Last fixes

Added epochs
Merge branch 'dev.train' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.train
2025-10-17 22:17:24 +02:00 · 2025-10-17 17:06:42 +02:00 · 2025-10-17 16:38:12 +02:00 · 2025-10-17 16:37:44 +02:00 · 2025-10-16 20:05:35 +02:00 · 2025-10-16 19:20:23 +02:00
63 changed files with 3207 additions and 6219 deletions
--- a/Assets/Dataset/1-hop/curated/corpus.txt
+++ b/Assets/Dataset/1-hop/curated/corpus.txt
--- a/Assets/Dataset/1-hop/curated/holdout/evaluation.csv
+++ b/Assets/Dataset/1-hop/curated/holdout/evaluation.csv
--- a/Assets/Dataset/1-hop/curated/holdout/test.csv
+++ b/Assets/Dataset/1-hop/curated/holdout/test.csv
--- a/Assets/Dataset/1-hop/curated/holdout/train.csv
+++ b/Assets/Dataset/1-hop/curated/holdout/train.csv
--- a/Assets/Dataset/1-hop/curated/rdf_completation.csv
+++ b/Assets/Dataset/1-hop/curated/rdf_completation.csv
--- a/Assets/Dataset/1-hop/curated/rdf_text.csv
+++ b/Assets/Dataset/1-hop/curated/rdf_text.csv
--- a/Assets/Dataset/1-hop/small/holdout/evaluation.csv
+++ b/Assets/Dataset/1-hop/small/holdout/evaluation.csv
--- a/Assets/Dataset/1-hop/small/holdout/test.csv
+++ b/Assets/Dataset/1-hop/small/holdout/test.csv
--- a/Assets/Dataset/1-hop/small/holdout/train.csv
+++ b/Assets/Dataset/1-hop/small/holdout/train.csv
--- a/Assets/Model/curated/NanoSocrates.zip
+++ b/Assets/Model/curated/NanoSocrates.zip
--- a/Assets/Model/curated/dec_optim.zip
+++ b/Assets/Model/curated/dec_optim.zip
--- a/Assets/Model/curated/enc_optim.zip
+++ b/Assets/Model/curated/enc_optim.zip
--- a/Assets/Model/curated/last_epoch.txt
+++ b/Assets/Model/curated/last_epoch.txt
--- a/Assets/Model/curated/log_loss.csv
+++ b/Assets/Model/curated/log_loss.csv
--- a/Assets/Model/curated/nano_optim.zip
+++ b/Assets/Model/curated/nano_optim.zip
--- a/Assets/Model/small/bpe-small-16.json
+++ b/Assets/Model/small/bpe-small-16.json
--- a/Assets/Model/small/bpe-small.json
+++ b/Assets/Model/small/bpe-small.json
--- a/Playgrounds/doctor.ipynb
+++ b/Playgrounds/doctor.ipynb
@@ -0,0 +1,193 @@
 {
 "cells": [
  {
   "cell_type": "code",
   "execution_count": 1,
   "id": "ddfb4457",
   "metadata": {},
   "outputs": [
    {
     "ename": "AssertionError",
     "evalue": "target id 3872 >= V (256). Fix TOKEN_SPACE_SIZE.",
     "output_type": "error",
     "traceback": [
      "\u001b[31m---------------------------------------------------------------------------\u001b[39m",
      "\u001b[31mAssertionError\u001b[39m                            Traceback (most recent call last)",
      "\u001b[36mCell\u001b[39m\u001b[36m \u001b[39m\u001b[32mIn[1]\u001b[39m\u001b[32m, line 126\u001b[39m\n\u001b[32m    124\u001b[39m \u001b[38;5;66;03m# sanity guard (helps debug vocab mismatches fast)\u001b[39;00m\n\u001b[32m    125\u001b[39m max_seen = tgt[:, :Tp].max().item()\n\u001b[32m--> \u001b[39m\u001b[32m126\u001b[39m \u001b[38;5;28;01massert\u001b[39;00m max_seen < V \u001b[38;5;129;01mor\u001b[39;00m (tgt[:, :Tp] == PAD_TOKEN).all(), \\\n\u001b[32m    127\u001b[39m     \u001b[33mf\u001b[39m\u001b[33m\"\u001b[39m\u001b[33mtarget id \u001b[39m\u001b[38;5;132;01m{\u001b[39;00mmax_seen\u001b[38;5;132;01m}\u001b[39;00m\u001b[33m >= V (\u001b[39m\u001b[38;5;132;01m{\u001b[39;00mV\u001b[38;5;132;01m}\u001b[39;00m\u001b[33m). Fix TOKEN_SPACE_SIZE.\u001b[39m\u001b[33m\"\u001b[39m\n\u001b[32m    129\u001b[39m \u001b[38;5;66;03m# CE over all tokens produced so far (0..t). PAD is ignored by ignore_index\u001b[39;00m\n\u001b[32m    130\u001b[39m loss_t = cross_entropy(\n\u001b[32m    131\u001b[39m     logits_btV.reshape(-\u001b[32m1\u001b[39m, V),                                             \u001b[38;5;66;03m# [B*(t+1), V]\u001b[39;00m\n\u001b[32m    132\u001b[39m     tgt[:, :Tp].reshape(-\u001b[32m1\u001b[39m)                                                \u001b[38;5;66;03m# [B*(t+1)]\u001b[39;00m\n\u001b[32m    133\u001b[39m )\n",
      "\u001b[31mAssertionError\u001b[39m: target id 3872 >= V (256). Fix TOKEN_SPACE_SIZE."
     ]
    }
   ],
   "source": [
    "import random\n",
    "import torch\n",
    "import pandas as pd\n",
    "from pathlib import Path\n",
    "import Project_Model.Libs.Embedder as Embedder\n",
    "import Project_Model.Libs.BPE as BPE\n",
    "import Project_Model.Libs.Transformer as Transformer\n",
    "import Project_Model.Libs.TorchShims as torch_shims\n",
    "from Project_Model.Libs.Training.learning_rade_shedulers import CustomLR\n",
    "from Project_Model.Libs.Training.logistic_collector import LogitsCollector  # external collector\n",
    "\n",
    "# set a fixed seed\n",
    "torch.manual_seed(0)\n",
    "random.seed(0)\n",
    "DEVICE = torch_shims.get_default_device()\n",
    "torch.set_default_device(DEVICE)\n",
    "\n",
    "# BPE Init\n",
    "VOCABULARY_PATH = Path(\"Assets/Model/toy_10/toy_dictionary.json\")\n",
    "SPECIAL_VOC = BPE.default_special_tokens()\n",
    "\n",
    "VOCABULARY = BPE.load_nanos_vocabulary(VOCABULARY_PATH)\n",
    "TOKENANO = BPE.TokeNanoCore(VOCABULARY, SPECIAL_VOC)\n",
    "\n",
    "# Constants (TEMP size; will be corrected after dataset scan below)\n",
    "TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size + 1\n",
    "EMBEDDED_SIZE = 256\n",
    "FEED_FORWARD_MULTIPLIER = 4\n",
    "ATTENTION_HEADS = 4\n",
    "SENTENCE_LENGTH = 256\n",
    "NUMBER_OF_BLOCKS = 2\n",
    "MAX_EPOCHS = int(1e4)\n",
    "\n",
    "PAD_TOKEN = TOKENANO.encode(\"<PAD>\")[0]\n",
    "END_TOKEN = TOKENANO.encode(\"<END>\")[0]\n",
    "\n",
    "# Load CSV\n",
    "TOY_DATASET_PATH = Path(\"Assets/Dataset/1-hop/toy/rdf_text.csv\")\n",
    "TOY_DATASET = pd.read_csv(TOY_DATASET_PATH)\n",
    "\n",
    "TOY_BATCH_INPUT_LIST: list[list[int]] = []\n",
    "TOY_BATCH_PADDING_LIST: list[list[bool]] = []\n",
    "TOY_BATCH_TARGET_LIST: list[list[int]] = []\n",
    "TOY_BATCH_DECODER_DEFAULT: list[list[int]] = []\n",
    "\n",
    "for index, row in TOY_DATASET.iterrows():\n",
    "    RDFs: str = row[\"RDFs\"]\n",
    "    Abstract: str = row[\"Abstract\"]\n",
    "\n",
    "    input_tokens = TOKENANO.encode(RDFs)                    # encoder input ids\n",
    "    output_tokens = TOKENANO.encode(Abstract)[1:]           # decoder target ids (shifted left)\n",
    "    decoder_default_tokens = TOKENANO.encode(\"<SOS>\")       # decoder input starts with <SOS>\n",
    "\n",
    "    input_tokens, padding = Transformer.normalize_sequence(\n",
    "        input_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN\n",
    "    )  # pad/trim + end token\n",
    "    output_tokens, _ = Transformer.normalize_sequence(\n",
    "        output_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN\n",
    "    )  # pad/trim + end token\n",
    "    decoder_default_tokens = Transformer.pad_sequence(\n",
    "        decoder_default_tokens, SENTENCE_LENGTH, PAD_TOKEN\n",
    "    )  # pad with PAD up to SENTENCE_LENGTH\n",
    "\n",
    "    TOY_BATCH_INPUT_LIST.append(input_tokens)\n",
    "    TOY_BATCH_PADDING_LIST.append(padding)\n",
    "    TOY_BATCH_TARGET_LIST.append(output_tokens)\n",
    "    TOY_BATCH_DECODER_DEFAULT.append(decoder_default_tokens)\n",
    "\n",
    "# fix V to cover ALL ids (including specials)                                   # <- important\n",
    "max_enc_id = max(max(row) for row in TOY_BATCH_INPUT_LIST) if TOY_BATCH_INPUT_LIST else 0\n",
    "max_tgt_id = max(max(row) for row in TOY_BATCH_TARGET_LIST) if TOY_BATCH_TARGET_LIST else 0\n",
    "TOKEN_SPACE_SIZE = max(TOKEN_SPACE_SIZE, max(PAD_TOKEN, END_TOKEN, max_enc_id, max_tgt_id) + 1)\n",
    "\n",
    "# Training loop\n",
    "LOSS_HISTORY = []\n",
    "NANOSOCRATES = Transformer.TrainingModel(\n",
    "    TOKEN_SPACE_SIZE,\n",
    "    EMBEDDED_SIZE,\n",
    "    FEED_FORWARD_MULTIPLIER,\n",
    "    ATTENTION_HEADS,\n",
    "    NUMBER_OF_BLOCKS,\n",
    ")\n",
    "\n",
    "collector = LogitsCollector(PAD_TOKEN, END_TOKEN, TOKENANO)  # collects logits and decodes\n",
    "\n",
    "NANOSOCRATES.train()\n",
    "cross_entropy = torch.nn.CrossEntropyLoss(ignore_index=PAD_TOKEN)\n",
    "optimizer = torch.optim.AdamW(NANOSOCRATES.parameters(), lr=1.0)                  # base lr works as factor\n",
    "scheduler = CustomLR(optimizer, EMBEDDED_SIZE, warmup_steps=4000, factor=1.0)     # step each optimizer step\n",
    "\n",
    "current_epoch = 0\n",
    "BATCH_SIZE = min(32, len(TOY_BATCH_INPUT_LIST))  # small batch to stabilize\n",
    "\n",
    "while current_epoch < MAX_EPOCHS:\n",
    "    # simple fixed mini-batch from the top; later you can shuffle/slice\n",
    "    enc = torch.tensor(TOY_BATCH_INPUT_LIST[:BATCH_SIZE], dtype=torch.long)        # [B,T] encoder token ids\n",
    "    pad = torch.tensor(TOY_BATCH_PADDING_LIST[:BATCH_SIZE], dtype=torch.bool)      # [B,T] True where encoder PAD is present\n",
    "    tgt = torch.tensor(TOY_BATCH_TARGET_LIST[:BATCH_SIZE], dtype=torch.long)       # [B,T] decoder targets (ground-truth)\n",
    "\n",
    "    # decoder prefix buffer: <SOS> at pos 0, PAD elsewhere (no shift here)         # we will fill it step by step\n",
    "    dec = torch.tensor(TOY_BATCH_DECODER_DEFAULT[:BATCH_SIZE], dtype=torch.long)   # [B,T]\n",
    "\n",
    "    total_loss = 0.0\n",
    "    collector.reset()  # start fresh for this epoch\n",
    "\n",
    "    T = tgt.size(1)  # sequence length\n",
    "    for t in range(T):\n",
    "        # skip all-PAD steps to avoid CE divide-by-zero late in the sequence\n",
    "        if (tgt[:, t] == PAD_TOKEN).all():                                         # all PAD at this timestep\n",
    "            break\n",
    "\n",
    "        optimizer.zero_grad(set_to_none=True)                                      # clear grads for this token step\n",
    "\n",
    "        prefix = dec[:, : t + 1]                                                   # [B, t+1] current decoder prefix\n",
    "        dec_pad_mask = prefix.eq(PAD_TOKEN)                                        # [B, t+1] True where PAD inside prefix\n",
    "\n",
    "        # now decoder returns all steps up to t -> [B, t+1, V]\n",
    "        logits_btV: torch.Tensor = NANOSOCRATES((enc, pad, prefix, dec_pad_mask))  # full logits for learning\n",
    "        collector.add(logits_btV)                                                  # collector will take the last step\n",
    "\n",
    "        Tp = logits_btV.size(1)                                                    # t+1\n",
    "        V  = logits_btV.size(-1)                                                   # vocab size\n",
    "\n",
    "        # sanity guard (helps debug vocab mismatches fast)\n",
    "        max_seen = tgt[:, :Tp].max().item()\n",
    "        assert max_seen < V or (tgt[:, :Tp] == PAD_TOKEN).all(), \\\n",
    "            f\"target id {max_seen} >= V ({V}). Fix TOKEN_SPACE_SIZE.\"\n",
    "\n",
    "        # CE over all tokens produced so far (0..t). PAD is ignored by ignore_index\n",
    "        loss_t = cross_entropy(\n",
    "            logits_btV.reshape(-1, V),                                             # [B*(t+1), V]\n",
    "            tgt[:, :Tp].reshape(-1)                                                # [B*(t+1)]\n",
    "        )\n",
    "\n",
    "        loss_t.backward()                                                          # backprop for this step\n",
    "        optimizer.step()                                                           # update params\n",
    "        scheduler.step()                                                           # Noam/warmup: step per optimizer step\n",
    "\n",
    "        total_loss = float(loss_t.detach())                                        # keep last step loss for logging\n",
    "\n",
    "        # teacher forcing: reveal the correct token for next position\n",
    "        if t < T - 1:\n",
    "            dec[:, t + 1] = tgt[:, t]                                              # write ground-truth into next slot\n",
    "\n",
    "    current_epoch += 1\n",
    "    print(f\"EPOCH {current_epoch}\\n\\tLoss: {total_loss:.6f}\")                      # simple log\n",
    "    collector.print_decoded()                                                      # print decoded predictions for the batch\n"
   ]
  }
 ],
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--- a/Playgrounds/encoder-pretraining.py
+++ b/Playgrounds/encoder-pretraining.py
--- a/Playgrounds/evaluation.py
+++ b/Playgrounds/evaluation.py
@@ -0,0 +1,263 @@
 import random
 import torch
 from pathlib import Path
 import Project_Model.Libs.BPE as BPE
 import Project_Model.Libs.Transformer as Transformer
 import Project_Model.Libs.TransformerUtils as TUtils
 import Project_Model.Libs.TorchShims as torch_shims
 import Project_Model.Libs.Batch as Batch
 # set a default device
 DEVICE = torch_shims.get_default_device()
 torch.set_default_device(DEVICE)
 # set a fixed seed
 torch.manual_seed(0)
 random.seed(0)
 # Get paths
 MODEL_DIR = "Assets/Model/curated"
 # MODEL_DIR= "Assets/Dataset/Tmp"
 VOCABULARY_PATH = Path("Assets/Model/small/bpe-small-16.json")
 TRAIN_DATASET_PATH = Path("Assets/Dataset/1-hop/small/holdout/train.csv")
 VALIDATION_DATASET_PATH = Path("Assets/Dataset/1-hop/small/holdout/evaluation.csv")
 TEST_DATASET_PATH = Path("Assets/Dataset/1-hop/small/holdout/test.csv")
 # TEST_DATASET_PATH = Path("Assets/Dataset/1-hop/toy/rdf_text.csv")
 MODEL_PATH = Path(f"{MODEL_DIR}/NanoSocrates.zip")
 # BPE Init
 SPECIAL_VOC = BPE.default_special_tokens()
 VOCABULARY = BPE.load_nanos_vocabulary(VOCABULARY_PATH)
 TOKENANO = BPE.TokeNanoCore(VOCABULARY, SPECIAL_VOC)
 # Constants
 MASK_EXTRA_SPACE = 100
 REAL_TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size
 TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size + MASK_EXTRA_SPACE
 EMBEDDED_SIZE = 256
 FEED_FORWARD_MULTIPLIER = 4
 ATTENTION_HEADS = 4
 SENTENCE_LENGTH = 256
 NUMBER_OF_BLOCKS = 2
 SOS_TOKEN = TOKENANO.encode("<SOS>")[0]
 PAD_TOKEN = TOKENANO.encode("<PAD>")[0]
 END_TOKEN = TOKENANO.encode("<EOS>")[0]
 SUBJ_TOKEN = TOKENANO.encode("<SUBJ>")[0]
 REL_TOKEN = TOKENANO.encode("<PRED>")[0]
 OBJ_TOKEN = TOKENANO.encode("<OBJ>")[0]
 MASK_TOKEN = TOKENANO.encode("<MASK>")[0]
 CONTINUTE_TOKEN = TOKENANO.encode("<CONTINUERDF>")[0]
 SPECIAL_TOKENS: set[int] = set(TOKENANO.encode("".join(BPE.default_special_tokens())))
 ALLOWED_TOKENS = set([SUBJ_TOKEN, REL_TOKEN, OBJ_TOKEN])
 FORBIDDEN_TOKENS = SPECIAL_TOKENS - ALLOWED_TOKENS
 # Spanned_Masker
 MASKER = Transformer.SpannedMasker(REAL_TOKEN_SPACE_SIZE, FORBIDDEN_TOKENS, average_span=4)
 TRAIN_BATCHER = Batch.Batcher(TRAIN_DATASET_PATH, SENTENCE_LENGTH, TOKENANO, MASKER)
 VALIDATION_BATCHER = Batch.Batcher(
    VALIDATION_DATASET_PATH, SENTENCE_LENGTH, TOKENANO, MASKER
 )
 TEST_BATCHER = Batch.Batcher(TEST_DATASET_PATH, SENTENCE_LENGTH, TOKENANO, MASKER, debug=True)
 # Model
 NANOSOCRATES_TRAIN = Transformer.TrainingModel(
    TOKEN_SPACE_SIZE,
    EMBEDDED_SIZE,
    FEED_FORWARD_MULTIPLIER,
    ATTENTION_HEADS,
    NUMBER_OF_BLOCKS,
 )
 NANOSOCRATES = Transformer.NanoSocratesCore(
    TOKEN_SPACE_SIZE,
    SENTENCE_LENGTH,
    SOS_TOKEN,
    PAD_TOKEN,
    END_TOKEN,
    CONTINUTE_TOKEN,
    EMBEDDED_SIZE,
    FEED_FORWARD_MULTIPLIER,
    ATTENTION_HEADS,
    NUMBER_OF_BLOCKS,
 )
 if MODEL_PATH.is_file():
    nanosocrates_dict = torch.load(MODEL_PATH, weights_only=True, map_location=DEVICE)
    NANOSOCRATES_TRAIN.load_state_dict(nanosocrates_dict)
 _, ENCODER_ONLY, DECODER_ONLY = TUtils.decompose_nano_socrates(
    NANOSOCRATES, TOKEN_SPACE_SIZE, EMBEDDED_SIZE
 )
 NANOSOCRATES = TUtils.train2inference(
    NANOSOCRATES_TRAIN,
    NANOSOCRATES
 )
 NANOSOCRATES.eval()
 ENCODER_ONLY.eval()
 DECODER_ONLY.eval()
 NANOSOCRATES_TRAIN.eval()
 task_1_metrics = []
 task_2_metrics = []
 task_3_metrics = []
 task_4_metrics = []
 example_num = 0
 with torch.no_grad():
    for example in TEST_BATCHER.batch(1):
        print(f"DOING Example: {example_num}")
        src_x, tgt_y, pad_x, pad_y, tasktype = example
        enc_x = torch.tensor(src_x)
        ACTUAL_BATCH_SIZE, _ = enc_x.shape
        enc_x_pad = torch.tensor(pad_x, dtype=torch.bool)
        tgt = torch.tensor(tgt_y)
        tgt_pad = torch.tensor(pad_y, dtype=torch.bool)
        dec_x = Transformer.get_decoder_input(
            ACTUAL_BATCH_SIZE, SOS_TOKEN, PAD_TOKEN, SENTENCE_LENGTH
        )
        dec_x[:, 1:] = tgt[:, :-1]
        dec_x_pad = dec_x.eq(PAD_TOKEN)
        out: torch.Tensor = NANOSOCRATES.inference((enc_x, enc_x_pad), tasktype)
        tokens: list[int] = out.tolist()[0]
        tokens.append(END_TOKEN)
        tokens = list(map(lambda x: MASK_TOKEN if x > TOKENANO.vocabulary_size else x, tokens))
        out_string = TOKENANO.decode(tokens)
        exp_tokens: list[int] = tgt_y[0]
        exp_tokens = list(map(lambda x: MASK_TOKEN if x > TOKENANO.vocabulary_size else x, exp_tokens))
        exp_string = TOKENANO.decode(exp_tokens)
        enc_tokens: list[int] = src_x[0]
        enc_tokens = list(map(lambda x: MASK_TOKEN if x > TOKENANO.vocabulary_size else x, enc_tokens))
        enc_string = TOKENANO.decode(enc_tokens)
        print(f"PROMPT:\n{enc_string}")
        print(f"EXPECTED:\n{exp_string}")
        print(f"ACTUAL:\n{out_string}")
        if tasktype == Batch.TaskType.RDF2TXT:
            example_num += 1
            ref = TUtils.remove_padding(exp_tokens, PAD_TOKEN, END_TOKEN)
            pred = TUtils.remove_padding(tokens, PAD_TOKEN, END_TOKEN)
            ref_str = TOKENANO.decode(ref)
            pred_str = TOKENANO.decode(pred)
            bleu, rouge, meteor = TUtils.rdf2txt([ref_str], [pred_str])
            task_1_metrics.append(
                [
                    bleu["bleu"], rouge["rougeL"], meteor["meteor"] # type: ignore
                ]
            )
        if tasktype == Batch.TaskType.TEXT2RDF:
            ref = TUtils.remove_padding(exp_tokens, PAD_TOKEN, END_TOKEN)
            pred = TUtils.remove_padding(tokens[1:], PAD_TOKEN, END_TOKEN)
            ref, pred = TUtils.balance_paddings(ref, pred, PAD_TOKEN)
            precision, recall = TUtils.txt2rdf(ref, pred)
            task_2_metrics.append(
                [
                    precision["precision"], recall["recall"] # type: ignore
                ]
            )
        if tasktype == Batch.TaskType.MASKING:
            ref = TUtils.remove_padding(exp_tokens, PAD_TOKEN, END_TOKEN)
            pred = TUtils.remove_padding(tokens, PAD_TOKEN, END_TOKEN)
            ref, pred = TUtils.balance_paddings(ref, pred, PAD_TOKEN)
