v1", repo_type="model")
          if f.startswith("checkpoints/step_") and f.endswith("ckpt.pt")]
    latest = max(fs)
    print(f"[ckpt] {latest}", flush=True)
    return hf_hub_download("kdirgul/smartcore-v1", latest, repo_type="model", token=token)


def resolve_ckpt(spec, token):
    """spec yoksa base latest; yerel .pt varsa onu; aksi halde HF yolu (örn sft/epoch_2/ckpt.pt)."""
    if not spec:
        return latest_ckpt(token)
    if os.path.exists(spec):
        return spec
    from huggingface_hub import hf_hub_download
    print(f"[ckpt] HF: {spec}", flush=True)
    return hf_hub_download("kdirgul/smartcore-v1", spec, repo_type="model", token=token)


# ───────────── log-likelihood skorlama ─────────────
@torch.no_grad()
def loglik(model, sp, ctx, cont):
    ctx_ids = sp.encode(ctx, out_type=int)
    full_ids = sp.encode(ctx + cont, out_type=int)
    n_cont = max(1, len(full_ids) - len(ctx_ids))
    full_ids = full_ids[-2048:]
    x = torch.tensor([full_ids], device="cuda")
    with torch.autocast(device_type="cuda", dtype=torch.bfloat16):
        logits = model(x)[0].float()
    lp = F.log_softmax(logits[:-1], dim=-1)
    tgt = torch.tensor(full_ids[1:], device="cuda")
    tok_lp = lp[torch.arange(len(tgt), device="cuda"), tgt]
    return tok_lp[-n_cont:].sum().item(), n_cont


def predict(model, sp, ctx, conts):
    sc = [loglik(model, sp, ctx, c) for c in conts]
    raw = max(range(len(conts)), key=lambda i: sc[i][0])
    norm = max(range(len(conts)), key=lambda i: sc[i][0] / sc[i][1])
    return raw, norm


# ───────────── görevler → (ctx, [şıklar], altın_idx) ─────────────
def task_xcopa(limit):
    from datasets import load_dataset
    ds = load_dataset("cambridgeltl/xcopa", "tr", split="validation")
    conn = {"cause": "çünkü", "effect": "bu yüzden"}
    out = []
    for ex in ds:
        ctx = f"{ex['premise'].strip().rstrip('.')} {conn[ex['question']]}"
        conts = [" " + ex["choice1"].strip(), " " + ex["choice2"].strip()]
        out.append((ctx, conts, int(ex["label"])))
        if limit and len(out) >= limit:
            break
    return out


def task_belebele(limit):
    from datasets import load_dataset
    ds = load_dataset("facebook/belebele", "tur_Latn", split="test")
    out = []
    for ex in ds:
        ctx = f"{ex['flores_passage'].strip()}\nSoru: {ex['question'].strip()}\nCevap:"
        conts = [" " + ex[f"mc_answer{i}"].strip() for i in (1, 2, 3, 4)]
        out.append((ctx, conts, int(ex["correct_answer_num"]) - 1))
        if limit and len(out) >= limit:
            break
    return out


def task_hellaswag(limit):
    from datasets import load_dataset
    ds = load_dataset("Rowan/hellaswag", split="validation")
    out = []
    for ex in ds:
        ctx = ex["ctx"].strip()
        conts = [" " + e.strip() for e in ex["endings"]]
        out.append((ctx, conts, int(ex["label"])))
        if limit and len(out) >= limit:
            break
    return out


def task_xnli(limit):
    """XNLI-tr (NLI) → 3-şık MC: premise+hypothesis → Doğru/Belirsiz/Yanlış.
    label 0=entailment→Doğru, 1=neutral→Belirsiz, 2=contradiction→Yanlış."""
    from datasets import load_dataset
    ds = load_dataset("facebook/xnli", "tr", split="validation")
    opts = [" Doğru", " Belirsiz", " Yanlış"]
    out = []
    for ex in ds:
        ctx = (f"{ex['premise'].strip()}\nSoru: \"{ex['hypothesis'].strip()}\" — "
               f"doğru mu, belirsiz mi, yanlış mı?\nCevap:")
        out.append((ctx, opts, int(ex["label"])))
        if limit and len(out) >= limit:
            break
    return out


def task_turkishmmlu(limit):
    """TurkishMMLU (All config) → 4-5 şık akademik MC. answer = 0-tabanlı int index."""
    from datasets import load_dataset
    ds = load_dataset("AYueksel/TurkishMMLU", "All", split="test")
    out = []
    for ex in ds:
        choices = ex["choices"]
        gold = int(ex["answer"])
        if not (0 <= gold < len(choices)):
            continue
        ctx = f"Soru: {ex['question'].strip()}\nCevap:"
        conts = [" " + str(c).strip() for c in choices]
        out.append((ctx, conts, gold))
        if limit and len(out) >= limit:
            break
    return out


TASKS = {"xcopa": task_xcopa, "belebele": task_belebele, "hellaswag": task_hellaswag,
         "xnli": task_xnli, "turkishmmlu": task_turkishmmlu}


def run_task(model, sp, name, items):
    raw_ok = norm_ok = 0
    for i, (ctx, conts, gold) in enumerate(items):
        r, n = predict(model, sp, ctx, conts)
        raw_ok += (r == gold); norm_ok += (n == gold)
        if (i + 1) % 50 == 0:
            print(f"  {name} {i+1}/{len(items)}...", flush=True)
    N = len(items); rnd = 1.0 / len(items[0][1])
    print(f"[{name}] acc={raw_ok/N:.3f} | acc_norm={norm_ok/N:.3f} | N={N} | random={rnd:.3f}", flush=True)
    return raw_ok / N, norm_ok / N


def main():
    ap = argparse.ArgumentParser()
    ap.add_argument("--tasks", default="xcopa,belebele,hellaswag")
    ap.add_argument("--limit", type=int, default=200)
    ap.add_argument("--ckpt", default=None, help="HF yolu (sft/epoch_2/ckpt.pt) | yerel .pt | boş=base latest")
    args = ap.parse_args()

    assert torch.cuda.is_available(), "CUDA yok (Colab GPU gerekir)."
    torch.set_float32_matmul_precision("high")
    from huggingface_hub import get_token
    token = os.environ.get("HF_TOKEN") or get_token()

    sp = load_tok(token)
    st = torch.load(resolve_ckpt(args.ckpt, token), map_location="cpu")
    model = HybridLM(st["cfg"], device="cuda", dtype=torch.bfloat16)
    model.load_state_dict(st["model"], strict=False); model.eval()
    tag = f"sft/epoch={st.get('epoch')}" if st.get("sft") else f"base step={st.get('step','?')}"
    print(f"[model] {tag} | {'MIMO' if st['cfg'].get('is_mimo') else 'SISO'}\n", flush=True)

    results = {}
    for name in [t.strip() for t in args.tasks.split(",") if t.strip()]:
        if name not in TASKS:
            print(f"[atla] bilinmeyen görev: {name}"); continue
        print(f"=== {name} yükleniyor ===", flush=True)
        results[name] = run_task(model, sp, name, TASKS[name](args.limit or None))

    print("\n===== ÖZET (baseline) =====")
    for name, (acc, accn) in results.items():
        print(f"{name:12s} acc={acc:.3f}  acc_norm={accn:.3f}")


if __name__ == "__main__":
    main()