            accuracy = TUtils.accuracy(ref, pred)
            task_3_metrics.append(
                accuracy["accuracy"] # type: ignore
            )
        if tasktype == Batch.TaskType.COMPLETATION:
            ref = TUtils.remove_padding(exp_tokens, PAD_TOKEN, END_TOKEN)
            pred = TUtils.remove_padding(tokens, PAD_TOKEN, END_TOKEN)
            ref, pred = TUtils.balance_paddings(ref, pred, PAD_TOKEN)
            precision, recall = TUtils.txt2rdf(ref, pred)
            task_4_metrics.append(
                [
                    precision["precision"], recall["recall"] # type: ignore
                ]
            )
 bleus = [row[0] for row in task_1_metrics]
 rouges = [row[1] for row in task_1_metrics]
 meteors = [row[2] for row in task_1_metrics]
 prec_1 = [row[0] for row in task_2_metrics]
 rec_1 = [row[1] for row in task_2_metrics]
 acc = task_3_metrics
 prec_2 = [row[0] for row in task_4_metrics]
 rec_2 = [row[1] for row in task_4_metrics]
 BLEU = TUtils.average(bleus)
 ROUGE = TUtils.average(rouges)
 METEOR = TUtils.average(meteors)
 PREC_1 = TUtils.average(prec_1)
 REC_1 = TUtils.average(rec_1)
 F1_1 = TUtils.f1(PREC_1, REC_1)
 ACC = TUtils.average(acc)
 PREC_2 = TUtils.average(prec_2)
 REC_2 = TUtils.average(rec_2)
 F1_2 = TUtils.f1(PREC_2, REC_2)
 SEPARATOR = "**************************************************************************"
 OUTPUT = "".join([
    f"{SEPARATOR}\n",
    "*\tRDF2TXT:\n",
    f"*\t\tBLEU: {BLEU} - ROUGE: {ROUGE} - METEOR: {METEOR}\n"
    f"{SEPARATOR}\n",
    "*\tTXT2RDF:\n",
    f"*\t\tPRECISION: {PREC_1} - RECALL: {REC_1} - F1: {F1_1}\n"
    f"{SEPARATOR}\n",
    "*\tRDF Completion 1:\n",
    f"*\t\tACCURACY: {ACC}\n"
    f"{SEPARATOR}\n",
    "*\tRDF Completion 2:\n",
    f"*\t\tPRECISION: {PREC_2} - RECALL: {REC_2} - F1: {F1_2}\n"
    f"{SEPARATOR}\n",
    ""
 ])
 print(OUTPUT)
 print("\nDEBUG")
 print(task_1_metrics)
 print(task_2_metrics)
 print(task_3_metrics)
 print(task_4_metrics)
--- a/Playgrounds/nanosocrates-train-experiment-2.py
+++ b/Playgrounds/nanosocrates-train-experiment-2.py
@@ -0,0 +1,472 @@
 import random
 import sys
 import torch
 import pandas as pd
 from pathlib import Path
 import Project_Model.Libs.Embedder as Embedder
 import Project_Model.Libs.BPE as BPE
 import Project_Model.Libs.Transformer as Transformer
 import Project_Model.Libs.TransformerUtils as TUtils
 import Project_Model.Libs.TorchShims as torch_shims
 import Project_Model.Libs.Batch as Batch
 from Project_Model.Libs.Training.loss_saver import Log
 # set a fixed seed
 torch.manual_seed(0)
 random.seed(0)
 # set a default device
 DEVICE = torch_shims.get_default_device()
 torch.set_default_device(DEVICE)
 # Get paths
 CHECKPOINT_DIR = "Assets/Dataset/Tmp"
 VOCABULARY_PATH = Path("Assets/Model/small/bpe-small-16.json")
 TRAIN_DATASET_PATH = Path("Assets/Dataset/1-hop/toy/rdf_text.csv")
 VALIDATION_DATASET_PATH = Path("Assets/Dataset/1-hop/toy/rdf_text.csv")
 TEST_DATASET_PATH = Path("Assets/Dataset/1-hop/toy/rdf_text.csv")
 CHECKPOINT_PATH = Path(f"{CHECKPOINT_DIR}/NanoSocrates.zip")
 NANO_OPTIM_PATH = Path(f"{CHECKPOINT_DIR}/nano_optim.zip")
 ENC_OPTIM_PATH = Path(f"{CHECKPOINT_DIR}/enc_optim.zip")
 DEC_OPTIM_PATH = Path(f"{CHECKPOINT_DIR}/dec_optim.zip")
 LAST_EPOCH_PATH = Path(f"{CHECKPOINT_DIR}/last_epoch.txt")
 # log saver:
 loss_saver = Log(f"{CHECKPOINT_DIR}/log_loss.csv")
 # BPE Init
 SPECIAL_VOC = BPE.default_special_tokens()
 VOCABULARY = BPE.load_nanos_vocabulary(VOCABULARY_PATH)
 TOKENANO = BPE.TokeNanoCore(VOCABULARY, SPECIAL_VOC)
 # Constants
 MASK_EXTRA_SPACE = 100
 REAL_TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size
 TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size + MASK_EXTRA_SPACE
 EMBEDDED_SIZE = 256
 FEED_FORWARD_MULTIPLIER = 4
 ATTENTION_HEADS = 4
 SENTENCE_LENGTH = 256
 NUMBER_OF_BLOCKS = 2
 MAX_EPOCHS = int(300)
 PRETRAIN_EPOCHS = int(20)
 WARMUP_EPOCHS = int(30)
 MINI_BATCH_SIZE = 20
 VALIDATION_STEPS = 10
 CHECKPOINT_STEPS = VALIDATION_STEPS
 PATIENCE = 4
 CURRENT_EPOCH = -1 if not LAST_EPOCH_PATH.is_file() else int(LAST_EPOCH_PATH.read_text())
 VERBOSE = False
 LEARNING_RATE = 0.05
 LABEL_SMOOTHING = 0.01
 SOS_TOKEN = TOKENANO.encode("<SOS>")[0]
 PAD_TOKEN = TOKENANO.encode("<PAD>")[0]
 END_TOKEN = TOKENANO.encode("<END>")[0]
 SUBJ_TOKEN = TOKENANO.encode("<SUBJ>")[0]
 REL_TOKEN = TOKENANO.encode("<PRED>")[0]
 OBJ_TOKEN = TOKENANO.encode("<OBJ>")[0]
 MASK_TOKEN = TOKENANO.encode("<MASK>")[0]
 SPECIAL_TOKENS: set[int] = set(TOKENANO.encode("".join(BPE.default_special_tokens())))
 ALLOWED_TOKENS = set([SUBJ_TOKEN, REL_TOKEN, OBJ_TOKEN])
 FORBIDDEN_TOKENS = SPECIAL_TOKENS - ALLOWED_TOKENS
 # Spanned_Masker
 MASKER = Transformer.SpannedMasker(REAL_TOKEN_SPACE_SIZE, FORBIDDEN_TOKENS, average_span=4)
 TRAIN_BATCHER = Batch.Batcher(TRAIN_DATASET_PATH, SENTENCE_LENGTH, TOKENANO, MASKER)
 VALIDATION_BATCHER = Batch.Batcher(
    VALIDATION_DATASET_PATH, SENTENCE_LENGTH, TOKENANO, MASKER
 )
 TEST_BATCHER = Batch.Batcher(TEST_DATASET_PATH, SENTENCE_LENGTH, TOKENANO, MASKER)
 # Model
 NANOSOCRATES = Transformer.TrainingModel(
    TOKEN_SPACE_SIZE,
    EMBEDDED_SIZE,
    FEED_FORWARD_MULTIPLIER,
    ATTENTION_HEADS,
    NUMBER_OF_BLOCKS,
 )
 if CHECKPOINT_PATH.is_file():
    nanosocrates_dict = torch.load(CHECKPOINT_PATH, weights_only=True)
    NANOSOCRATES.load_state_dict(nanosocrates_dict)
 _, ENCODER_ONLY, DECODER_ONLY = TUtils.decompose_nano_socrates(
    NANOSOCRATES, TOKEN_SPACE_SIZE, EMBEDDED_SIZE
 )
 # Training constants
 nano_cross_entropy = torch.nn.CrossEntropyLoss(ignore_index=PAD_TOKEN, label_smoothing=LABEL_SMOOTHING)
 encoder_ce = torch.nn.CrossEntropyLoss( label_smoothing=LABEL_SMOOTHING)
 decoder_ce = torch.nn.CrossEntropyLoss(ignore_index=PAD_TOKEN, label_smoothing=LABEL_SMOOTHING)
 nano_optim = torch.optim.AdamW(NANOSOCRATES.parameters(), LEARNING_RATE)
 encoder_only_optim = torch.optim.AdamW(ENCODER_ONLY.parameters(), LEARNING_RATE)
 decoder_only_optim = torch.optim.AdamW(DECODER_ONLY.parameters(), LEARNING_RATE)
 if NANO_OPTIM_PATH.is_file():
    optim_dict = torch.load(NANO_OPTIM_PATH)
    nano_optim.load_state_dict(optim_dict)
 if ENC_OPTIM_PATH.is_file():
    optim_dict = torch.load(ENC_OPTIM_PATH)
    encoder_only_optim.load_state_dict(optim_dict)
 if DEC_OPTIM_PATH.is_file():
    optim_dict = torch.load(DEC_OPTIM_PATH)
    decoder_only_optim.load_state_dict(optim_dict)
 nano_scheduler = Transformer.WarmupLR(nano_optim, WARMUP_EPOCHS, EMBEDDED_SIZE, last_epoch=CURRENT_EPOCH)
 encoder_only_scheduler = Transformer.WarmupLR(
    encoder_only_optim, WARMUP_EPOCHS, EMBEDDED_SIZE, last_epoch=CURRENT_EPOCH
 )
 decoder_only_scheduler = Transformer.WarmupLR(
    decoder_only_optim, WARMUP_EPOCHS, EMBEDDED_SIZE, last_epoch=CURRENT_EPOCH
 )
 current_epoch = CURRENT_EPOCH + 2
 patience = 0
 average_loss_validation = {
    "txt": float("inf"),
    "encoder_only": float("inf"),
    "decoder_only": float("inf"),
 }
 while current_epoch < MAX_EPOCHS:
    NANOSOCRATES.train()
    ENCODER_ONLY.train()
    DECODER_ONLY.train()
    text_batch_losses = []
    encoder_batch_losses = []
    decoder_batch_losses = []
    batch_counter = 0
    if VERBOSE:
        print(f"EPOCH {current_epoch} STARTING")
    for batch in TRAIN_BATCHER.batch(MINI_BATCH_SIZE):
        batch_counter += 1
        src_x, tgt_y, pad_x, pad_y, tasktype = batch
        enc_x = torch.tensor(src_x)
        ACTUAL_BATCH_SIZE, _ = enc_x.shape
        enc_x_pad = torch.tensor(pad_x, dtype=torch.bool)
        tgt = torch.tensor(tgt_y)
        tgt_pad = torch.tensor(pad_y, dtype=torch.bool)
        dec_x = Transformer.get_decoder_input(
            ACTUAL_BATCH_SIZE, SOS_TOKEN, PAD_TOKEN, SENTENCE_LENGTH
        )
        dec_x[:, 1:] = tgt[:, :-1]
        dec_x_pad = dec_x.eq(PAD_TOKEN)
        if VERBOSE:
            for s in TUtils.decode_batch(enc_x, TOKENANO, MASK_TOKEN):
                print("Input")
                print(s)
            for s in TUtils.decode_batch(enc_x_pad, TOKENANO, MASK_TOKEN):
                print("Encoder Padding mask")
                print(s)
            for s in TUtils.decode_batch(tgt, TOKENANO, MASK_TOKEN):
                print("Desired Output")
                print(s)
            a_dx = dec_x[:,:]
            a_dx[:, -1]= END_TOKEN
            for s in TUtils.decode_batch(a_dx, TOKENANO, MASK_TOKEN):
                print("Decoder Input")
                print(s)
        if VERBOSE:
            print(f"\tBATCH {batch_counter} Starting")
        # Task 1 and Task 2
        if tasktype == Batch.TaskType.RDF2TXT or tasktype == Batch.TaskType.TEXT2RDF:
            if VERBOSE:
                print(f"\tExecuting TASK 1 or 2 - BATCH {batch_counter}")
            nano_optim.zero_grad()
            pred_logits: torch.Tensor = NANOSOCRATES((enc_x, enc_x_pad, dec_x, dec_x_pad))
            pred_logits = pred_logits.permute(0, 2, 1)
            loss: torch.Tensor = nano_cross_entropy(pred_logits, tgt)
            loss.backward()
            nano_optim.step()
            text_batch_losses.append(loss)
            continue
        # Pretrain first
        if current_epoch < PRETRAIN_EPOCHS:
            continue
        # Task 3
        if tasktype == Batch.TaskType.MASKING:
            if VERBOSE:
                print(f"\tExecuting TASK 3 - BATCH {batch_counter}")
            encoder_only_optim.zero_grad()
            pred_logits = ENCODER_ONLY((enc_x, enc_x_pad))
            pred_logits = pred_logits.permute(0, 2, 1)
            # print(torch.max(tgt))
            loss: torch.Tensor = encoder_ce(pred_logits, tgt)
            loss.backward()
            encoder_only_optim.step()
            exp_tokens: list[int] = tgt_y[0]
            exp_tokens = list(map(lambda x: MASK_TOKEN if x > TOKENANO.vocabulary_size else x, exp_tokens))
            exp_string = TOKENANO.decode(exp_tokens)
            enc_tokens: list[int] = src_x[0]
            enc_tokens = list(map(lambda x: MASK_TOKEN if x > TOKENANO.vocabulary_size else x, enc_tokens))
            enc_string = TOKENANO.decode(enc_tokens)
            print(f"PROMPT:\n{enc_string}")
            print(f"EXPECTED:\n{exp_string}")
            encoder_batch_losses.append(loss.item())
            continue
        # Task 4
        if tasktype == Batch.TaskType.COMPLETATION:
            if VERBOSE:
                print(f"\tExecuting TASK 4 - BATCH {batch_counter}")
            decoder_only_optim.zero_grad()
            pred_logits = DECODER_ONLY((dec_x, enc_x_pad, dec_x_pad))
            pred_logits = pred_logits.permute(0, 2, 1)
            loss: torch.Tensor = decoder_ce(pred_logits, tgt)
            loss.backward()
            decoder_only_optim.step()
            decoder_batch_losses.append(
                loss
            )
            continue
    nano_scheduler.step()
    encoder_only_scheduler.step()
    decoder_only_scheduler.step()
    current_epoch += 1
    if current_epoch % VALIDATION_STEPS == 0:
        NANOSOCRATES.eval()
        ENCODER_ONLY.eval()
        DECODER_ONLY.eval()
        with torch.no_grad():
            txt_avg_batch_losses = []
            enc_avg_batch_losses = []
            dec_avg_batch_losses = []
            for batch in VALIDATION_BATCHER.batch(MINI_BATCH_SIZE):
                src_x, tgt_y, pad_x, pad_y, tasktype = batch
                enc_x = torch.tensor(src_x)
                ACTUAL_BATCH_SIZE, _ = enc_x.shape
                enc_x_pad = torch.tensor(pad_x, dtype=torch.bool)
                tgt = torch.tensor(tgt_y)
                tgt_pad = torch.tensor(pad_y, dtype=torch.bool)
                dec_x = Transformer.get_decoder_input(
                    ACTUAL_BATCH_SIZE, SOS_TOKEN, PAD_TOKEN, SENTENCE_LENGTH
                )
                dec_x[:, 1:] = tgt[:, :-1]
                dec_x_pad = dec_x.eq(PAD_TOKEN)
                # Task 1 and Task 2
                if (
                    tasktype == Batch.TaskType.RDF2TXT
                    or tasktype == Batch.TaskType.TEXT2RDF
                ):
                    pred_logits = NANOSOCRATES((enc_x, enc_x_pad, dec_x, dec_x_pad))
                    pred_logits = pred_logits.permute(0, 2, 1)
                    loss: torch.Tensor = nano_cross_entropy(
                        pred_logits, tgt
                    )
                    txt_avg_batch_losses.append(loss)
                    continue
                # Pretrain first
                if current_epoch <= PRETRAIN_EPOCHS:
                    continue
                # Task 3
                if tasktype == Batch.TaskType.MASKING:
                    pred_logits = ENCODER_ONLY((enc_x, enc_x_pad))
                    pred_logits = pred_logits.permute(0, 2, 1)
                    loss: torch.Tensor = encoder_ce(pred_logits, tgt)
                    enc_avg_batch_losses.append(loss.item())
                    continue
                # Task 4
                if tasktype == Batch.TaskType.COMPLETATION:
                    pred_logits = DECODER_ONLY((dec_x, enc_x_pad, dec_x_pad))
                    pred_logits = pred_logits.permute(0, 2, 1)
                    loss: torch.Tensor = decoder_ce(pred_logits, tgt)
                    dec_avg_batch_losses.append(loss)
                    continue
        txt_avg_loss = sum(txt_avg_batch_losses) / len(txt_avg_batch_losses)
        enc_avg_loss = float("inf")
        dec_avg_loss = float("inf")
        if current_epoch > PRETRAIN_EPOCHS:
            enc_avg_loss = sum(enc_avg_batch_losses) / len(enc_avg_batch_losses)
            dec_avg_loss = sum(dec_avg_batch_losses) / len(dec_avg_batch_losses)
        if current_epoch < PRETRAIN_EPOCHS:
            if txt_avg_loss < average_loss_validation["txt"]:
                average_loss_validation["txt"] = txt_avg_loss
            else:
                patience += 1
                if VERBOSE:
                    print(f"losing a patience, current irritation: {patience}")
        else:
            counter = 0
            if txt_avg_loss > average_loss_validation["txt"]:
                if VERBOSE:
                    print("txt average is higher than lowest")
                counter += 1
            else:
                average_loss_validation["txt"] = txt_avg_loss
            if enc_avg_loss > average_loss_validation["encoder_only"]:
                if VERBOSE:
                    print("masking average is higher than lowest")
                counter += 1
            else:
                average_loss_validation["encoder_only"] = enc_avg_loss
            if dec_avg_loss > average_loss_validation["decoder_only"]:
                if VERBOSE:
                    print("decoding only average is higher than lowest")
                counter += 1
            else:
                average_loss_validation["decoder_only"] = dec_avg_loss
            if counter > 1:
                patience += 1
                if VERBOSE:
                    print(f"losing a patience, current irritation: {patience}")
            if counter == 0:
                patience = max(0, patience - 1)
                if VERBOSE:
                    print(f"all good, gaining a patience, current irritation: {patience}")
        txt_train_avg_loss = sum(text_batch_losses) / len(text_batch_losses)
        enc_avg_train_loss = float("inf")
        dec_avg_train_loss = float("inf")
        if current_epoch > PRETRAIN_EPOCHS:
            try:
                enc_avg_train_loss = sum(encoder_batch_losses) / len(encoder_batch_losses)
                dec_avg_train_loss = sum(decoder_batch_losses) / len(decoder_batch_losses)
            except:
                pass
        # write on log
        loss_saver.write([current_epoch, txt_train_avg_loss,enc_avg_train_loss,dec_avg_train_loss,txt_avg_loss,enc_avg_loss,dec_avg_loss])
        SEPARATOR = "================================================================================================================"
        DEBUG_TEXT = "".join(
            [
                f"{SEPARATOR}\n",
                f"EPOCH {current_epoch}\n",
                f"{SEPARATOR}\n",
                f"Train Losses:\n",
                f"\tAvg Losses:\n",
                f"\t\tavg_txt: {txt_train_avg_loss} - avg_enc: {enc_avg_train_loss} - avg_dec: {dec_avg_train_loss}\n",
                f"{SEPARATOR}\n",
                f"Validation Losses:\n",
                f"\ttxt_loss: {txt_avg_loss} - masking_loss: {enc_avg_loss} - prediction_loss: {dec_avg_loss}\n",
                f"{SEPARATOR}\n",
            ]
        )
        print(DEBUG_TEXT)
    # Warn about patience
    if patience == PATIENCE:
        print("Model is likely overfitting, so let's stop here")
    # SAVE MODEL
    if current_epoch % CHECKPOINT_STEPS == 0 or patience == PATIENCE:
        print(f"Saving model at {CHECKPOINT_PATH.as_posix()}")
        torch.save(NANOSOCRATES.state_dict(), CHECKPOINT_PATH)
        torch.save(nano_optim.state_dict(), NANO_OPTIM_PATH)
        torch.save(encoder_only_optim.state_dict(), ENC_OPTIM_PATH)
        torch.save(decoder_only_optim.state_dict(), DEC_OPTIM_PATH)
        FILE = open(LAST_EPOCH_PATH, "w", encoding="utf-8")
        FILE.write(f"{current_epoch}")
        FILE.close()
    if patience == PATIENCE:
        exit(0)
--- a/Playgrounds/nanosocrates-train-toy.ipynb
+++ b/Playgrounds/nanosocrates-train-toy.ipynb
@@ -11,13 +11,7 @@
     "output_type": "stream",
     "text": [
      "c:\\Users\\Chris\\miniconda3\\envs\\deep_learning\\Lib\\site-packages\\torch\\utils\\_device.py:103: UserWarning: Aten Op fallback from XPU to CPU happends. This may have performance implications. If need debug the fallback ops please set environment variable `PYTORCH_DEBUG_XPU_FALLBACK=1`  (Triggered internally at C:\\actions-runner\\_work\\pytorch\\pytorch\\pytorch\\build\\xpu\\ATen\\RegisterXPU_0.cpp:54528.)\n",
-      "  return func(*args, **kwargs)\n",
+      "  return func(*args, **kwargs)\n"
      "252.87s - name 'tensor' is not defined\n",
      "Traceback (most recent call last):\n",
      "  File \"c:\\Users\\Chris\\miniconda3\\envs\\deep_learning\\Lib\\site-packages\\debugpy\\_vendored\\pydevd\\_pydevd_bundle\\pydevd_vars.py\", line 636, in change_attr_expression\n",
      "    value = eval(expression, frame.f_globals, frame.f_locals)\n",
      "  File \"<string>\", line 1, in <module>\n",
      "NameError: name 'tensor' is not defined\n"
     ]
    },
    {
@@ -25,15 +19,9 @@
     "evalue": "",
     "output_type": "error",
     "traceback": [
-      "\u001b[1;31mCannot execute code, session has been disposed. Please try restarting the Kernel."
+      "\u001b[1;31mThe Kernel crashed while executing code in the current cell or a previous cell. \n",
-     ]
+      "\u001b[1;31mPlease review the code in the cell(s) to identify a possible cause of the failure. \n",
-    },
+      "\u001b[1;31mClick <a href='https://aka.ms/vscodeJupyterKernelCrash'>here</a> for more info. \n",
    {
     "ename": "",
     "evalue": "",
     "output_type": "error",
     "traceback": [
      "\u001b[1;31mCannot execute code, session has been disposed. Please try restarting the Kernel. \n",
      "\u001b[1;31mView Jupyter <a href='command:jupyter.viewOutput'>log</a> for further details."
     ]
    }
@@ -68,9 +56,9 @@
    "TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size + 1\n",
    "EMBEDDED_SIZE = 256\n",
    "FEED_FORWARD_MULTIPLIER =  4\n",
-    "ATTENTION_HEADS = 4\n",
+    "ATTENTION_HEADS = 8\n",
    "SENTENCE_LENGTH = 256\n",
-    "NUMBER_OF_BLOCKS = 2\n",
+    "NUMBER_OF_BLOCKS = 4\n",
    "MAX_EPOCHS = int(1e3)\n",
    "\n",
    "\n",
@@ -105,7 +93,26 @@
    "        output_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN\n",
    "    )\n",
    "    decoder_default_tokens, _ = Transformer.normalize_sequence(\n",
-    "        decoder_default_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN\n",
+    "        decoder_default_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN, False\n",
    "    )\n",
    "\n",
    "    TOY_BATCH_INPUT_LIST.append(input_tokens)\n",
    "    TOY_BATCH_PADDING_LIST.append(padding)\n",
    "    TOY_BATCH_TARGET_LIST.append(output_tokens)\n",
    "    TOY_BATCH_DECODER_DEFAULT.append(decoder_default_tokens)\n",
    "\n",
    "    output_tokens = TOKENANO.encode(RDFs)\n",
    "    input_tokens = TOKENANO.encode(Abstract)[1:]\n",
    "    decoder_default_tokens = TOKENANO.encode(\"<SOS>\")\n",
    "\n",
    "    input_tokens, padding = Transformer.normalize_sequence(\n",
    "        input_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN\n",
    "    )\n",
    "    output_tokens, _ = Transformer.normalize_sequence(\n",
    "        output_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN\n",
    "    )\n",
    "    decoder_default_tokens, _ = Transformer.normalize_sequence(\n",
    "        decoder_default_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN, False\n",
    "    )\n",
    "\n",
    "    TOY_BATCH_INPUT_LIST.append(input_tokens)\n",
@@ -124,7 +131,7 @@
    ")\n",
    "cross_entropy = torch.nn.CrossEntropyLoss(ignore_index=PAD_TOKEN)\n",
    "optimizer = torch.optim.AdamW(NANOSOCRATES.parameters())\n",
-    "scheduler = torch.optim.lr_scheduler.StepLR(optimizer, 4)\n",
+    "scheduler = Transformer.WarmupLR(optimizer, 4000, EMBEDDED_SIZE)\n",
    "last_loss = 0\n",
    "current_epoch = 0\n",
    "\n",
@@ -132,32 +139,44 @@
    "\n",
    "    optimizer.zero_grad()\n",
    "\n",
-    "    encoder_list = torch.tensor([TOY_BATCH_INPUT_LIST[0]])\n",
+    "    encoder_list = torch.tensor(TOY_BATCH_INPUT_LIST[:])\n",
-    "    decoder_list = torch.tensor([TOY_BATCH_DECODER_DEFAULT[0]])\n",
+    "    decoder_list = torch.tensor(TOY_BATCH_DECODER_DEFAULT[:])\n",
-    "    padding_list = torch.tensor([TOY_BATCH_PADDING_LIST[0]], dtype=torch.bool)\n",
+    "    src_padding = torch.tensor(TOY_BATCH_PADDING_LIST[:], dtype=torch.bool)\n",
    "\n",
    "    # Transform target into logits\n",
-    "    target_logits = torch.tensor([TOY_BATCH_TARGET_LIST[0]])\n",
+    "    target_logits = torch.tensor(TOY_BATCH_TARGET_LIST[:])\n",
    "\n",
    "    last_loss = 0\n",
    "    last_prediction: torch.Tensor\n",
    "\n",
    "    for i in range(0, SENTENCE_LENGTH):\n",
    "\n",
    "        optimizer.zero_grad()\n",
    "        tgt_padding = decoder_list.eq(PAD_TOKEN)\n",
    "\n",
-    "        logits: torch.Tensor = NANOSOCRATES((encoder_list, padding_list, decoder_list))\n",
+    "        logits: torch.Tensor = NANOSOCRATES((encoder_list, src_padding, decoder_list, tgt_padding))\n",
    "        prob = torch.softmax(logits, 2)\n",
    "\n",
-    "        most_probable_tokens = torch.argmax(logits, 2)\n",
+    "        most_probable_tokens = torch.argmax(prob, 2)\n",
    "        last_prediction = most_probable_tokens\n",
    "\n",
-    "        logits = logits[:,i,:]\n",
+    "        logits = logits[:,:i,:]\n",
    "        logits = logits.permute(0, 2, 1)\n",
    "\n",
    "        loss : torch.Tensor = cross_entropy(logits, target_logits[:, 0:i])\n",
    "        # loss : torch.Tensor = cross_entropy(logits, target_logits)\n",
    "\n",
    "        loss = cross_entropy(logits, target_logits[:,i])\n",
    "        last_loss = loss\n",
    "        loss.backward()\n",
    "        optimizer.step()\n",
    "        scheduler.step()\n",
    "\n",
    "        if i < SENTENCE_LENGTH - 1:\n",
-    "            decoder_list[:,i+1] = most_probable_tokens[:,i]\n",
+    "            decoder_list[:,i+1] = target_logits[:,i]\n",
    "\n",
    "\n",
    "\n",
    "\n",
    "\n",
    "\n",
    "    current_epoch += 1\n",
@@ -165,6 +184,14 @@
    "    if current_epoch % 1 == 0:\n",
    "        print(f\"EPOCH {current_epoch}\\n\\tLoss: {last_loss}\")\n",
    "\n",
    "        for encoded_sentence, expected_sentence in zip(\n",
    "            Transformer.tensor2token(last_prediction[:,:], END_TOKEN), # type: ignore\n",
    "            Transformer.tensor2token(target_logits[:,:], END_TOKEN)\n",
    "        ):\n",
    "            decoded_sentence = TOKENANO.decode(encoded_sentence)\n",
    "            decoded_target = TOKENANO.decode(expected_sentence)\n",
    "            print(f\"\\tACTUAL:\\n\\t\\t{decoded_sentence}\\n\\tEXPECTED:\\n\\t\\t{decoded_target}\\n\")\n",
    "\n",
    "\n",
    "\n",
    "\n",
--- a/Playgrounds/nanosocrates-train.ipynb
+++ b/Playgrounds/nanosocrates-train.ipynb
@@ -0,0 +1,509 @@
 {
 "cells": [
  {
   "cell_type": "code",
   "execution_count": 1,
   "id": "adbef43f",
   "metadata": {},
   "outputs": [
    {
     "name": "stderr",
     "output_type": "stream",
     "text": [
      "c:\\Users\\Chris\\miniconda3\\envs\\deep_learning\\Lib\\site-packages\\torch\\utils\\_device.py:103: UserWarning: Aten Op fallback from XPU to CPU happends. This may have performance implications. If need debug the fallback ops please set environment variable `PYTORCH_DEBUG_XPU_FALLBACK=1`  (Triggered internally at C:\\actions-runner\\_work\\pytorch\\pytorch\\pytorch\\build\\xpu\\ATen\\RegisterXPU_0.cpp:54528.)\n",
      "  return func(*args, **kwargs)\n",
      "c:\\Users\\Chris\\miniconda3\\envs\\deep_learning\\Lib\\site-packages\\torch\\optim\\lr_scheduler.py:192: UserWarning: Detected call of `lr_scheduler.step()` before `optimizer.step()`. In PyTorch 1.1.0 and later, you should call them in the opposite order: `optimizer.step()` before `lr_scheduler.step()`.  Failure to do this will result in PyTorch skipping the first value of the learning rate schedule. See more details at https://pytorch.org/docs/stable/optim.html#how-to-adjust-learning-rate\n",
      "  warnings.warn(\n"
     ]
    },
    {
     "ename": "IndexError",
     "evalue": "list index out of range",
     "output_type": "error",
     "traceback": [
      "\u001b[31m---------------------------------------------------------------------------\u001b[39m",
      "\u001b[31mIndexError\u001b[39m                                Traceback (most recent call last)",
      "\u001b[36mCell\u001b[39m\u001b[36m \u001b[39m\u001b[32mIn[1]\u001b[39m\u001b[32m, line 383\u001b[39m\n\u001b[32m    381\u001b[39m txt_min_train_losses = text_batch_losses[:][\u001b[32m0\u001b[39m]\n\u001b[32m    382\u001b[39m txt_avg_train_losses = text_batch_losses[:][\u001b[32m1\u001b[39m]\n\u001b[32m--> \u001b[39m\u001b[32m383\u001b[39m txt_max_train_losses = \u001b[43mtext_batch_losses\u001b[49m\u001b[43m[\u001b[49m\u001b[43m:\u001b[49m\u001b[43m]\u001b[49m\u001b[43m[\u001b[49m\u001b[32;43m2\u001b[39;49m\u001b[43m]\u001b[49m\n\u001b[32m    385\u001b[39m txt_min_loss = \u001b[38;5;28mmin\u001b[39m(txt_min_train_losses)\n\u001b[32m    386\u001b[39m txt_avg_min_loss = \u001b[38;5;28msum\u001b[39m(txt_min_train_losses) / \u001b[38;5;28mlen\u001b[39m(txt_min_train_losses)\n",
      "\u001b[31mIndexError\u001b[39m: list index out of range"
     ]
    }
   ],
   "source": [
    "import random\n",
    "import sys\n",
    "import torch\n",
    "import pandas as pd\n",
    "from pathlib import Path\n",
    "import Project_Model.Libs.Embedder as Embedder\n",
    "import Project_Model.Libs.BPE as BPE\n",
    "import Project_Model.Libs.Transformer as Transformer\n",
    "import Project_Model.Libs.TransformerUtils as TUtils\n",
    "import Project_Model.Libs.TorchShims as torch_shims\n",
    "import Project_Model.Libs.Batch as Batch\n",
    "\n",
    "# set a fixed seed\n",
    "torch.manual_seed(0)\n",
    "random.seed(0)\n",
    "\n",
    "\n",
    "# set a default device\n",
    "DEVICE = torch_shims.get_default_device()\n",
    "torch.set_default_device(DEVICE)\n",
    "\n",
    "\n",
    "# Get paths\n",
    "VOCABULARY_PATH = Path(\"Assets/Model/small/bpe-small-16.json\")\n",
    "TRAIN_DATASET_PATH = Path(\"Assets/Dataset/1-hop/toy/rdf_text.csv\")\n",
    "VALIDATION_DATASET_PATH = Path(\"Assets/Dataset/1-hop/toy/rdf_text.csv\")\n",
    "TEST_DATASET_PATH = Path(\"Assets/Dataset/1-hop/toy/rdf_text.csv\")\n",
    "CHECKPOINT_PATH = Path(\"Assets/Dataset/Tmp/NanoSocrates.zip\")\n",
    "\n",
    "\n",
    "# BPE Init\n",
    "SPECIAL_VOC = BPE.default_special_tokens()\n",
    "VOCABULARY = BPE.load_nanos_vocabulary(VOCABULARY_PATH)\n",
    "TOKENANO = BPE.TokeNanoCore(VOCABULARY, SPECIAL_VOC)\n",
    "\n",
    "\n",
    "# Constants\n",
    "MASK_EXTRA_SPACE = 25\n",
    "TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size  + MASK_EXTRA_SPACE\n",
    "EMBEDDED_SIZE = 256\n",
    "FEED_FORWARD_MULTIPLIER =  4\n",
    "ATTENTION_HEADS = 8\n",
    "SENTENCE_LENGTH = 256\n",
    "NUMBER_OF_BLOCKS = 4\n",
    "MAX_EPOCHS = int(1e3)\n",
    "PRETRAIN_EPOCHS = int(2)\n",
    "WARMUP_EPOCHS = int(4e3)\n",
    "MINI_BATCH_SIZE = 10\n",
    "VALIDATION_STEPS = 1\n",
    "CHECKPOINT_STEPS = VALIDATION_STEPS * 4\n",
    "PATIENCE = 4\n",
    "CURRENT_EPOCH = 0\n",
    "\n",
    "SOS_TOKEN = TOKENANO.encode(\"<SOS>\")[0]\n",
    "\n",
    "PAD_TOKEN = TOKENANO.encode(\"<PAD>\")[0]\n",
    "END_TOKEN = TOKENANO.encode(\"<END>\")[0]\n",
    "SUBJ_TOKEN = TOKENANO.encode(\"<SUBJ>\")[0]\n",
    "REL_TOKEN = TOKENANO.encode(\"<PRED>\")[0]\n",
    "OBJ_TOKEN = TOKENANO.encode(\"<OBJ>\")[0]\n",
    "\n",
    "SPECIAL_TOKENS: set[int] = set(TOKENANO.encode(\"\".join(BPE.default_special_tokens())))\n",
    "ALLOWED_TOKENS = set([SUBJ_TOKEN, REL_TOKEN, OBJ_TOKEN])\n",
    "FORBIDDEN_TOKENS = SPECIAL_TOKENS - ALLOWED_TOKENS\n",
    "\n",
    "\n",
    "# Spanned_Masker\n",
    "MASKER = Transformer.SpannedMasker(\n",
    "    TOKEN_SPACE_SIZE,\n",
    "    FORBIDDEN_TOKENS\n",
    ")\n",
    "\n",
    "TRAIN_BATCHER = Batch.Batcher(\n",
    "    TRAIN_DATASET_PATH,\n",
    "    SENTENCE_LENGTH,\n",
    "    TOKENANO,\n",
    "    MASKER\n",
    ")\n",
    "VALIDATION_BATCHER = Batch.Batcher(\n",
    "    VALIDATION_DATASET_PATH,\n",
    "    SENTENCE_LENGTH,\n",
    "    TOKENANO,\n",
    "    MASKER\n",
    ")\n",
    "TEST_BATCHER = Batch.Batcher(\n",
    "    TEST_DATASET_PATH,\n",
    "    SENTENCE_LENGTH,\n",
    "    TOKENANO,\n",
    "    MASKER\n",
    ")\n",
    "\n",
    "\n",
    "# Model\n",
    "NANOSOCRATES = Transformer.TrainingModel(\n",
    "    TOKEN_SPACE_SIZE,\n",
    "    EMBEDDED_SIZE,\n",
    "    FEED_FORWARD_MULTIPLIER,\n",
    "    ATTENTION_HEADS,\n",
    "    NUMBER_OF_BLOCKS\n",
    ")\n",
    "_, ENCODER_ONLY, DECODER_ONLY = TUtils.decompose_nano_socrates(\n",
    "    NANOSOCRATES,\n",
    "    TOKEN_SPACE_SIZE,\n",
    "    EMBEDDED_SIZE\n",
    ")\n",
    "\n",
    "\n",
    "# Training constants\n",
    "cross_entropy = torch.nn.CrossEntropyLoss(ignore_index=PAD_TOKEN)\n",
    "nano_optim = torch.optim.AdamW(NANOSOCRATES.parameters())\n",
    "encoder_only_optim = torch.optim.AdamW(ENCODER_ONLY.parameters())\n",
    "decoder_only_optim = torch.optim.AdamW(DECODER_ONLY.parameters())\n",
    "\n",
    "nano_scheduler = Transformer.WarmupLR(nano_optim, WARMUP_EPOCHS, EMBEDDED_SIZE)\n",
    "encoder_only_scheduler = Transformer.WarmupLR(encoder_only_optim, WARMUP_EPOCHS, EMBEDDED_SIZE)\n",
    "decoder_only_scheduler = Transformer.WarmupLR(decoder_only_optim, WARMUP_EPOCHS, EMBEDDED_SIZE)\n",
    "\n",
    "current_epoch = CURRENT_EPOCH\n",
    "patience = 0\n",
    "\n",
    "\n",
    "average_loss_validation = {\n",
    "    \"txt\": float(\"inf\"),\n",
    "    \"encoder_only\": float(\"inf\"),\n",
    "    \"decoder_only\": float(\"inf\")\n",
    "}\n",
    "\n",
    "while current_epoch < MAX_EPOCHS:\n",
    "\n",
    "    text_batch_losses = []\n",
    "    encoder_batch_losses = []\n",
    "    decoder_batch_losses = []\n",
    "\n",
    "    for batch in TRAIN_BATCHER.batch(MINI_BATCH_SIZE):\n",
    "\n",
    "        src_x, tgt_y, pad_x, pad_y, tasktype = batch\n",
    "\n",
    "        enc_x = torch.tensor(src_x)\n",
    "        enc_x_pad = torch.tensor(pad_x, dtype=torch.bool)\n",
    "        dec_x = Transformer.get_decoder_input(MINI_BATCH_SIZE, SOS_TOKEN, PAD_TOKEN, SENTENCE_LENGTH)\n",
    "        dec_x_pad = dec_x.eq(PAD_TOKEN)\n",
    "        tgt = torch.tensor(tgt_y)\n",
    "        tgt_pad = torch.tensor(pad_y, dtype=torch.bool)\n",
    "\n",
    "        # Task 1 and Task 2\n",
    "        if tasktype == Batch.TaskType.RDF2TXT or tasktype == Batch.TaskType.TEXT2RDF:\n",
    "\n",
    "            BATCH_LOSS = []\n",
    "\n",
    "            for token_idx in range(0, SENTENCE_LENGTH):\n",
    "\n",
    "                nano_optim.zero_grad()\n",
    "\n",
    "\n",
    "\n",
    "                pred_logits = NANOSOCRATES((\n",
    "                    enc_x, enc_x_pad, dec_x, dec_x_pad\n",
    "                ))\n",
    "\n",
    "                pred_logits = pred_logits[:, token_idx, :]\n",
    "\n",
    "                loss: torch.Tensor= cross_entropy(pred_logits, tgt[:, token_idx])\n",
    "\n",
    "                loss.backward()\n",
    "                nano_optim.step()\n",
    "\n",
    "\n",
    "                BATCH_LOSS.append(\n",
    "                    loss.item()\n",
    "                )\n",
    "\n",
    "                if token_idx < SENTENCE_LENGTH - 1:\n",
    "                    dec_x[:,token_idx + 1] = tgt[:, token_idx]\n",
    "\n",
    "            MIN_BATCH_LOSS = min(BATCH_LOSS)\n",
    "            MAX_BATCH_LOSS = max(BATCH_LOSS)\n",
    "            AVG_BATCH_LOSS = sum(BATCH_LOSS) / MINI_BATCH_SIZE\n",
    "\n",
    "            text_batch_losses.append([MIN_BATCH_LOSS, AVG_BATCH_LOSS, MAX_BATCH_LOSS])\n",
    "            continue\n",
    "\n",
    "\n",
    "        # Pretrain first\n",
    "        if current_epoch < PRETRAIN_EPOCHS:\n",
    "            continue\n",
    "\n",
    "\n",
    "        # Task 3\n",
    "        if tasktype == Batch.TaskType.MASKING:\n",
    "\n",
    "            encoder_only_optim.zero_grad()\n",
    "\n",
    "            pred_logits = ENCODER_ONLY((\n",
    "                enc_x, enc_x_pad\n",
    "            ))\n",
    "\n",
    "            loss: torch.Tensor= cross_entropy(pred_logits, tgt)\n",
    "\n",
    "            loss.backward()\n",
    "            encoder_only_optim.step()\n",
    "\n",
    "            encoder_batch_losses.append(\n",
    "                loss.item()\n",
    "            )\n",
    "\n",
    "            continue\n",
    "\n",
    "\n",
    "        # Task 4\n",
    "        if tasktype == Batch.TaskType.COMPLETATION:\n",
    "\n",
    "            BATCH_LOSS = []\n",
    "\n",
    "            for token_idx in range(0, SENTENCE_LENGTH):\n",
    "\n",
    "                decoder_only_optim.zero_grad()\n",
    "\n",
    "                pred_logits = DECODER_ONLY((\n",
    "                    enc_x, enc_x_pad\n",
    "                ))\n",
    "\n",
    "                pred_logits = pred_logits[:, token_idx, :]\n",
    "\n",
    "                loss: torch.Tensor= cross_entropy(pred_logits, tgt[:, token_idx])\n",
    "\n",
    "                loss.backward()\n",
    "                decoder_only_optim.step()\n",
    "\n",
    "                BATCH_LOSS.append(\n",
    "                    loss.item()\n",
    "                )\n",
    "\n",
    "                if token_idx < SENTENCE_LENGTH - 1:\n",
    "                    dec_x[:,token_idx + 1] = tgt[:, token_idx]\n",
    "\n",
    "\n",
    "            MIN_BATCH_LOSS = min(BATCH_LOSS)\n",
    "            MAX_BATCH_LOSS = max(BATCH_LOSS)\n",
    "            AVG_BATCH_LOSS = sum(BATCH_LOSS) / MINI_BATCH_SIZE\n",
    "\n",
    "            decoder_batch_losses.append([MIN_BATCH_LOSS, AVG_BATCH_LOSS, MAX_BATCH_LOSS])\n",
    "\n",
    "            continue\n",
    "\n",
    "\n",
    "    nano_scheduler.step()\n",
    "    encoder_only_scheduler.step()\n",
    "    decoder_only_scheduler.step()\n",
    "\n",
    "    current_epoch += 1\n",
    "\n",
    "    if current_epoch % VALIDATION_STEPS == 0:\n",
    "\n",
    "        txt_avg_batch_losses = []\n",
    "        enc_avg_batch_losses = []\n",
    "        dec_avg_batch_losses = []\n",
    "\n",
    "        for batch in VALIDATION_BATCHER.batch(MINI_BATCH_SIZE):\n",
    "\n",
    "            src_x, tgt_y, pad_x,  pad_y, tasktype = batch\n",
    "\n",
    "            enc_x = torch.tensor(src_x)\n",
    "            enc_x_pad = torch.tensor(pad_x, dtype=torch.bool)\n",
    "            dec_x = Transformer.get_decoder_input(MINI_BATCH_SIZE, SOS_TOKEN, PAD_TOKEN, SENTENCE_LENGTH)\n",
    "            dec_x_pad = dec_x.eq(PAD_TOKEN)\n",
    "            tgt = torch.tensor(tgt_y)\n",
    "            tgt_pad = torch.tensor(pad_y, dtype=torch.bool)\n",
    "\n",
    "            # Task 1 and Task 2\n",
    "            if tasktype == Batch.TaskType.RDF2TXT or tasktype == Batch.TaskType.TEXT2RDF:\n",
    "\n",
    "                BATCH_LOSS = []\n",
    "\n",
    "                for token_idx in range(0, SENTENCE_LENGTH):\n",
    "\n",
    "\n",
    "\n",
    "                    pred_logits = NANOSOCRATES((\n",
    "                        enc_x, enc_x_pad, dec_x, dec_x_pad\n",
    "                    ))\n",
    "\n",
    "                    pred_logits = pred_logits[:, token_idx, :]\n",
    "\n",
    "                    loss: torch.Tensor= cross_entropy(pred_logits, tgt[:, token_idx])\n",
    "\n",
    "\n",
    "                    BATCH_LOSS.append(\n",
    "                        loss.item()\n",
    "                    )\n",
    "\n",
    "                    if token_idx < SENTENCE_LENGTH - 1:\n",
    "                        dec_x[:,token_idx + 1] = tgt[:, token_idx]\n",
    "\n",
    "\n",
    "                AVG_BATCH_LOSS = sum(BATCH_LOSS) / MINI_BATCH_SIZE\n",
    "                txt_avg_batch_losses.append(AVG_BATCH_LOSS)\n",
    "\n",
    "                continue\n",
    "\n",
    "\n",
    "            # Pretrain first\n",
    "            if current_epoch < PRETRAIN_EPOCHS:\n",
    "                continue\n",
    "\n",
    "\n",
    "            # Task 3\n",
    "            if tasktype == Batch.TaskType.MASKING:\n",
    "\n",
    "                pred_logits = ENCODER_ONLY((\n",
    "                    enc_x, enc_x_pad\n",
    "                ))\n",
    "\n",
    "                loss: torch.Tensor= cross_entropy(pred_logits, tgt)\n",
    "\n",
    "                enc_avg_batch_losses.append(\n",
    "                    loss.item()\n",
    "                )\n",
    "\n",
    "                continue\n",
    "\n",
    "\n",
    "            # Task 4\n",
    "            if tasktype == Batch.TaskType.COMPLETATION:\n",
    "\n",
    "                BATCH_LOSS = []\n",
    "\n",
    "                for token_idx in range(0, SENTENCE_LENGTH):\n",
    "\n",
    "                    pred_logits = DECODER_ONLY((\n",
    "                        enc_x, enc_x_pad\n",
    "                    ))\n",
    "\n",
    "                    pred_logits = pred_logits[:, token_idx, :]\n",
    "\n",
    "                    loss: torch.Tensor= cross_entropy(pred_logits, tgt[:, token_idx])\n",
    "\n",
    "                    BATCH_LOSS.append(\n",
    "                        loss.item()\n",
    "                    )\n",
    "\n",
    "                    if token_idx < SENTENCE_LENGTH - 1:\n",
    "                        dec_x[:,token_idx + 1] = tgt[:, token_idx]\n",
    "\n",
    "\n",
    "                AVG_BATCH_LOSS = sum(BATCH_LOSS) / MINI_BATCH_SIZE\n",
    "\n",
    "                dec_avg_batch_losses.append(AVG_BATCH_LOSS)\n",
    "\n",
    "                continue\n",
    "\n",
    "        txt_avg_loss = sum(txt_avg_batch_losses) / len(txt_avg_batch_losses)\n",
    "        enc_avg_loss = float(\"inf\")\n",
    "        dec_avg_loss = float(\"inf\")\n",
    "\n",
    "        if current_epoch >= PRETRAIN_EPOCHS:\n",
    "            enc_avg_loss = sum(enc_avg_batch_losses) / len(enc_avg_batch_losses)\n",
    "            dec_avg_loss = sum(dec_avg_batch_losses) / len(dec_avg_batch_losses)\n",
    "\n",
    "        if current_epoch < PRETRAIN_EPOCHS:\n",
    "\n",
    "            if txt_avg_loss < average_loss_validation[\"txt\"]:\n",
    "                average_loss_validation[\"txt\"] = txt_avg_loss\n",
    "            else:\n",
    "                patience += 1\n",
    "        else:\n",
    "\n",
    "            counter = 0\n",
    "\n",
    "            if txt_avg_loss > average_loss_validation[\"txt\"]:\n",
    "                counter += 1\n",
    "\n",
    "            if txt_avg_loss > average_loss_validation[\"encoder_only\"]:\n",
    "                counter += 1\n",
    "\n",
    "            if txt_avg_loss > average_loss_validation[\"decoder_only\"]:\n",
    "                counter += 1\n",
    "\n",
    "            if counter > 1:\n",
    "                patience += 1\n",
    "\n",
    "        txt_min_train_losses = text_batch_losses[:][0]\n",
    "        txt_avg_train_losses = text_batch_losses[:][1]\n",
    "        txt_max_train_losses = text_batch_losses[:][2]\n",
    "\n",
    "        txt_min_loss = min(txt_min_train_losses)\n",
    "        txt_avg_min_loss = sum(txt_min_train_losses) / len(txt_min_train_losses)\n",
    "        txt_max_loss = max(txt_max_train_losses)\n",
    "        txt_avg_max_loss = sum(txt_max_train_losses) / len(txt_max_train_losses)\n",
    "        txt_avg_loss = sum(txt_avg_train_losses) / len(txt_avg_train_losses)\n",
    "\n",
    "        enc_avg_train_loss = float(\"inf\")\n",
    "\n",
    "        dec_min_loss = float(\"inf\")\n",
    "        dec_avg_min_loss = float(\"inf\")\n",
    "        dec_max_loss = float(\"inf\")\n",
    "        dec_avg_max_loss = float(\"inf\")\n",
    "        dec_avg_loss = float(\"inf\")\n",
    "\n",
    "        if current_epoch >= PRETRAIN_EPOCHS:\n",
    "            enc_avg_train_loss = sum(encoder_batch_losses) / len(encoder_batch_losses)\n",
    "\n",
    "            dec_min_train_losses = decoder_batch_losses[:][0]\n",
    "            dec_avg_train_losses = decoder_batch_losses[:][1]\n",
    "            dec_max_train_losses = decoder_batch_losses[:][2]\n",
    "\n",
    "            dec_min_loss = min(dec_min_train_losses)\n",
    "            dec_avg_min_loss = sum(dec_min_train_losses) / len(dec_min_train_losses)\n",
    "            dec_max_loss = max(dec_max_train_losses)\n",
    "            dec_avg_max_loss = sum(dec_max_train_losses) / len(dec_max_train_losses)\n",
    "            dec_avg_loss = sum(dec_avg_train_losses) / len(dec_avg_train_losses)\n",
    "\n",
    "\n",
    "        SEPARATOR = \"===========================================================================================\"\n",
    "        DEBUG_TEXT = \"\".join([\n",
    "            f\"{SEPARATOR}\\n\",\n",
    "            f\"EPOCH {current_epoch}\"\n",
    "            f\"{SEPARATOR}\\n\",\n",
    "            f\"Train Losses:\\n\"\n",
    "            f\"\\tMin Losses:\\n\"\n",
    "            f\"\\t\\tmin_txt: {txt_min_loss} - avg_txt: {txt_avg_min_loss}\\n\"\n",
    "            f\"\\t\\tmin_dec: {dec_min_loss} - avg_dec: {dec_avg_min_loss}\\n\"\n",
    "            f\"\\tMax Losses:\\n\"\n",
    "            f\"\\t\\tmax_txt: {txt_max_loss} - avg_txt: {txt_avg_max_loss}\\n\"\n",
    "            f\"\\t\\tmax_dec: {dec_min_loss} - avg_dec: {dec_avg_max_loss}\\n\"\n",
    "            f\"\\tAvg Losses:\\n\"\n",
    "            f\"\\t\\tavg_txt: {txt_avg_loss} - avg_enc: {enc_avg_loss} - avg_dec: {dec_avg_loss}\\n\"\n",
    "            f\"{SEPARATOR}\\n\",\n",
    "            f\"Validation Losses:\\n\"\n",
    "            f\"\\ttxt_loss: {txt_avg_loss} - masking_loss: {enc_avg_loss} - prediction: {dec_avg_loss}\"\n",
    "            f\"{SEPARATOR}\\n\",\n",
    "        ])\n",
    "\n",
    "\n",
    "\n",
    "\n",
    "\n",
    "    # Warn about patience\n",
    "    if patience == PATIENCE:\n",
    "        print(\n",
    "            \"Model is likely overfitting, so let's stop here\"\n",
    "        )\n",
    "\n",
    "    # SAVE MODEL\n",
    "    if current_epoch % CHECKPOINT_STEPS == 0 or patience == PATIENCE:\n",
    "        print(f\"Saving model at {CHECKPOINT_PATH.as_posix()}\")\n",
    "        torch.save(NANOSOCRATES.state_dict(), CHECKPOINT_PATH)\n",
    "\n",
    "\n",
    "\n",
    "\n",
    "\n",
    "\n",
    "\n"
   ]
  }
 ],
 "metadata": {
  "kernelspec": {
   "display_name": "deep_learning",
   "language": "python",
   "name": "python3"
  },
  "language_info": {
   "codemirror_mode": {
    "name": "ipython",
    "version": 3
   },
   "file_extension": ".py",
   "mimetype": "text/x-python",
   "name": "python",
   "nbconvert_exporter": "python",
   "pygments_lexer": "ipython3",
   "version": "3.13.7"
  }
 },
 "nbformat": 4,
 "nbformat_minor": 5
 }
--- a/Playgrounds/nanosocrates-train.py
+++ b/Playgrounds/nanosocrates-train.py
@@ -0,0 +1,433 @@
 import random
 import sys
 import torch
 import pandas as pd
 from pathlib import Path
 import Project_Model.Libs.Embedder as Embedder
 import Project_Model.Libs.BPE as BPE
 import Project_Model.Libs.Transformer as Transformer
 import Project_Model.Libs.TransformerUtils as TUtils
 import Project_Model.Libs.TorchShims as torch_shims
 import Project_Model.Libs.Batch as Batch
 # set a fixed seed
 torch.manual_seed(0)
 random.seed(0)
 # set a default device
 DEVICE = torch_shims.get_default_device()
 torch.set_default_device(DEVICE)
 # Get paths
 VOCABULARY_PATH = Path("Assets/Model/small/bpe-small-16.json")
 TRAIN_DATASET_PATH = Path("Assets/Dataset/1-hop/small/holdout/train.csv")
 VALIDATION_DATASET_PATH = Path("Assets/Dataset/1-hop/small/holdout/evaluation.csv")
 TEST_DATASET_PATH = Path("Assets/Dataset/1-hop/small/holdout/test.csv")
 CHECKPOINT_PATH = Path("Assets/Dataset/Tmp/NanoSocrates.zip")
 # BPE Init
 SPECIAL_VOC = BPE.default_special_tokens()
 VOCABULARY = BPE.load_nanos_vocabulary(VOCABULARY_PATH)
 TOKENANO = BPE.TokeNanoCore(VOCABULARY, SPECIAL_VOC)
 # Constants
 MASK_EXTRA_SPACE = 100
 REAL_TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size
 TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size + MASK_EXTRA_SPACE
 EMBEDDED_SIZE = 256
 FEED_FORWARD_MULTIPLIER = 4
 ATTENTION_HEADS = 8
 SENTENCE_LENGTH = 256
 NUMBER_OF_BLOCKS = 4
 MAX_EPOCHS = int(1e3)
 PRETRAIN_EPOCHS = int(10)
 WARMUP_EPOCHS = int(4e3)
 MINI_BATCH_SIZE = 100
 VALIDATION_STEPS = 5
 CHECKPOINT_STEPS = VALIDATION_STEPS * 4
 PATIENCE = 4
 CURRENT_EPOCH = 0
 SOS_TOKEN = TOKENANO.encode("<SOS>")[0]
 PAD_TOKEN = TOKENANO.encode("<PAD>")[0]
 END_TOKEN = TOKENANO.encode("<END>")[0]
 SUBJ_TOKEN = TOKENANO.encode("<SUBJ>")[0]
 REL_TOKEN = TOKENANO.encode("<PRED>")[0]
 OBJ_TOKEN = TOKENANO.encode("<OBJ>")[0]
 SPECIAL_TOKENS: set[int] = set(TOKENANO.encode("".join(BPE.default_special_tokens())))
 ALLOWED_TOKENS = set([SUBJ_TOKEN, REL_TOKEN, OBJ_TOKEN])
 FORBIDDEN_TOKENS = SPECIAL_TOKENS - ALLOWED_TOKENS
 # Spanned_Masker
 MASKER = Transformer.SpannedMasker(REAL_TOKEN_SPACE_SIZE, FORBIDDEN_TOKENS)
 TRAIN_BATCHER = Batch.Batcher(TRAIN_DATASET_PATH, SENTENCE_LENGTH, TOKENANO, MASKER)
 VALIDATION_BATCHER = Batch.Batcher(
    VALIDATION_DATASET_PATH, SENTENCE_LENGTH, TOKENANO, MASKER
 )
 TEST_BATCHER = Batch.Batcher(TEST_DATASET_PATH, SENTENCE_LENGTH, TOKENANO, MASKER)
 # Model
 NANOSOCRATES = Transformer.TrainingModel(
    TOKEN_SPACE_SIZE,
    EMBEDDED_SIZE,
    FEED_FORWARD_MULTIPLIER,
    ATTENTION_HEADS,
    NUMBER_OF_BLOCKS,
 )
 _, ENCODER_ONLY, DECODER_ONLY = TUtils.decompose_nano_socrates(
    NANOSOCRATES, TOKEN_SPACE_SIZE, EMBEDDED_SIZE
 )
 # Training constants
 nano_cross_entropy = torch.nn.CrossEntropyLoss(ignore_index=PAD_TOKEN)
 encoder_ce = torch.nn.CrossEntropyLoss(ignore_index=PAD_TOKEN)
 decoder_ce = torch.nn.CrossEntropyLoss(ignore_index=PAD_TOKEN)
 nano_optim = torch.optim.AdamW(NANOSOCRATES.parameters())
 encoder_only_optim = torch.optim.AdamW(ENCODER_ONLY.parameters())
 decoder_only_optim = torch.optim.AdamW(DECODER_ONLY.parameters())
 nano_scheduler = Transformer.WarmupLR(nano_optim, WARMUP_EPOCHS, EMBEDDED_SIZE)
 encoder_only_scheduler = Transformer.WarmupLR(
    encoder_only_optim, WARMUP_EPOCHS, EMBEDDED_SIZE
 )
 decoder_only_scheduler = Transformer.WarmupLR(
    decoder_only_optim, WARMUP_EPOCHS, EMBEDDED_SIZE
 )
 current_epoch = CURRENT_EPOCH
 patience = 0
 average_loss_validation = {
    "txt": float("inf"),
    "encoder_only": float("inf"),
    "decoder_only": float("inf"),
 }
 while current_epoch < MAX_EPOCHS:
    NANOSOCRATES.train()
    ENCODER_ONLY.train()
    DECODER_ONLY.train()
    text_batch_losses = []
    encoder_batch_losses = []
    decoder_batch_losses = []
    batch_counter = 0
    print(f"EPOCH {current_epoch} STARTING")
    for batch in TRAIN_BATCHER.batch(MINI_BATCH_SIZE):
        batch_counter += 1
        src_x, tgt_y, pad_x, pad_y, tasktype = batch
        enc_x = torch.tensor(src_x)
        ACTUAL_BATCH_SIZE, _ = enc_x.shape
        enc_x_pad = torch.tensor(pad_x, dtype=torch.bool)
        dec_x = Transformer.get_decoder_input(
            ACTUAL_BATCH_SIZE, SOS_TOKEN, PAD_TOKEN, SENTENCE_LENGTH
        )
        dec_x_pad = dec_x.eq(PAD_TOKEN)
        tgt = torch.tensor(tgt_y)
        tgt_pad = torch.tensor(pad_y, dtype=torch.bool)
        print(f"\tBATCH {batch_counter} Starting")
        # Task 1 and Task 2
        if tasktype == Batch.TaskType.RDF2TXT or tasktype == Batch.TaskType.TEXT2RDF:
            print(f"\tExecuting TASK 1 or 2 - BATCH {batch_counter}")
            BATCH_LOSS = []
            for token_idx in range(0, SENTENCE_LENGTH):
                nano_optim.zero_grad()
                pred_logits = NANOSOCRATES((enc_x, enc_x_pad, dec_x, dec_x_pad))
                pred_logits = pred_logits[:, token_idx, :]
                loss: torch.Tensor = nano_cross_entropy(pred_logits, tgt[:, token_idx])
                loss.backward()
                nano_optim.step()
                BATCH_LOSS.append(loss.item())
                if token_idx < SENTENCE_LENGTH - 1:
                    dec_x[:, token_idx + 1] = tgt[:, token_idx]
            MIN_BATCH_LOSS = min(BATCH_LOSS)
            MAX_BATCH_LOSS = max(BATCH_LOSS)
            AVG_BATCH_LOSS = sum(BATCH_LOSS) / MINI_BATCH_SIZE
            text_batch_losses.append([MIN_BATCH_LOSS, AVG_BATCH_LOSS, MAX_BATCH_LOSS])
            continue
        # Pretrain first
        if current_epoch < PRETRAIN_EPOCHS:
            continue
        # Task 3
        if tasktype == Batch.TaskType.MASKING:
            print(f"\tExecuting TASK 3 - BATCH {batch_counter}")
            encoder_only_optim.zero_grad()
            pred_logits = ENCODER_ONLY((enc_x, enc_x_pad))
            pred_logits = pred_logits.permute(0, 2, 1)
            print(torch.max(tgt))
            loss: torch.Tensor = encoder_ce(pred_logits, tgt)
            loss.backward()
            encoder_only_optim.step()
            encoder_batch_losses.append(loss.item())
            continue
        # Task 4
        if tasktype == Batch.TaskType.COMPLETATION:
            print(f"\tExecuting TASK 4 - BATCH {batch_counter}")
            BATCH_LOSS = []
            for token_idx in range(0, SENTENCE_LENGTH):
                decoder_only_optim.zero_grad()
                pred_logits = DECODER_ONLY((enc_x, enc_x_pad))
                pred_logits = pred_logits[:, token_idx, :]
                loss: torch.Tensor = decoder_ce(pred_logits, tgt[:, token_idx])
                loss.backward()
                decoder_only_optim.step()
                BATCH_LOSS.append(loss.item())
                if token_idx < SENTENCE_LENGTH - 1:
                    dec_x[:, token_idx + 1] = tgt[:, token_idx]
            MIN_BATCH_LOSS = min(BATCH_LOSS)
            MAX_BATCH_LOSS = max(BATCH_LOSS)
            AVG_BATCH_LOSS = sum(BATCH_LOSS) / MINI_BATCH_SIZE
            decoder_batch_losses.append(
                [MIN_BATCH_LOSS, AVG_BATCH_LOSS, MAX_BATCH_LOSS]
            )
            continue
    nano_scheduler.step()
    encoder_only_scheduler.step()
    decoder_only_scheduler.step()
    current_epoch += 1
    if current_epoch % VALIDATION_STEPS == 0:
        NANOSOCRATES.eval()
        ENCODER_ONLY.eval()
        DECODER_ONLY.eval()
        txt_avg_batch_losses = []
        enc_avg_batch_losses = []
        dec_avg_batch_losses = []
        for batch in VALIDATION_BATCHER.batch(MINI_BATCH_SIZE):
            src_x, tgt_y, pad_x, pad_y, tasktype = batch
            enc_x = torch.tensor(src_x)
            ACTUAL_BATCH_SIZE, _, _ = enc_x.shape
            enc_x_pad = torch.tensor(pad_x, dtype=torch.bool)
            dec_x = Transformer.get_decoder_input(
                ACTUAL_BATCH_SIZE, SOS_TOKEN, PAD_TOKEN, SENTENCE_LENGTH
            )
            dec_x_pad = dec_x.eq(PAD_TOKEN)
            tgt = torch.tensor(tgt_y)
            tgt_pad = torch.tensor(pad_y, dtype=torch.bool)
            # Task 1 and Task 2
            if (
                tasktype == Batch.TaskType.RDF2TXT
                or tasktype == Batch.TaskType.TEXT2RDF
            ):
                BATCH_LOSS = []
                for token_idx in range(0, SENTENCE_LENGTH):
                    pred_logits = NANOSOCRATES((enc_x, enc_x_pad, dec_x, dec_x_pad))
                    pred_logits = pred_logits[:, token_idx, :]
                    loss: torch.Tensor = nano_cross_entropy(pred_logits, tgt[:, token_idx])
                    BATCH_LOSS.append(loss.item())
                    if token_idx < SENTENCE_LENGTH - 1:
                        dec_x[:, token_idx + 1] = tgt[:, token_idx]
                AVG_BATCH_LOSS = sum(BATCH_LOSS) / MINI_BATCH_SIZE
                txt_avg_batch_losses.append(AVG_BATCH_LOSS)
                continue
            # Pretrain first
            if current_epoch < PRETRAIN_EPOCHS:
                continue
            # Task 3
            if tasktype == Batch.TaskType.MASKING:
                pred_logits = ENCODER_ONLY((enc_x, enc_x_pad))
                pred_logits = pred_logits.permute(0, 2, 1)
                loss: torch.Tensor = encoder_ce(pred_logits, tgt)
                enc_avg_batch_losses.append(loss.item())
                continue
            # Task 4
            if tasktype == Batch.TaskType.COMPLETATION:
                BATCH_LOSS = []
                for token_idx in range(0, SENTENCE_LENGTH):
                    pred_logits = DECODER_ONLY((enc_x, enc_x_pad))
                    pred_logits = pred_logits[:, token_idx, :]
                    loss: torch.Tensor = decoder_ce(pred_logits, tgt[:, token_idx])
                    BATCH_LOSS.append(loss.item())
                    if token_idx < SENTENCE_LENGTH - 1:
                        dec_x[:, token_idx + 1] = tgt[:, token_idx]
                AVG_BATCH_LOSS = sum(BATCH_LOSS) / MINI_BATCH_SIZE
                dec_avg_batch_losses.append(AVG_BATCH_LOSS)
                continue
        txt_avg_loss = sum(txt_avg_batch_losses) / len(txt_avg_batch_losses)
        enc_avg_loss = float("inf")
        dec_avg_loss = float("inf")
        if current_epoch >= PRETRAIN_EPOCHS:
            enc_avg_loss = sum(enc_avg_batch_losses) / len(enc_avg_batch_losses)
            dec_avg_loss = sum(dec_avg_batch_losses) / len(dec_avg_batch_losses)
        if current_epoch < PRETRAIN_EPOCHS:
            if txt_avg_loss < average_loss_validation["txt"]:
                average_loss_validation["txt"] = txt_avg_loss
            else:
                patience += 1
        else:
            counter = 0
            if txt_avg_loss > average_loss_validation["txt"]:
                counter += 1
            if txt_avg_loss > average_loss_validation["encoder_only"]:
                counter += 1
            if txt_avg_loss > average_loss_validation["decoder_only"]:
                counter += 1
            if counter > 1:
                patience += 1
        txt_min_train_losses = [row[0] for row in text_batch_losses]
        txt_avg_train_losses = [row[1] for row in text_batch_losses]
        txt_max_train_losses = [row[2] for row in text_batch_losses]
        txt_min_loss = min(txt_min_train_losses)
        txt_avg_min_loss = sum(txt_min_train_losses) / len(txt_min_train_losses)
        txt_max_loss = max(txt_max_train_losses)
        txt_avg_max_loss = sum(txt_max_train_losses) / len(txt_max_train_losses)
        txt_avg_loss = sum(txt_avg_train_losses) / len(txt_avg_train_losses)
        enc_avg_train_loss = float("inf")
        dec_min_loss = float("inf")
        dec_avg_min_loss = float("inf")
        dec_max_loss = float("inf")
        dec_avg_max_loss = float("inf")
        dec_avg_loss = float("inf")
        if current_epoch >= PRETRAIN_EPOCHS:
            enc_avg_train_loss = sum(encoder_batch_losses) / len(encoder_batch_losses)
            dec_min_train_losses = [row[0] for row in decoder_batch_losses]
            dec_avg_train_losses = [row[1] for row in decoder_batch_losses]
            dec_max_train_losses = [row[2] for row in decoder_batch_losses]
            dec_min_loss = min(dec_min_train_losses)
            dec_avg_min_loss = sum(dec_min_train_losses) / len(dec_min_train_losses)
            dec_max_loss = max(dec_max_train_losses)
            dec_avg_max_loss = sum(dec_max_train_losses) / len(dec_max_train_losses)
            dec_avg_loss = sum(dec_avg_train_losses) / len(dec_avg_train_losses)
        SEPARATOR = "================================================================================================================"
        DEBUG_TEXT = "".join(
            [
                f"{SEPARATOR}\n",
                f"EPOCH {current_epoch}\n",
                f"{SEPARATOR}\n",
                f"Train Losses:\n",
                f"\tMin Losses:\n",
                f"\t\tmin_txt: {txt_min_loss} - avg_txt: {txt_avg_min_loss}\n",
                f"\t\tmin_dec: {dec_min_loss} - avg_dec: {dec_avg_min_loss}\n",
                f"\tMax Losses:\n",
                f"\t\tmax_txt: {txt_max_loss} - avg_txt: {txt_avg_max_loss}\n",
                f"\t\tmax_dec: {dec_min_loss} - avg_dec: {dec_avg_max_loss}\n",
                f"\tAvg Losses:\n",
                f"\t\tavg_txt: {txt_avg_loss} - avg_enc: {enc_avg_loss} - avg_dec: {dec_avg_loss}\n",
                f"{SEPARATOR}\n",
                f"Validation Losses:\n",
                f"\ttxt_loss: {txt_avg_loss} - masking_loss: {enc_avg_loss} - prediction: {dec_avg_loss}\n",
                f"{SEPARATOR}\n",
            ]
        )
        print(DEBUG_TEXT)
    # Warn about patience
    if patience == PATIENCE:
        print("Model is likely overfitting, so let's stop here")
    # SAVE MODEL
    if current_epoch % CHECKPOINT_STEPS == 0 or patience == PATIENCE:
        print(f"Saving model at {CHECKPOINT_PATH.as_posix()}")
        torch.save(NANOSOCRATES.state_dict(), CHECKPOINT_PATH)
--- a/Playgrounds/prova.py
+++ b/Playgrounds/prova.py
@@ -0,0 +1,177 @@
 import random
 import time
 import torch
 import pandas as pd
 from pathlib import Path
 import Project_Model.Libs.Embedder as Embedder
 import Project_Model.Libs.BPE as BPE
 import Project_Model.Libs.Transformer as Transformer
 import Project_Model.Libs.TorchShims as torch_shims
 # set a fixed seed
 torch.manual_seed(0)
 random.seed(0)
 DEVICE = torch_shims.get_default_device()
 torch.set_default_device(DEVICE)
 # set a default device
 # BPE Init
 VOCABULARY_PATH = Path("Assets/Model/toy_10/toy_dictionary.json")
 SPECIAL_VOC = BPE.default_special_tokens()
 VOCABULARY = BPE.load_nanos_vocabulary(VOCABULARY_PATH)
 TOKENANO = BPE.TokeNanoCore(VOCABULARY, SPECIAL_VOC)
 # Constants
 TOKEN_SPACE_SIZE = TOKENANO.vocabulary_size + 1
 EMBEDDED_SIZE = 256
 FEED_FORWARD_MULTIPLIER = 4
 ATTENTION_HEADS = 8
 SENTENCE_LENGTH = 256
 NUMBER_OF_BLOCKS = 4
 MAX_EPOCHS = int(1e3)
 PAD_TOKEN = TOKENANO.encode("<PAD>")[0]
 END_TOKEN = TOKENANO.encode("<END>")[0]
 # Load CSV
 TOY_DATASET_PATH = Path("Assets/Dataset/1-hop/toy/rdf_text.csv")
 TOY_DATASET = pd.read_csv(TOY_DATASET_PATH)
 TOY_BATCH_INPUT_LIST: list[list[int]] = []
 TOY_BATCH_PADDING_LIST: list[list[bool]] = []
 TOY_BATCH_TARGET_LIST: list[list[int]] = []
 TOY_BATCH_DECODER_DEFAULT: list[list[int]] = []
 for index, row in TOY_DATASET.iterrows():
    RDFs: str = row["RDFs"]
    Abstract: str = row["Abstract"]
    input_tokens = TOKENANO.encode(RDFs)
    output_tokens = TOKENANO.encode(Abstract)[1:]
    decoder_default_tokens = TOKENANO.encode("<SOS>")
    input_tokens, padding = Transformer.normalize_sequence(
        input_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN
    )
    output_tokens, _ = Transformer.normalize_sequence(
        output_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN
    )
    decoder_default_tokens, _ = Transformer.normalize_sequence(
        decoder_default_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN, False
    )
    TOY_BATCH_INPUT_LIST.append(input_tokens)
    TOY_BATCH_PADDING_LIST.append(padding)
    TOY_BATCH_TARGET_LIST.append(output_tokens)
    TOY_BATCH_DECODER_DEFAULT.append(decoder_default_tokens)
    output_tokens = TOKENANO.encode(RDFs)
    input_tokens = TOKENANO.encode(Abstract)[1:]
    decoder_default_tokens = TOKENANO.encode("<SOS>")
    input_tokens, padding = Transformer.normalize_sequence(
        input_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN
    )
    output_tokens, _ = Transformer.normalize_sequence(
        output_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN
    )
    decoder_default_tokens, _ = Transformer.normalize_sequence(
        decoder_default_tokens, SENTENCE_LENGTH, PAD_TOKEN, END_TOKEN, False
    )
    TOY_BATCH_INPUT_LIST.append(input_tokens)
    TOY_BATCH_PADDING_LIST.append(padding)
    TOY_BATCH_TARGET_LIST.append(output_tokens)
    TOY_BATCH_DECODER_DEFAULT.append(decoder_default_tokens)
 # Training loop
 LOSS_HISTORY = []
 NANOSOCRATES = Transformer.TrainingModel(
    TOKEN_SPACE_SIZE,
    EMBEDDED_SIZE,
    FEED_FORWARD_MULTIPLIER,
    ATTENTION_HEADS,
    NUMBER_OF_BLOCKS,
 )
 cross_entropy = torch.nn.CrossEntropyLoss(ignore_index=PAD_TOKEN)
 optimizer = torch.optim.AdamW(NANOSOCRATES.parameters())
 scheduler = Transformer.WarmupLR(optimizer, 4000, EMBEDDED_SIZE)
 last_loss = 0
 current_epoch = 0
 while current_epoch < MAX_EPOCHS:
    optimizer.zero_grad()
    encoder_list = torch.tensor(TOY_BATCH_INPUT_LIST[:])
    decoder_list = torch.tensor(TOY_BATCH_DECODER_DEFAULT[:])
    src_padding = torch.tensor(TOY_BATCH_PADDING_LIST[:], dtype=torch.bool)
    # Transform target into logits
    target_logits = torch.tensor(TOY_BATCH_TARGET_LIST[:])
    last_loss = 0
    last_prediction: torch.Tensor
    LOSS_HISTORY = []
    start = time.time_ns()
    for i in range(0, SENTENCE_LENGTH):
        optimizer.zero_grad()
        tgt_padding = decoder_list.eq(PAD_TOKEN)
        logits: torch.Tensor = NANOSOCRATES(
            (encoder_list, src_padding, decoder_list, tgt_padding)
        )
        prob = torch.softmax(logits, 2)
        most_probable_tokens = torch.argmax(prob, 2)
        last_prediction = most_probable_tokens
        logits = logits[:, i, :]
        # logits = logits.permute(0, 2, 1)
        loss: torch.Tensor = cross_entropy(logits, target_logits[:, i])
        LOSS_HISTORY.append(loss.item())
        # loss : torch.Tensor = cross_entropy(logits, target_logits[:, 0:i])
        # loss : torch.Tensor = cross_entropy(logits, target_logits)
        last_loss = loss
        loss.backward()
        optimizer.step()
        scheduler.step()
        if i < SENTENCE_LENGTH - 1:
            decoder_list[:, i + 1] = target_logits[:, i]
    current_epoch += 1
    end = time.time_ns()
    if current_epoch % 1 == 0:
        MIN_LOSS = min(LOSS_HISTORY)
        MAX_LOSS = max(LOSS_HISTORY)
        AVERAGE_LOSS = sum(LOSS_HISTORY)/len(LOSS_HISTORY)
        print(f"EPOCH {current_epoch}\n\tTime: {(end-start)/1E9}s\n\tLoss: {last_loss}")
        print(f"\tMin Loss: {MIN_LOSS}\tAvg Loss: {AVERAGE_LOSS}\tMax Loss: {MAX_LOSS}\n")
        # for encoded_sentence, expected_sentence in zip(
        #     Transformer.tensor2token(last_prediction[:, :], END_TOKEN),  # type: ignore
        #     Transformer.tensor2token(target_logits[:, :], END_TOKEN),
        # ):
        #     decoded_sentence = TOKENANO.decode(encoded_sentence)
        #     decoded_target = TOKENANO.decode(expected_sentence)
        #     print(
        #         f"\tACTUAL:\n\t\t{decoded_sentence}\n\tEXPECTED:\n\t\t{decoded_target}\n"
        #     )
--- a/Project_Model/Libs/BPE/Classes/NanoSocratesBPE.py
+++ b/Project_Model/Libs/BPE/Classes/NanoSocratesBPE.py
@@ -189,7 +189,7 @@ class NanoSocratesBPE(Encoder):
            token_stack.appendleft(right_token)
            token_stack.appendleft(left_token)
-        return UTF_8_STRING_ARR.decode("utf-8")
+        return UTF_8_STRING_ARR.decode("utf-8", errors="ignore")
    def __token_decode(self, token_id: int) -> tuple[int, int]:
--- a/Project_Model/Libs/BPE/Classes/TokeNanoCore.py
+++ b/Project_Model/Libs/BPE/Classes/TokeNanoCore.py
@@ -31,7 +31,7 @@ class TokeNanoCore:
    def vocabulary_size(self):
        BPE_VOC_SIZE = self.__bpe_encoder.vocabulary_size
        SPECIAL_VOC_SIZE = self.__special_encoder.vocabulary_size
-        return BPE_VOC_SIZE + SPECIAL_VOC_SIZE
+        return BPE_VOC_SIZE + SPECIAL_VOC_SIZE + 1
    def encode(self, corpus: str) -> list[int]:
        output: list[int] = []
--- a/Project_Model/Libs/Batch/Classes/Batcher.py
+++ b/Project_Model/Libs/Batch/Classes/Batcher.py
@@ -1,104 +1,243 @@
 import random
-from typing import Generator
+import sys
 from typing import Any, Generator
 import pandas as pd
-
+from pathlib import Path
 from ..Enums import TaskType
 import Project_Model.Libs.BPE as BPE
-from Scripts.Libs.CleaningPipeline.special_token import SpecialToken
+
-from Project_Model.Libs.Transformer.Classes.SpannedMasker import SpannedMasker
+# from Scripts.Libs.CleaningPipeline.special_token import SpecialToken
-from TokenCompletation import TokenCompletationTransformer
+from Project_Model.Libs.Transformer import (
-from Project_Model.Libs.BPE.Enums.SpecialToken import SpecialToken
+    SpannedMasker,
    truncate_rdf_list,
    normalize_sequence,
 )
 from Project_Model.Libs.BPE import SpecialToken
 class Batcher:
-    def __init__(self, dataset_path: str, batch_size:int, tokenizer: BPE.TokeNanoCore, masker: SpannedMasker) -> None:
+    def __init__(
        self,
        dataset_path: Path,
        max_length: int,
        tokenizer: BPE.TokeNanoCore,
        masker: SpannedMasker,
        seed: int = 0,
        debug = False
    ) -> None:
        # ABSTRACT, TRIPLE
        # tasks:
        #   rdf2text: X: TRIPLE, Y: ABSTRACT
        #   text2rdf: X: ABSTRACT, X:TRIPLE
        #   masking ( call masker): X: incomplete_triple Y: complete_triple (as exam)
        #   completation: X: TRIPLE SUBSET, Y: related TRIPLE SUBSET
        # it will truncate
        # it will instantiate spanmaskter and truncator
        self._dataset_path = dataset_path
        self._batch_size = batch_size
        self._tokenizer = tokenizer
        self._masker = masker
        self.__max_length = max_length
        self._seed = seed
        # self._token_completation = TokenCompletationTransformer(sotl,eos)
        self._completation_task_token_truncator = truncate_rdf_list
        self.__debug = debug
-        sotl = self._tokenizer.encode(SpecialToken.START_TRIPLE_LIST.value)
+    def batch(self, batch_size) -> Generator[
-        eos = self._tokenizer.encode(SpecialToken.END_OF_SEQUENCE.value)
+        tuple[
-        self._token_completation = TokenCompletationTransformer(sotl,eos)
+            list[list[int]],
            list[list[int]],
            list[list[int]],
            list[list[int]],
            TaskType
        ],
        Any,
        Any,
    ]:
        """
        Yields: X,Y,padding_X
        """
        RNG = random.Random(self._seed)
        self._masker.reseed(self._seed)
-
+        for batch in pd.read_csv(self._dataset_path, chunksize=batch_size):
    def get_batch(self)-> Generator[pd.DataFrame]:
        for batch in pd.read_csv(self._dataset_path, chunksize= int(self._batch_size/4)): #now we support 3 task
            tokenized_batch = pd.DataFrame()
-            tokenized_batch[["Abstract","RDFs"]] = (
+            # encode
-                batch[["Abstract","RDFs"]]
+            tokenized_batch[["Abstract", "RDFs"]] = batch[["Abstract", "RDFs"]].map(
-                .map(lambda t: self._tokenizer.encode(t))
+                lambda t: self._tokenizer.encode(t)
            )
-            rdf2txt_batch = self.__rdf2txt_transformation(tokenized_batch)
+            X, Y, padding_X, padding_Y = self.__rdf2txt_transformation(tokenized_batch)
-            txt2rdf_batch = self.__txt2rdf_transformation(tokenized_batch)
+            yield X, Y, padding_X, padding_Y, TaskType.RDF2TXT
-            mask_batch = self.__masking_trasformation(tokenized_batch)
+            (
-            completation_batch = self.__token_completation_task(tokenized_batch)
+                X,
                Y,
                padding_X,
                padding_Y,
            ) = self.__txt2rdf_transformation(tokenized_batch)
            yield X, Y, padding_X, padding_Y, TaskType.TEXT2RDF
            (
                X,
                Y,
                padding_X,
                padding_Y,
            ) = self.__masking_trasformation(tokenized_batch)
            yield X, Y, padding_X, padding_Y, TaskType.MASKING
            (
                X,
                Y,
                padding_X,
                padding_Y,
            ) = self.__token_completation_task(
                tokenized_batch, RNG.randint(0, sys.maxsize)
            )
            yield X, Y, padding_X, padding_Y, TaskType.COMPLETATION
-            output = pd.concat([rdf2txt_batch,txt2rdf_batch,mask_batch,completation_batch],ignore_index=True)
+            # output = pd.concat([rdf2txt_batch,txt2rdf_batch,completation_batch],ignore_index=True)
-            output = output.sample(frac=1).reset_index(drop=True)
+            # output = output.sample(frac=1).reset_index(drop=True)
-            yield output
+            # self.decode_debug(output)
            # yield output
-
+    def __random_subset_rdfs(self, batch: pd.DataFrame, seed=0):
    def __random_subset_rdfs(self, batch: pd.DataFrame, seed = 0):
        # WIP
        rng = random.Random(seed)
        def to_list(x):
            return x.split(SpecialToken.START_TRIPLE.value)[1:]
-        batch["RDFs"] = batch["RDFs"].map(
+        batch["RDFs"] = batch["RDFs"].map(to_list)
-            to_list
+
    def decode_debug(self, batch: pd.DataFrame):
        decoded = pd.DataFrame()
        decoded[["X", "Y"]] = batch[["X", "Y"]].map(lambda t: self._tokenizer.decode(t))
        print(decoded)
    def __normalization(
        self, X: list[list[int]], Y: list[list[int]]
    ) -> tuple[list[list[int]], list[list[int]], list[list[int]], list[list[int]]]:
        pad_token = self._tokenizer.encode(SpecialToken.PAD.value)[0]
        end_token = self._tokenizer.encode(SpecialToken.END_OF_SEQUENCE.value)[0]
        out_X = []
        padding_X = []
        out_Y = []
        padding_Y = []
        for x in X:
            out_x, padding_x = normalize_sequence(
                x, self.__max_length, pad_token, end_token, True
            )
            out_X.append(out_x)
            padding_X.append(padding_x)
        for y in Y:
            out_y, padding_y = normalize_sequence(
                y, self.__max_length, pad_token, end_token, True
            )
            out_Y.append(out_y)
            padding_Y.append(padding_y)
        return out_X, out_Y, padding_X, padding_Y
    def __rdf2txt_transformation(self, batch: pd.DataFrame):
-        batch = batch.rename(columns={"RDFs": "X", "Abstract": "Y"})
+        X: list[list[int]]
-        return batch[["X", "Y"]]
+        task_token = self._tokenizer.encode(SpecialToken.RDF_TO_TEXT.value)
-
+        out = batch.rename(columns={"RDFs": "X", "Abstract": "Y"})[["X", "Y"]]
        out["X"] = [task_token + x for x in out["X"]]
        return self.__normalization(out["X"].to_list(), out["Y"].to_list())
    def __txt2rdf_transformation(self, batch: pd.DataFrame):
-        batch = batch.rename(columns={ "Abstract": "X","RDFs": "Y"})
+        task_token = self._tokenizer.encode(SpecialToken.TEXT_TO_RDF.value)
-        return batch[["X", "Y"]]
+        out = batch.rename(columns={"Abstract": "X", "RDFs": "Y"})[["X", "Y"]]
        out["X"] = [task_token + x for x in out["X"]]
        return self.__normalization(out["X"].to_list(), out["Y"].to_list())
    def __masking_trasformation(self, batch: pd.DataFrame):
-        # mask_sequence: List[int] -> Tuple[List[int], List[int]]
+        X = []
-        xy_tuples = batch["RDFs"].apply(self._masker.mask_sequence)  # Series of (X, Y)
+        Y = []
        for rdf in batch["RDFs"]:
            x, y = self._masker.mask_sequence(rdf[:self.__max_length])
            X.append(x)
            Y.append(y)
        return self.__normalization(X, Y)
-        output = batch.copy()
+    def __token_completation_task(self, batch: pd.DataFrame, minibatch_seed: int):
-        # Expand into two columns preserving the original index
+        continue_triple_token = self._tokenizer.encode(SpecialToken.CONTINUE_RDF.value)[
-        output[["X", "Y"]] = pd.DataFrame(xy_tuples.tolist(), index=batch.index)
+            0
-        return output[["X", "Y"]] 
+        ]
        eot = self._tokenizer.encode(SpecialToken.END_TRIPLE.value)[0]
        X = []
        Y = []
        for rdf in batch["RDFs"]:
            # here first truncate to max_lenght
            rdf = rdf[: self.__max_length] # truncator that uses "eot" so no problem
            x, y = self._completation_task_token_truncator(
                rdf, 0.5, continue_triple_token, eot, minibatch_seed
            )
            X.append(x)
            Y.append(y)
        return self.__token_cmpletation_task_special_normalization(X, Y)
    def __token_cmpletation_task_special_normalization(self, X: list[list[int]], Y: list[list[int]]
    ) -> tuple[list[list[int]], list[list[int]], list[list[int]], list[list[int]]]:
-    def __token_completation_task(self, batch: pd.DataFrame):
+        def continue_rdf_padding(sequence: list[int], pad_token: int):
-        xy_tuples = batch["RDFs"].apply(self._token_completation.get_completation_tuple)
+            for i, x in enumerate(sequence):
-        output = batch.copy()
+                if x == pad_token:
-        output[["X", "Y"]] = pd.DataFrame(xy_tuples.tolist(), index=batch.index)
+                    i = i+1 # continueRDF will be excluded by the mask
-        return output[["X", "Y"]] 
+                    # fill the tail with True and stop
                    return [False] * i + [True] * (len(sequence) - i)
            return [False] * len(sequence)  # no pad token found
        pad_token = self._tokenizer.encode(SpecialToken.PAD.value)[0]
        end_token = self._tokenizer.encode(SpecialToken.END_OF_SEQUENCE.value)[0]
        continue_rdf = self._tokenizer.encode(SpecialToken.CONTINUE_RDF.value)[0]
        out_X = []
        padding_X = []
        out_Y = []
        padding_Y = []
        for x in X:
            out_x, _ = normalize_sequence(
                x, self.__max_length, pad_token, end_token, True
            )
            out_X.append(out_x)
            # padding_X.append(padding_x)
            special_padding = continue_rdf_padding(out_x,continue_rdf)
            padding_X.append(special_padding)
-"""
+        for y in Y:
-DATASET_PATH = "Assets/Dataset/Tmp/rdf_text.csv"
+            out_y, padding_y = normalize_sequence(
-VOCABULARY_path = "Assets/Dataset/Tmp/trimmed.json"
+                y, self.__max_length, pad_token, end_token, True
            )
            out_Y.append(out_y)
            # special padding
            # special_padding = continue_rdf_padding(out_y,continue_rdf)
            # padding_Y.append(special_padding)
            padding_Y.append(padding_y)
-from pathlib import Path
+        return out_X, out_Y, padding_X, padding_Y
 VOCABULARY = BPE.load_nanos_vocabulary(Path(VOCABULARY_path))
 SPECIAL_LIST = BPE.default_special_tokens()
 TOKENANO = BPE.TokeNanoCore(VOCABULARY, SPECIAL_LIST)
 SPECIAL_TOKENS: set[int] = set(TOKENANO.encode("".join(SPECIAL_LIST)))
-MASKER = SpannedMasker(TOKENANO.vocabulary_size,SPECIAL_TOKENS)
+if __name__ == "__main__":
-prova = "<ABS>Cactus Flower is a 1969 American screwball comedy film directed by Gene Saks, and starring Walter Matthau, Ingrid Bergman and Goldie Hawn, who won an Academy Award for her performance.The screenplay was adapted by I. A. L. Diamond from the 1965 Broadway play of the same title written by Abe Burrows, which, in turn, is based on the French play Fleur de cactus by Pierre Barillet and Jean-Pierre Gredy. Cactus Flower was the ninth highest-grossing film of 1969."
+    DATASET_PATH = Path("Assets/Dataset/Tmp/rdf_text.csv")
-print(TOKENANO.encode(prova))
+    VOCABULARY_path = "Assets/Dataset/Tmp/trimmed.json"
-batcher = Batcher(DATASET_PATH,8,TOKENANO,MASKER)
+
-for batch in batcher.get_batch():
+    from pathlib import Path
    VOCABULARY = BPE.load_nanos_vocabulary(Path(VOCABULARY_path))
    SPECIAL_LIST = BPE.default_special_tokens()
    TOKENANO = BPE.TokeNanoCore(VOCABULARY, SPECIAL_LIST)
    SPECIAL_TOKENS: set[int] = set(TOKENANO.encode("".join(SPECIAL_LIST)))
    MASKER = SpannedMasker(TOKENANO.vocabulary_size, SPECIAL_TOKENS)
    prova = "<ABS>Cactus Flower is a 1969 American screwball comedy film directed by Gene Saks, and starring Walter Matthau, Ingrid Bergman and Goldie Hawn, who won an Academy Award for her performance.The screenplay was adapted by I. A. L. Diamond from the 1965 Broadway play of the same title written by Abe Burrows, which, in turn, is based on the French play Fleur de cactus by Pierre Barillet and Jean-Pierre Gredy. Cactus Flower was the ninth highest-grossing film of 1969."
    print(TOKENANO.encode(prova))
    batcher = Batcher(DATASET_PATH,256, TOKENANO, MASKER)
    for batch in batcher.batch(8):
        print(batch)
 """
--- a/Project_Model/Libs/Batch/Classes/init.py
+++ b/Project_Model/Libs/Batch/Classes/init.py
@@ -0,0 +1,2 @@
 from .Batcher import Batcher
 from .TokenCompletation import TokenCompletationTransformer
--- a/Project_Model/Libs/Batch/Enums/init.py
+++ b/Project_Model/Libs/Batch/Enums/init.py
@@ -0,0 +1,5 @@
 from .TaskType import TaskType
 __all__ = [
    "TaskType"
 ]
--- a/Project_Model/Libs/Batch/init.py
+++ b/Project_Model/Libs/Batch/init.py
@@ -0,0 +1,5 @@
 from .Classes import *
 from .Enums import *
 from . import Classes
 from . import Enums
--- a/Project_Model/Libs/Evaluation/evaluation.py
+++ b/Project_Model/Libs/Evaluation/evaluation.py
@@ -0,0 +1,70 @@
 import evaluate
 from sklearn.metrics import accuracy_score, precision_recall_fscore_support
 class Evaluator():
    def __init__(self) -> None:
        # txt based evaluator
        self.__rouge = evaluate.load("rouge")
        self.__rouge_types = ["rougeLsum", "rouge1", "rouge2"] #rougeLsum will work bad because it expect that each sentence are divided with /n
        self._bleu = evaluate.load("bleu")
        self._meteor = evaluate.load("meteor")
        # token based evaluator
        self.__acc_m = evaluate.load("accuracy")
        self.__prec_m = evaluate.load("precision")
        self.__rec_m  = evaluate.load("recall")
        self.__f1_m   = evaluate.load("f1")
    def rdf2txt_rouge_evaluation(self, preds: list[str], refs: list[str]):
        results = self.__rouge.compute(
        predictions=preds, references=refs,
        rouge_types=self.__rouge_types,
        use_stemmer=True, 
        use_aggregator=True #F1
        )
        return {k: float(results[k]) for k in self.__rouge_types}
    def rdf2txt_bleu_evaluation(self, preds: list[str], refs: list[str]) -> float:
        # sacreBLEU via evaluate; expects references as list-of-lists
        # each prediction can be evaluated against a list of references, hence [[ref]]
        results = self._bleu.compute(predictions=preds, references=[[r] for r in refs])
        return float(results["bleu"])   # (native sacreBLEU scale)
    def rdf2txt_meteor_evaluation(self, preds: list[str], refs: list[str]) -> float:
        # as bleu
        res = self._meteor.compute(predictions=preds, references=[[r] for r in refs])
        return float(res["meteor"])
    def __my_accuracy(self,preds: list[list[int]], refs: list[list[int]]):
        # it is done on token sequence not single token
        total = len(preds)
        correct = 0
        for p, r in zip(preds, refs):
            correct += int(p == r)
        return correct / total
    def __accuracy(self, preds, refs):
        return accuracy_score(preds,refs)
    def __clean_batch_by_pad(self, preds: list[list[int]], refs: list[list[int]]):
        output_preds = []
        output_refs = []
        #TODO
        pad_token: int = 7000 # percolate
        for pred, ref in zip(preds,refs):
            try:
                i = ref.index(pad_token)        # first time pad token appears
            except ValueError:
                i = len(ref)
            output_preds.append(pred[:i])
            output_refs.append(ref[:i])
        return output_preds,output_refs
    def __precision_recall(self, preds: list[list[int]], refs: list[list[int]]):
        #TODO
        p, r, f1, _ = precision_recall_fscore_support(
            preds, refs, average="binary", zero_division=0
        ) #### watch later
        return {"precision": float(p), "recall": float(r), "f1": float(f1)}
--- a/Project_Model/Libs/Training/learning_rade_shedulers.py
+++ b/Project_Model/Libs/Training/learning_rade_shedulers.py
@@ -1,41 +0,0 @@
 import numpy as np
 # custom LR from attention is all you need
 class Custom_lr():
    def __init__(self, d_model: int, warmup_step:int) -> None:
        self.__d_model = d_model
        self.__warmup_step = warmup_step
        self.__epoch = 0
    def step(self) -> int:
        self.__epoch += 1
        return (self.__d_model ** -0.5) * min(self.__epoch ** -0.5,
                                   self.__epoch * (self.__warmup_step ** -1.5))
 # OTHER LR
 # Learning rate schedules (matching visualization parameters)
 def step_lr(epoch, lr):
    # StepLR: step_size=20, gamma=0.5 (from visualization)
    return lr * 0.5 if epoch % 20 == 0 and epoch > 0 else lr
 def exp_lr(epoch, lr):
    # ExponentialLR: gamma=0.95 (from visualization)
    return lr * 0.95
 def cosine_lr(epoch, lr):
    # CosineAnnealingLR: lr_min=0.001, lr_max=0.1, max_epochs=100 (from visualization)
    lr_min, lr_max = 0.001, 0.1
    max_epochs = 100
    return lr_min + 0.5 * (lr_max - lr_min) * (1 + np.cos(epoch * np.pi / max_epochs))
 def cyclical_lr(epoch, lr):
    # CyclicalLR: base_lr=0.001, max_lr=0.1, step_size=20 (from visualization)
    base_lr = 0.001
    max_lr = 0.1
    step_size = 20
    cycle = np.floor(1 + epoch / (2 * step_size))
    x = np.abs(epoch / step_size - 2 * cycle + 1)
    return base_lr + (max_lr - base_lr) * max(0, (1 - x))
--- a/Project_Model/Libs/Training/logistic_collector.py
+++ b/Project_Model/Libs/Training/logistic_collector.py
@@ -0,0 +1,43 @@
 import torch
 class LogitsCollector:
    def __init__(self, pad_token: int, end_token: int, tokenizer) -> None:
        self.__pad_token = pad_token                      # used to skip PAD
        self.__end_token = end_token                      # used to stop at END
        self.__tokenizer = tokenizer                      # exposes .decode(list[int]) -> str
        self.__steps: list[torch.Tensor] = []             # list of per-step logits [B,V]
    def reset(self) -> None:
        self.__steps.clear()                              # clear history
    def add(self, logits_step: torch.Tensor) -> None:
        if logits_step.dim() == 3:                        # handle [B,1,V]
            logits_step = logits_step[:, -1, :]           # -> [B,V]
        self.__steps.append(logits_step.detach())         # store raw logits (detached)
    def tokens(self) -> list[list[int]]:
        if not self.__steps:
            return []
        stack = torch.stack(self.__steps, dim=0)          # [T,B,V]
        probs = torch.softmax(stack, dim=-1)              # softmax over vocab -> [T,B,V]
        ids = probs.argmax(dim=-1).transpose(0, 1)        # greedy ids -> [B,T]
        out: list[list[int]] = []
        for row in ids.tolist():
            seq: list[int] = []
            for tok in row:
                # if tok == self.__end_token:               # stop on END
                #   break
                if tok == self.__pad_token:               # skip PAD
                    continue
                seq.append(tok)
            out.append(seq)
        return out
    def print_decoded(self) -> None:
        for i, seq in enumerate(self.tokens()):
            try:
                # text = text + self.__end_token
                text = self.__tokenizer.decode(seq)       # decode tokens to string
            except Exception:
                text = str(seq)                           # fallback to ids
            print(f"[{i}] {text}")                        # simple print
--- a/Project_Model/Libs/Training/loss_saver.py
+++ b/Project_Model/Libs/Training/loss_saver.py
@@ -0,0 +1,20 @@
 import os
 from pathlib import Path
 class Log:
    def __init__(self, path):
        self.path = path
        header = ["epoch","avg_txt","avg_enc","avg_dec","txt_loss","masking_loss","prediction_loss"]
        if Path(path).is_file():
            return
        with open(self.path, "w", encoding="utf-8", newline="") as f:
            f.write(",".join(header) + "\n")
    def write(self, loss: list[float]):
        line = ",".join(str(float(x)) for x in loss) + "\n"
        with open(self.path, "a", encoding="utf-8", newline="") as f:
            f.write(line)
            f.flush()
            os.fsync(f.fileno())  # extra durability per write # suggested against sudden crashes since it will be done
--- a/Project_Model/Libs/Transformer/Classes/DeToken.py
+++ b/Project_Model/Libs/Transformer/Classes/DeToken.py
@@ -14,6 +14,6 @@ class DeToken(torch.nn.Module):
        x = self.__linear(x)
        # 2) Go to logits
-        x = torch.softmax(x, 2)
+        # x = torch.softmax(x, 2)
        return x
--- a/Project_Model/Libs/Transformer/Classes/Decoder.py
+++ b/Project_Model/Libs/Transformer/Classes/Decoder.py
@@ -1,8 +1,9 @@
 from typing import Optional
 import torch
 import torch.nn as nn
 from .FeedForwardNetwork import FeedForwardNetwork
 from .TorchMultiHeadAttention import TorchMultiHeadAttention as MultiHeadAttention
-from ..Utils.attention_mask import get_causal_attention_mask
+from ..Utils.attention_mask import get_causal_attention_mask, get_prefix_causal_mask_from_padding_mask
 # B, L(T), E_D
@@ -15,8 +16,10 @@ class Decoder(nn.Module):
        feed_forward_hidden_layer_dimension: int,
        number_of_attention_heads: int,
    ) -> None:
        self.__attention_heads = number_of_attention_heads
        super().__init__()
        self.__masked_attention = MultiHeadAttention(
            embedding_dimension, number_of_attention_heads, dropout=0.1
        )
@@ -41,43 +44,53 @@ class Decoder(nn.Module):
            torch.Tensor,
            torch.Tensor,
            torch.Tensor,
-            torch.Tensor
+            torch.Tensor,
            torch.Tensor,
            Optional[bool]
        ]
    ):  # -> list[torch.Tensor]:  # k_x = v_x . While x_q = x
        # WARNING: args is needed to have sequential
-        x, k_x, v_x, padding_mask = args
+        if len(args) < 6:
            args = args + (False)
        x, k_x, v_x, src_padding_mask, tgt_padding_mask, decoder_only = args
        # build of attention mask
        # TODO: create a prefix causal mask if needed
        if decoder_only:
            attention_mask = get_prefix_causal_mask_from_padding_mask(x.size(1),src_padding_mask,self.__attention_heads) # the correct is tgt however ...
        else:
            attention_mask = get_causal_attention_mask(x.size(1))
        # 1) Masked Attention
        MASKED_ATTENTION = self.__masked_attention(
-            x, x, x, key_padding_mask=padding_mask, attention_mask=attention_mask
+            x, x, x, key_padding_mask=tgt_padding_mask, attention_mask=attention_mask
        )
        # 2) Dropout
-        # DROPPED_MASKED_ATTENTION = self.__dropout(MASKED_ATTENTION)
+        DROPPED_MASKED_ATTENTION = self.__dropout(MASKED_ATTENTION)
-        # del MASKED_ATTENTION
+        del MASKED_ATTENTION
        # 3) Residual Connection
-        x = x + MASKED_ATTENTION
+        x = x + DROPPED_MASKED_ATTENTION
-        del MASKED_ATTENTION
+        del DROPPED_MASKED_ATTENTION
        # 4) Layer Normalization
        x = self.__layer_norm_1(x)
        if not decoder_only:
            # 5) Encoder–decoder (cross) attention
            CROSS_ATTENTION = self.__cross_attention(
-            x, k_x, v_x, key_padding_mask=padding_mask
+                x, k_x, v_x, key_padding_mask=src_padding_mask
            )
            # 6) Dropout
-        # DROPPED_CROSS_ATTENTION = self.__dropout(CROSS_ATTENTION)
+            DROPPED_CROSS_ATTENTION = self.__dropout(CROSS_ATTENTION)
-        # del CROSS_ATTENTION
+            del CROSS_ATTENTION
            # 7) Residual Connection
-        x = x + CROSS_ATTENTION
+            x = x + DROPPED_CROSS_ATTENTION
-        del CROSS_ATTENTION
+            del DROPPED_CROSS_ATTENTION
            # 8) Layer Normalization
            x = self.__layer_norm_2(x)
@@ -86,17 +99,17 @@ class Decoder(nn.Module):
        FEED_FORWARD = self.__feed_forward_network(x)
        # 10) Dropout
-        # DROPPED_FEED_FORWARD = self.__dropout(FEED_FORWARD)
+        DROPPED_FEED_FORWARD = self.__dropout(FEED_FORWARD)
-        # del FEED_FORWARD
+        del FEED_FORWARD
        # 11) Residual Connection
-        x = x + FEED_FORWARD
+        x = x + DROPPED_FEED_FORWARD
-        del FEED_FORWARD
+        del DROPPED_FEED_FORWARD
        # 12) Layer Normalization
        x = self.__layer_norm_3(x)
-        return (x, k_x, v_x, padding_mask)
+        return (x, k_x, v_x, src_padding_mask, tgt_padding_mask, decoder_only)
 # use eval to disable dropout ecc
--- a/Project_Model/Libs/Transformer/Classes/Encoder.py
+++ b/Project_Model/Libs/Transformer/Classes/Encoder.py
@@ -43,12 +43,12 @@ class Encoder(
        ATTENTION = self.__attention(x, x, x, key_padding_mask=padding_mask)
        # 2) Dropout
-        # DROPPED_ATTENTION = self.__dropout(ATTENTION)
+        DROPPED_ATTENTION = self.__dropout(ATTENTION)
-        # del ATTENTION
+        del ATTENTION
        # 3) Residual Connection
-        x = x + ATTENTION
+        x = x + DROPPED_ATTENTION
-        del ATTENTION
+        del DROPPED_ATTENTION
        # 4) Layer Normalization
        x = self.__layer_norm_1(x)
@@ -57,12 +57,12 @@ class Encoder(
        FEED_FORWARD = self.__feed_forward(x)
        # 6) Dropout
-        # DROPPED_FEED_FORWARD = self.__dropout(FEED_FORWARD)
+        DROPPED_FEED_FORWARD = self.__dropout(FEED_FORWARD)
-        # del FEED_FORWARD
+        del FEED_FORWARD
        # 7) Residual Connection
-        x = x + FEED_FORWARD
+        x = x + DROPPED_FEED_FORWARD
-        del FEED_FORWARD
+        del DROPPED_FEED_FORWARD
        # 8) Layer Normalization
        x = self.__layer_norm_2(x)
--- a/Project_Model/Libs/Transformer/Classes/SpannedMasker.py
+++ b/Project_Model/Libs/Transformer/Classes/SpannedMasker.py
@@ -10,7 +10,7 @@ class SpannedMasker:
        max_vocabulary: int,
        forbidden_tokens: set[int],
        change_token_probability: float = 0.15,
-        average_span: int = 1,
+        average_span: int = 2,
        seed: int = random.randint(0, sys.maxsize),
    ) -> None:
@@ -25,6 +25,11 @@ class SpannedMasker:
        self.__forbidden_tokens = forbidden_tokens
    def reseed(self, seed:int):
        self.__rng = random.Random(seed)
    def mask_sequence(
        self,
        token_sequence: list[int],
--- a/Project_Model/Libs/Transformer/Classes/WarmupLR.py
+++ b/Project_Model/Libs/Transformer/Classes/WarmupLR.py
@@ -0,0 +1,47 @@
 from typing import override
 import torch
 # custom LR from attention is all you need
 class WarmupLR(torch.optim.lr_scheduler.LRScheduler):
    def __init__(
        self,
        optimizer: torch.optim.Optimizer,
        warmup_steps: int,
        embedding_size: int,
        warming_multiplier: float = -1.5,
        decaying_multiplier: float = -0.5,
        multiplicative_factor: float = 1.0,
        last_epoch: int = -1,
    ) -> None:
        self.__warmup_steps = warmup_steps
        self.__embedding_size = embedding_size
        self.__warming_multiplier = warming_multiplier
        self.__decaying_multiplier = decaying_multiplier
        self.__multiplicative_factor = multiplicative_factor
        super().__init__(optimizer, last_epoch)
    def __scale_at(self, step: int) -> float:
        step = max(step, 1)
        return (
            self.__multiplicative_factor
            * (self.__embedding_size**self.__decaying_multiplier)
            * min(
                step**self.__decaying_multiplier,
                step * (self.__warmup_steps**self.__warming_multiplier),
            )
        )
    @override
    def get_lr(self) -> list[float]:
        torch.optim.lr_scheduler._warn_get_lr_called_within_step(self)
        step = max(self.last_epoch, 1)
        scale = self.__scale_at(step)
        return [base_lr * scale for base_lr in self.base_lrs]
    def _get_closed_form_lr(self):
        step = max(self.last_epoch, 1)
        scale = self.__scale_at(step)
        return [base_lr * scale for base_lr in self.base_lrs]
--- a/Project_Model/Libs/Transformer/Classes/init.py
+++ b/Project_Model/Libs/Transformer/Classes/init.py
@@ -5,6 +5,7 @@ from .FeedForwardNetwork import FeedForwardNetwork
 from .TorchMultiHeadAttention import TorchMultiHeadAttention
 from .SpannedMasker import SpannedMasker
 from .DeToken import DeToken
 from .WarmupLR import WarmupLR
 __all__ = [
    "Decoder",
@@ -12,5 +13,6 @@ __all__ = [
    "FeedForwardNetwork",
    "TorchMultiHeadAttention",
    "SpannedMasker",
-    "DeToken"
+    "DeToken",
    "WarmupLR"
 ]
--- a/Project_Model/Libs/Transformer/Models/NanoSocraDecoder.py
+++ b/Project_Model/Libs/Transformer/Models/NanoSocraDecoder.py
@@ -0,0 +1,33 @@
 import torch
 import Project_Model.Libs.Embedder as Embedder
 from ..Classes import DeToken
 class NanoSocraDecoder(torch.nn.Module):
    def __init__(
        self,
        decoder_embedder: Embedder.NanoSocratesEmbedder,
        decoder_layers: torch.nn.Sequential,
        detokener: DeToken
    ) -> None:
        super().__init__()
        self.__decoder_embedder = decoder_embedder
        self.__decoder = decoder_layers
        self.__detokener = detokener
    def forward(self, args: tuple[torch.Tensor,torch.Tensor, torch.Tensor]):
        decoder_embedder_input, prefix_mask, tgt_padding = args
        decoder_tensor = self.__decoder_embedder(decoder_embedder_input)
        decoder_output, _, _, _, _, _ = self.__decoder(
            (decoder_tensor, decoder_tensor, decoder_tensor, prefix_mask, tgt_padding, True)
        )
        logits: torch.Tensor = self.__detokener(decoder_output)
        return logits
--- a/Project_Model/Libs/Transformer/Models/NanoSocratEncoder.py
+++ b/Project_Model/Libs/Transformer/Models/NanoSocratEncoder.py
@@ -0,0 +1,29 @@
 import torch
 import Project_Model.Libs.Embedder as Embedder
 from ..Classes import DeToken
 class NanoSocratEncoder(torch.nn.Module):
    def __init__(
        self,
        encoder_embedder: Embedder.NanoSocratesEmbedder,
        encoder_layers: torch.nn.Sequential,
        detokener: DeToken
    ) -> None:
        super().__init__()
        self.__encoder_embedder = encoder_embedder
        self.__encoder = encoder_layers
        self.__detokener = detokener
    def forward(self,  args: tuple[torch.Tensor, torch.Tensor]):
        encoder_embedder_input, src_padding = args
        encoder_tensor = self.__encoder_embedder(encoder_embedder_input)
        encoder_output, _ = self.__encoder((encoder_tensor, src_padding))
        logits: torch.Tensor = self.__detokener(encoder_output)
        return logits
--- a/Project_Model/Libs/Transformer/Models/NanoSocrates.py
+++ b/Project_Model/Libs/Transformer/Models/NanoSocrates.py
@@ -0,0 +1,219 @@
 import torch
 import Project_Model.Libs.Embedder as Embedder
 from ..Classes import Encoder, Decoder, DeToken
 from ..Utils import get_decoder_input
 from Project_Model.Libs.Batch import TaskType
 class NanoSocratesCore(torch.nn.Module):
    def __init__(
        self,
        vocabulary_size: int,
        sentence_max_length: int,
        sos: int,
        pad: int,
        eos: int,
        continuerdf: int,
        latent_space: int = 256,
        feed_forward_multiplier: int = 4,
        attention_heads: int = 4,
        layer_number: int = 2,
    ) -> None:
        super().__init__()
        self.__sos = sos
        self.__pad = pad
        self.__eos = eos
        self.__continuerdf = continuerdf
        self.__sentence_len = sentence_max_length
        feed_forward_latent_space = latent_space * feed_forward_multiplier
        self.__encoder_embedder = Embedder.NanoSocratesEmbedder(
            vocabulary_size, latent_space
        )
        self.__decoder_embedder = Embedder.NanoSocratesEmbedder(
            vocabulary_size, latent_space
        )
        TMP_ENCODERS = [
            Encoder(latent_space, feed_forward_latent_space, attention_heads)
        ] * layer_number
        TMP_DECODERS = [
            Decoder(latent_space, feed_forward_latent_space, attention_heads)
        ] * layer_number
        self.__encoder = torch.nn.Sequential(*TMP_ENCODERS)
        self.__decoder = torch.nn.Sequential(*TMP_DECODERS)
        self.__detokener = DeToken(latent_space, vocabulary_size)
        self.__encoder_detokener = DeToken(latent_space, vocabulary_size)
    def forward(self, args: tuple[torch.Tensor, torch.Tensor, torch.Tensor, torch.Tensor]):
        encoder_embedder_input, src_padding, decoder_embedder_input, tgt_padding = args
        encoder_tensor = self.__encoder_embedder(encoder_embedder_input)
        decoder_tensor = self.__decoder_embedder(decoder_embedder_input)
        encoder_output, _ = self.__encoder((encoder_tensor, src_padding))
        decoder_output, _, _, _, _, _ = self.__decoder(
            (decoder_tensor, encoder_output, encoder_output, src_padding, tgt_padding, False)
        )
        logits: torch.Tensor = self.__detokener(decoder_output)
        return logits
    def inference(self, input: tuple[torch.Tensor, torch.Tensor], task_type: TaskType) -> torch.Tensor:
        if task_type == TaskType.MASKING:
            return self.__masking(input)
        if task_type == TaskType.COMPLETATION:
            return self.__continue_rdf(input)
        return self.__text_generation(input)
    def __text_generation(self, args: tuple[torch.Tensor, torch.Tensor]) -> torch.Tensor:
        x, padding = args
        encoder_tensor = self.__encoder_embedder(x)
        BATCH: int
        if len(x.shape) > 2:
            BATCH, SEQ_LEN, _ = x.shape
        else:
            _, SEQ_LEN = x.shape
            BATCH = 1
        encoder_output, _ = self.__encoder((encoder_tensor, padding))
        decoder_in = get_decoder_input(BATCH, self.__sos, self.__pad, SEQ_LEN)
        decoder_in_pad_mask = decoder_in.eq(self.__pad)
        continue_generating = True
        token_idx = 0
        while continue_generating:
            decoder_in_x = self.__decoder_embedder(decoder_in)
            decoder_output, _, _, _, _, _ = self.__decoder(
                (decoder_in_x, encoder_output, encoder_output, padding, decoder_in_pad_mask, False)
            )
            logits: torch.Tensor = self.__detokener(decoder_output)
            logits = torch.softmax(logits, 2)
            tokens = torch.argmax(logits, 2)
            if token_idx < self.__sentence_len - 1:
                decoder_in[:,token_idx + 1] = tokens[:,token_idx]
                decoder_in_pad_mask = decoder_in.eq(self.__pad)
            if token_idx == self.__sentence_len - 1:
                continue_generating = False
                continue
            if tokens.shape[0] == 1 and tokens[0,token_idx] == self.__eos:
                continue_generating = False
                continue
            token_idx += 1
        return decoder_in
    def __masking(self, args: tuple[torch.Tensor, torch.Tensor]) -> torch.Tensor:
        x, padding = args
        encoder_tensor = self.__encoder_embedder(x)
        x, _ = self.__encoder((encoder_tensor, padding))
        logits: torch.Tensor = self.__encoder_detokener(x)
        del x
        logits = torch.softmax(logits, 2)
        tokens = torch.argmax(logits, 2)
        return tokens
    def __continue_rdf(self, args: tuple[torch.Tensor, torch.Tensor]) -> torch.Tensor:
        decoder_in, _ = args
        decoder_in_prefix_mask =  decoder_in.eq(self.__pad)
        decoder_in_pad_mask = decoder_in.eq(self.__pad)
        continue_generating = True
        token_idx: int= int((decoder_in[0] == self.__continuerdf).nonzero()[0].item()) + 1
        while continue_generating:
            decoder_x = self.__decoder_embedder(decoder_in)
            decoder_output, _, _, _, _, _ = self.__decoder(
                (decoder_x, decoder_in, decoder_in, decoder_in_prefix_mask, decoder_in_pad_mask, True)
            )
            logits: torch.Tensor = self.__detokener(decoder_output)
            logits = torch.softmax(logits, 2)
            tokens = torch.argmax(logits, 2)
            if token_idx < self.__sentence_len - 1:
                decoder_in[:,token_idx + 1] = tokens[:,token_idx]
                decoder_in_pad_mask = decoder_in.eq(self.__pad)
            if token_idx == self.__sentence_len - 1:
                continue_generating = False
                continue
            if tokens.shape[0] == 1 and tokens[0,token_idx] == self.__eos:
                continue_generating = False
                continue
            token_idx += 1
        return decoder_in
    def take_pieces(self):
        return (
            (self.__encoder_embedder, self.__encoder, self.__encoder_detokener),
            (self.__decoder_embedder, self.__decoder, self.__detokener)
        )
    def load_pieces(
        self,
        encoder_embedder: Embedder.NanoSocratesEmbedder,
        decoder_embedder: Embedder.NanoSocratesEmbedder,
        encoder: torch.nn.Sequential,
        decoder: torch.nn.Sequential,
        encoder_detokener: DeToken,
        decoder_detokener: DeToken
    ):
        self.__encoder_embedder = encoder_embedder
        self.__decoder_embedder = decoder_embedder
        self.__encoder = encoder
        self.__decoder = decoder
        self.__encoder_detokener = encoder_detokener
        self.__detokener = decoder_detokener
--- a/Project_Model/Libs/Transformer/Models/TrainingModel.py
+++ b/Project_Model/Libs/Transformer/Models/TrainingModel.py
@@ -36,20 +36,28 @@ class TrainingModel(torch.nn.Module):
        self.__decoder = torch.nn.Sequential(*TMP_DECODERS)
        self.__detokener = DeToken(latent_space, vocabulary_size)
        self.__encoder_detokener = DeToken(latent_space, vocabulary_size)
-    def forward(self, args: tuple[torch.Tensor, torch.Tensor, torch.Tensor]):
+    def forward(self, args: tuple[torch.Tensor, torch.Tensor, torch.Tensor, torch.Tensor]):
-        encoder_embedder_input, padding_tensor, decoder_embedder_input = args
+        encoder_embedder_input, src_padding, decoder_embedder_input, tgt_padding = args
        encoder_tensor = self.__encoder_embedder(encoder_embedder_input)
        decoder_tensor = self.__decoder_embedder(decoder_embedder_input)
-        encoder_output, _ = self.__encoder((encoder_tensor, padding_tensor))
+        encoder_output, _ = self.__encoder((encoder_tensor, src_padding))
-        decoder_output, _, _, _ = self.__decoder(
+        decoder_output, _, _, _, _, _ = self.__decoder(
-            (decoder_tensor, encoder_tensor, encoder_tensor, None)
+            (decoder_tensor, encoder_output, encoder_output, src_padding, tgt_padding, False)
        )
        logits: torch.Tensor = self.__detokener(decoder_output)
        return logits
    def take_pieces(self):
        return (
            (self.__encoder_embedder, self.__encoder, self.__encoder_detokener),
            (self.__decoder_embedder, self.__decoder, self.__detokener)
        )
--- a/Project_Model/Libs/Transformer/Models/init.py
+++ b/Project_Model/Libs/Transformer/Models/init.py
@@ -1,5 +1,11 @@
 from .TrainingModel import TrainingModel
 from .NanoSocratEncoder import NanoSocratEncoder
 from .NanoSocraDecoder import NanoSocraDecoder
 from .NanoSocrates import NanoSocratesCore
 __all__ = [
-    "TrainingModel"
+    "TrainingModel",
    "NanoSocratEncoder",
    "NanoSocraDecoder",
    "NanoSocratesCore"
 ]
--- a/Project_Model/Libs/Transformer/Utils/init.py
+++ b/Project_Model/Libs/Transformer/Utils/init.py
@@ -3,6 +3,9 @@ from .task_type import TaskType
 from .post_tokenization import truncate_sequence, pad_sequence, normalize_sequence, create_padding_mask
 from .inference_masking import inference_masking
 from .truncate_rdf_list import truncate_rdf_list
 from .decode_out import tensor2token
 from .decoder_input import get_decoder_input
 __all__ = [
    "TaskType",
@@ -13,5 +16,7 @@ __all__ = [
    "create_padding_mask",
    "normalize_sequence",
    "inference_masking",
-    "truncate_rdf_list"
+    "truncate_rdf_list",
    "tensor2token",
    "get_decoder_input"
 ]
--- a/Project_Model/Libs/Transformer/Utils/attention_mask.py
+++ b/Project_Model/Libs/Transformer/Utils/attention_mask.py
@@ -9,3 +9,22 @@ def get_causal_attention_mask_batched(seq_len: int, batch_size: int ) -> torch.T
    base_mask = get_causal_attention_mask(seq_len)
    return base_mask.unsqueeze(0).expand(batch_size, -1, -1)  # add another dimension at the beginning, big as batch_size   
    # the result is that z,x,y where x,y are repeated along z
 def get_causal_attention_mask_with_prefix(seq_len, prefix):
    mask = torch.triu(torch.ones(seq_len, seq_len, dtype=torch.bool), diagonal=1)
    mask[:,:prefix] = False
    return mask
 def get_prefix_causal_mask_from_padding_mask(seq_len:int, prefix_mask, att_heads:int=1):
    expanded_padding_mask = prefix_mask.unsqueeze(-1).repeat(1, 1, seq_len)         # B,T,T
    expanded_padding_mask = expanded_padding_mask.permute(0,2,1)                    # B,T,T
    mask = torch.triu(torch.ones(seq_len, seq_len, dtype=torch.bool), diagonal=1)   #   T,T
    tri_batched = mask.unsqueeze(0)                                                 # 1,T,T will broadcast over B
    prefix_causal_mask = expanded_padding_mask & tri_batched
    prefix_causal_mask = prefix_causal_mask.repeat_interleave(att_heads, dim=0)     # B*H,T,T
    return prefix_causal_mask
 #def get_prefix_causal_mask():
 #    continue_rdf = 
--- a/Project_Model/Libs/Transformer/Utils/decode_out.py
+++ b/Project_Model/Libs/Transformer/Utils/decode_out.py
@@ -0,0 +1,27 @@
 from typing import Generator
 import torch
 def tensor2token(tensor: torch.Tensor, end_token: int) -> Generator[list[int]]:
    if len(tensor.shape) < 1 or len(tensor.shape) > 2:
        raise ValueError("Shape is not correct")
    if len(tensor.shape) == 1:
        token_list: list[int] = tensor.tolist()
        token_list.append(end_token)
        yield token_list
        return
    batch_len: int
    batch_len, _ = tensor.shape
    for i in range(batch_len):
        smaller_tensor = tensor[i, :]
        token_list: list[int] = smaller_tensor.tolist()
        token_list.append(end_token)
        yield token_list
--- a/Project_Model/Libs/Transformer/Utils/decoder_input.py
+++ b/Project_Model/Libs/Transformer/Utils/decoder_input.py
@@ -0,0 +1,14 @@
 import torch
 from ..Utils import normalize_sequence
 # from Project_Model.Libs.Embedder import NanoSocratesEmbedder as Embedder
 def get_decoder_input(batch_size, sos_token,pad_token, seq_len):
    single_decoder_input, _ = normalize_sequence([sos_token],seq_len,pad_token, end_token=0, add_ending=False)
    tensor_decoder_input = torch.tensor(single_decoder_input[:])
    # embedded_decoder_intput = embedder(tensor_decoder_input)
    batch_decoder_input = tensor_decoder_input.unsqueeze(0).repeat(batch_size, 1)
    return batch_decoder_input
--- a/Project_Model/Libs/Transformer/Utils/post_tokenization.py
+++ b/Project_Model/Libs/Transformer/Utils/post_tokenization.py
@@ -1,16 +1,19 @@
 def truncate_sequence(
-    sequence: list[int], truncate_at: int, end_token: int
+    sequence: list[int], truncate_at: int, end_token: int, add_ending: bool
 ) -> list[int]:
    if len(sequence) < truncate_at - 1:
        if add_ending:
            sequence.append(end_token)
        return sequence
    if len(sequence) < truncate_at:
        if add_ending:
            sequence[-1] = end_token
        return sequence
    TRUNCATED_SEQUENCE = sequence[:truncate_at]
    if add_ending:
        TRUNCATED_SEQUENCE[-1] = end_token
    return TRUNCATED_SEQUENCE
@@ -48,8 +51,9 @@ def normalize_sequence(
    max_length: int,
    pad_token: int,
    end_token: int,
    add_ending: bool = True
 ) -> tuple[list[int], list[bool]]:
-    new_sequence = truncate_sequence(sequence, max_length, end_token)
+    new_sequence = truncate_sequence(sequence, max_length, end_token, add_ending)
    new_sequence = pad_sequence(new_sequence, max_length, pad_token)
    PADDING_MASK = create_padding_mask(new_sequence, pad_token)
--- a/Project_Model/Libs/Transformer/Utils/task_type.py
+++ b/Project_Model/Libs/Transformer/Utils/task_type.py
@@ -1,6 +1,7 @@
 from enum import Enum, auto
 class TaskType(Enum):
    TEXT2RDF = auto()
    RDF2TEXT = auto()
    MASK = auto()
    COMPLETATION = auto()
--- a/Project_Model/Libs/Transformer/Utils/truncate_rdf_list.py
+++ b/Project_Model/Libs/Transformer/Utils/truncate_rdf_list.py
@@ -27,7 +27,6 @@ def truncate_rdf_list(
        END_OF_TRIPLES.append(i + 1)
    TRIPLES_TOKENS: list[int] = []
    TARGET_TRIPLES: list[int] = []
    start_of_triple = 0
    exit_loop = False
@@ -56,10 +55,10 @@ def truncate_rdf_list(
        EOT = END_OF_TRIPLES.popleft()
        TRIPLE = sequence[start_of_triple:EOT]
-        TARGET_TRIPLES.extend(TRIPLE)
+        TRIPLES_TOKENS.extend(TRIPLE)
        start_of_triple = EOT
-    return (TRIPLES_TOKENS, TARGET_TRIPLES)
+    return (TRIPLES_TOKENS, TRIPLES_TOKENS)
--- a/Project_Model/Libs/Transformer/init.py
+++ b/Project_Model/Libs/Transformer/init.py
@@ -1,7 +1,9 @@
 from .Classes import *
 from .Enums import *
 from .Utils import *
 from .Models import *
 from . import Classes
 from . import Enums
 from . import Utils
 from . import Models
--- a/Project_Model/Libs/TransformerUtils/ModelType.py
+++ b/Project_Model/Libs/TransformerUtils/ModelType.py
@@ -0,0 +1,6 @@
 from enum import Enum, auto
 class ModelType(Enum):
    ENCODER_ONLY = auto()
    DECODER_ONLY = auto()
--- a/Project_Model/Libs/TransformerUtils/init.py
+++ b/Project_Model/Libs/TransformerUtils/init.py
@@ -0,0 +1,14 @@
 from .model_utils import decompose_nano_socrates, create_standalone_model, train2inference
 from .ModelType import ModelType
 from .decode_batch import decode_batch
 from .metrics import precision, recall, accuracy, f1, meteor, bleu, rouge, average, rdf2txt, txt2rdf, rdf_completion_1, rdf_completion_2, remove_padding, balance_paddings
 __all__ = [
    "ModelType",
    "decompose_nano_socrates",
    "create_standalone_model",
    "decode_batch",
    "train2inference",
    "precision", "recall", "accuracy", "f1", "meteor", "bleu", "rouge", "average",
    "rdf2txt", "txt2rdf", "rdf_completion_1", "rdf_completion_2", "remove_padding", "balance_paddings"
 ]
--- a/Project_Model/Libs/TransformerUtils/decode_batch.py
+++ b/Project_Model/Libs/TransformerUtils/decode_batch.py
@@ -0,0 +1,16 @@
 import torch
 import Project_Model.Libs.BPE as BPE
 def decode_batch(batch: torch.Tensor, tokenizer: BPE.TokeNanoCore ,uknonw_token: int) -> list[str]:
    strings = []
    BATCH, _ = batch.shape
    for i in range(0, BATCH):
        tokens: list[int] = batch.tolist()[i]
        tokens = list(map(lambda x: uknonw_token if x > tokenizer.vocabulary_size else x, tokens))
        strings.append(tokenizer.decode(tokens))
    return strings
--- a/Project_Model/Libs/TransformerUtils/metrics.py
+++ b/Project_Model/Libs/TransformerUtils/metrics.py
@@ -0,0 +1,100 @@
 import evaluate as eval
 BLEU = eval.load("bleu")
 ROUGE = eval.load("rouge")
 METEOR = eval.load("meteor")
 def precision(ref: list[int], pred: list[int]):
    metric = eval.load("precision")
    return metric.compute(predictions=pred, references=ref, average="weighted", zero_division=0)
 def recall(ref: list[int], pred: list[int]):
    metric = eval.load("recall")
    return metric.compute(predictions=pred, references=ref, average="weighted", zero_division=0)
 def accuracy(ref: list[int], pred: list[int]):
    metric = eval.load("accuracy")
    return metric.compute(predictions=pred, references=ref)
 def meteor(ref: list[str], pred: list[str]):
    metric = METEOR
    return metric.compute(predictions=pred, references=ref)
 def bleu(ref: list[str], pred: list[str]):
    metric = BLEU
    return metric.compute(predictions=pred, references=ref)
 def rouge(ref: list[str], pred: list[str]):
    metric = ROUGE
    return metric.compute(predictions=pred, references=ref)
 def f1(precision: float, recall: float):
    divisor = max((precision + recall), 1E-5)
    return (2 * recall * precision) / divisor
 def average(array: list[float]):
    return sum(array) / len(array)
 def rdf2txt(ref: list[str], pred: list[str]):
    b_m = bleu(ref, pred)
    r_m = rouge(ref, pred)
    m_m = meteor(ref, pred)
    return (b_m, r_m, m_m)
 def txt2rdf(ref: list[int], pred: list[int]):
    p_m = precision(ref, pred)
    r_m = recall(ref, pred)
    return (p_m, r_m)
 def rdf_completion_1(ref: list[int], pred: list[int]):
    a_m = accuracy(ref, pred)
    return a_m
 def rdf_completion_2(ref: list[int], pred: list[int]):
    p_m = precision(ref, pred)
    r_m = recall(ref, pred)
    return (p_m, r_m)
 def remove_padding(seq: list[int], pad_token: int, end_token: int):
    clean_seq = list(filter(lambda x: x != pad_token, seq))
    if clean_seq[-1] == end_token:
        return clean_seq
    clean_seq.append(
        end_token
    )
    return clean_seq
 def balance_paddings(seq_1: list[int], seq_2: list[int], pad_token: int):
    SEQ_1_LEN = len(seq_1)
    SEQ_2_LEN = len(seq_2)
    if SEQ_1_LEN > SEQ_2_LEN:
        PAD = [pad_token] * (SEQ_1_LEN - SEQ_2_LEN)
        seq_2.extend(PAD)
    if SEQ_2_LEN > SEQ_1_LEN:
        seq_2 = seq_2[:SEQ_1_LEN]
    return (seq_1, seq_2)
--- a/Project_Model/Libs/TransformerUtils/model_utils.py
+++ b/Project_Model/Libs/TransformerUtils/model_utils.py
@@ -0,0 +1,72 @@
 import torch
 from Project_Model.Libs.Embedder import NanoSocratesEmbedder
 from Project_Model.Libs.Transformer import TrainingModel,NanoSocratesCore,  NanoSocraDecoder, NanoSocratEncoder, DeToken, Encoder, Decoder
 from .ModelType import ModelType
 def decompose_nano_socrates(
    model: TrainingModel | NanoSocratesCore , vocabulary_size: int, embedding_size: int
 ) -> tuple[TrainingModel | NanoSocratesCore, NanoSocratEncoder, NanoSocraDecoder]:
    encoder_pieces, decoder_pieces = model.take_pieces()
    encoder_embedder, encoder, encoder_detokener = encoder_pieces
    decoder_embedder, decoder, decoder_detokener = decoder_pieces
    return (
        model,
        NanoSocratEncoder(encoder_embedder, encoder, encoder_detokener),
        NanoSocraDecoder(decoder_embedder, decoder, decoder_detokener),
    )
 def train2inference(
    train_model: TrainingModel,
    inference_model: NanoSocratesCore
 ) -> NanoSocratesCore:
    encoder_pieces, decoder_pieces = train_model.take_pieces()
    enc_emb, encoder, enc_det = encoder_pieces
    dec_emb, decoder, dec_det = decoder_pieces
    inference_model.load_pieces(
        enc_emb,
        dec_emb,
        encoder,
        decoder,
        enc_det,
        dec_det
    )
    return inference_model
 def create_standalone_model(
    model_type: ModelType,
    vocabulary_size: int,
    latent_space: int = 256,
    feed_forward_multiplier: int = 4,
    attention_heads: int = 4,
    layer_number: int = 2,
 ) -> NanoSocratEncoder | NanoSocraDecoder:
    feed_forward_latent_space = latent_space * feed_forward_multiplier
    embedder = NanoSocratesEmbedder(vocabulary_size, latent_space)
    detokener = DeToken(latent_space, vocabulary_size)
    if model_type == ModelType.ENCODER_ONLY:
        TMP_ENCODERS = [
            Encoder(latent_space, feed_forward_latent_space, attention_heads)
        ] * layer_number
        encoder = torch.nn.Sequential(*TMP_ENCODERS)
        return NanoSocratEncoder(embedder, encoder, detokener)
    TMP_DECODERS = [
        Decoder(latent_space, feed_forward_latent_space, attention_heads)
    ] * layer_number
    decoder = torch.nn.Sequential(*TMP_DECODERS)
    return NanoSocraDecoder(embedder, decoder, detokener)
--- a/Project_Model/Libs/init.py
+++ b/Project_Model/Libs/init.py
@@ -2,3 +2,4 @@ from . import BPE
 from . import Embedder
 from . import Transformer
 from . import TorchShims
 from . import TransformerUtils
--- a/Project_Model/UML/model.excalidraw.json
+++ b/Project_Model/UML/model.excalidraw.json
--- a/environment.yaml
+++ b/environment.yaml
--- a/requirements.txt
+++ b/requirements.txt
Author	SHA1	Message	Date
Christian Risi	b79521995c	Last fixes	2025-10-17 22:17:24 +02:00
Christian Risi	540b78204c	Added epochs	2025-10-17 17:06:42 +02:00
GassiGiuseppe	86a063591e	Merge branch 'dev.train' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.train	2025-10-17 16:38:12 +02:00
GassiGiuseppe	f33d4f1db6	Added a loss_saver file to save the losses	2025-10-17 16:37:44 +02:00
Christian Risi	fe62b1edd5	Fixed evaluation	2025-10-16 20:05:35 +02:00
Christian Risi	892f91aad7	Fixes for evaluation	2025-10-16 19:20:23 +02:00
Christian Risi	9ff117f437	Adding best model	2025-10-16 19:20:09 +02:00
Christian Risi	83693f1d4e	Fixed a patience bug and added label smoothing	2025-10-14 11:03:15 +02:00
Christian Risi	0b256001fe	Changed position to reflect other datasets	2025-10-14 10:51:11 +02:00
Christian Risi	7585f556f8	Added more logging	2025-10-14 10:41:28 +02:00
Christian Risi	4968d79403	Fixed a masking problem	2025-10-14 10:34:14 +02:00
GassiGiuseppe	80fd7fd600	evaluator WIP	2025-10-12 22:59:07 +02:00
GassiGiuseppe	972a73758d	added holdout for curated dataset	2025-10-12 19:06:09 +02:00
GassiGiuseppe	b38a011105	added curated dataset, which is 8000	2025-10-12 19:01:28 +02:00
GassiGiuseppe	2bdcd78622	Merge branch 'dev.train' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.train	2025-10-12 18:20:04 +02:00
GassiGiuseppe	7dedbc481b	evaluator WIP	2025-10-12 18:18:20 +02:00
Christian Risi	76345f8d4f	Fixed a visual bug	2025-10-12 16:42:59 +02:00
GassiGiuseppe	2ccec9efb8	typo	2025-10-12 16:41:06 +02:00
GassiGiuseppe	e2231eb3b9	Merge branch 'dev.train' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.train	2025-10-12 16:36:09 +02:00
GassiGiuseppe	144f8724d6	Update of the batcher to resolve a bug in the 4th construction	2025-10-12 16:35:42 +02:00
Christian Risi	07130ff489	Fixed several bugs for task 4	2025-10-12 16:30:30 +02:00
Christian Risi	e0f8a36aa5	Added support for fast resuming	2025-10-12 13:53:07 +02:00
Christian Risi	37a2501a79	Added a way to load checkpoints	2025-10-12 12:28:24 +02:00
Christian Risi	4ca1d0a189	Activated Dropout to avoid overfitting	2025-10-12 12:28:06 +02:00
Christian Risi	f463f699cf	Fixed a bug over task 4	2025-10-12 12:22:38 +02:00
Christian Risi	ab3d68bc13	fixed patience not quitting	2025-10-12 01:41:34 +02:00
Christian Risi	79438e3d30	Fixed Patience system	2025-10-12 01:22:06 +02:00
Christian Risi	f98f5a2611	Fixed misprint in task 3	2025-10-12 01:16:09 +02:00
Christian Risi	4281f8724b	Fixed Validation loss	2025-10-12 00:57:24 +02:00
Christian Risi	71d602e36e	Fixed a memory bug	2025-10-12 00:47:20 +02:00
Christian Risi	46ee6055ec	Added Colab default values	2025-10-12 00:15:54 +02:00
Christian Risi	e579e1c88b	fixed verbosity	2025-10-12 00:15:15 +02:00
Christian Risi	f51ada866f	Added verbosity level	2025-10-12 00:13:03 +02:00
Christian Risi	acd978cbc5	Merge branch 'dev.train' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.train	2025-10-12 00:05:36 +02:00
Christian Risi	56fbadd55e	Fixed training	2025-10-12 00:05:30 +02:00
GassiGiuseppe	14f1c574e7	typo batch size	2025-10-11 22:11:53 +02:00
Christian Risi	d8e65bfb8a	Fixed a bug about mismatched batch sizes	2025-10-11 22:09:46 +02:00
Christian Risi	bcc2fe7368	Fixed bugs and added visibility	2025-10-11 21:49:29 +02:00
Christian Risi	160b7dbfc0	V0.0.1 Athene	2025-10-11 19:35:43 +02:00
GassiGiuseppe	49946727d8	updated decoder_input to work without embedder	2025-10-11 16:53:36 +02:00
GassiGiuseppe	1649cd7768	added decoder_input method to build the batch tensor to give in input to the deocder	2025-10-11 16:18:43 +02:00
GassiGiuseppe	443f54fffd	WIP decoder with prefix mask	2025-10-11 15:31:43 +02:00
GassiGiuseppe	ff721107b9	typo	2025-10-11 15:26:58 +02:00
GassiGiuseppe	f1886e5be1	added builder for prefix mask	2025-10-11 15:19:09 +02:00
GassiGiuseppe	5e3878ea17	Merge branch 'dev' into dev.train	2025-10-11 11:51:58 +02:00
GassiGiuseppe	79d3fb9ff8	Merge branch 'dev' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev	2025-10-11 11:51:19 +02:00
GassiGiuseppe	586f021276	Merge branch 'dev.train' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.train	2025-10-11 11:28:35 +02:00
GassiGiuseppe	82462078f8	WIP for the new prefix mask	2025-10-11 11:28:15 +02:00
Christian Risi	625f79f7c3	Fixed imports	2025-10-11 11:18:44 +02:00
GassiGiuseppe	3446870291	typo	2025-10-10 22:27:01 +02:00
GassiGiuseppe	e76dbeb9a7	typo	2025-10-10 22:26:06 +02:00
GassiGiuseppe	96610612fe	Batcher added	2025-10-10 20:10:08 +02:00
Christian Risi	92ae40013d	Added a way to detach models and create them standalone	2025-10-10 18:43:20 +02:00
Christian Risi	15f203cad5	Added boe 16k tokens vocabulary	2025-10-10 18:43:02 +02:00
Christian Risi	31c8541dfb	Co-authored-by: GassiGiuseppe <GassiGiuseppe@users.noreply.github.com>	2025-10-10 16:28:09 +02:00
Christian Risi	bed9718f27	Added BPE small vocabulary	2025-10-10 11:40:39 +02:00
GassiGiuseppe	93865bee8a	typo	2025-10-09 22:26:17 +02:00
Christian Risi	1c0ddb8753	Merge branch 'dev.embedder' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.embedder	2025-10-09 22:23:36 +02:00
Christian Risi	51399f9dc9	commit of toy dataset with whole batch	2025-10-09 22:22:42 +02:00
GassiGiuseppe	d1ba4ae026	last update for collab ( we are gonna run it on a 100 yey)	2025-10-09 21:57:05 +02:00
Christian Risi	db0090981c	Merge branch 'dev.embedder' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.embedder	2025-10-09 21:53:45 +02:00
Christian Risi	e1c5649d67	updated to overfit over toy dataset	2025-10-09 21:53:42 +02:00
GassiGiuseppe	0bca241662	update environment yaml	2025-10-09 20:53:45 +02:00
GassiGiuseppe	005d7af6a0	lil update of requirements	2025-10-09 20:30:06 +02:00
GassiGiuseppe	9068db550e	Merge branch 'dev.embedder' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.embedder	2025-10-09 19:44:46 +02:00
GassiGiuseppe	d8f81e1a47	that god can have mercy upon us	2025-10-09 19:43:50 +02:00
Christian Risi	a67df9724e	Merge branch 'dev.embedder' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.embedder	2025-10-09 18:14:33 +02:00
Christian Risi	c5fd57d854	Updated train playground	2025-10-09 18:14:29 +02:00
GassiGiuseppe	ee253c39f4	Merge branch 'dev.embedder' of https://repositories.communitynotfound.work/PoliBa-DeepLearning/NanoSocrates into dev.embedder	2025-10-09 13:31:37 +02:00
GassiGiuseppe	2036b4015f	added logistic collector	2025-10-09 13:31:16 +02:00
Christian Risi	aac7675b30	Pipeline fix and added a util to decode	2025-10-09 13:24:48 +02:00
GassiGiuseppe	d2fdeb18a2	bla bla doctor	2025-10-09 12:41:47 +02:00
Christian Risi	f3b83eda3d	Rework	2025-10-09 11:37:46 +02:00
Christian Risi	0158db2dce	Fixed a bug where I took encoder embeddings rather than encoder output	2025-10-09 11:37:21 +02:00
Christian Risi	ba592c3480	Disabled Softmax	2025-10-09 11:36:56 +02:00
Christian Risi	1f9c30b531	Added Custom Learning Rate	2025-10-09 11:36:40 +02:00
		`@@ -0,0 +1,2 @@`
							`from .Batcher import Batcher`
							`from .TokenCompletation import TokenCompletationTransformer`