notebooks/TD3B_Inference_Demo.ipynb

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      "gpuType": "T4"
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    "kernelspec": {
      "name": "python3",
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      "name": "python"
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  "cells": [
    {
      "cell_type": "markdown",
      "source": [
        "# TD3B: Transition-Directed Discrete Diffusion for Allosteric Binder Generation\n",
        "\n",
        "This notebook demonstrates **TD3B inference** — generating peptide binders with specified agonist or antagonist behavior for GPCR targets.\n",
        "\n",
        "**What TD3B does:**\n",
        "- Takes a target protein sequence + desired direction (agonist / antagonist)\n",
        "- Generates peptide binder sequences using a finetuned discrete diffusion model\n",
        "- Scores them with a Direction Oracle and binding affinity predictor\n",
        "- Returns the best candidates via weighted resampling (Algorithm 2)\n",
        "\n",
        "**Requirements:** GPU runtime (T4 or better). Click **Runtime → Change runtime type → GPU**."
      ],
      "metadata": {}
    },
    {
      "cell_type": "markdown",
      "source": [
        "## 1. Setup"
      ],
      "metadata": {}
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "# Install dependencies\n",
        "!pip install -q torch torchvision --index-url https://download.pytorch.org/whl/cu121\n",
        "!pip install -q transformers fair-esm SmilesPE rdkit-pypi scipy pandas numpy xgboost pytorch-lightning lightning hydra-core loguru timm huggingface_hub"
      ]
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "# Clone TD3B repository and download checkpoints from HuggingFace\n",
        "!git clone https://github.com/chq1155/TD3B_ICML.git TD3B\n",
        "%cd TD3B\n",
        "\n",
        "from huggingface_hub import hf_hub_download\n",
        "import os\n",
        "\n",
        "REPO_ID = \"ChatterjeeLab/TD3B\"\n",
        "os.makedirs(\"checkpoints\", exist_ok=True)\n",
        "os.makedirs(\"data\", exist_ok=True)\n",
        "\n",
        "# Download checkpoints (this may take a few minutes)\n",
        "for fname in [\"checkpoints/td3b.ckpt\", \"checkpoints/pretrained.ckpt\",\n",
        "              \"checkpoints/direction_oracle.pt\",\n",
        "              \"scoring/functions/classifiers/binding-affinity.pt\",\n",
        "              \"data/test.csv\", \"data/train.csv\"]:\n",
        "    print(f\"Downloading {fname}...\")\n",
        "    hf_hub_download(repo_id=REPO_ID, filename=fname, local_dir=\".\")\n",
        "\n",
        "print(\"\\nAll files downloaded!\")\n",
        "!ls -lh checkpoints/"
      ]
    },
    {
      "cell_type": "markdown",
      "source": [
        "## 2. Load Model and Oracle"
      ],
      "metadata": {}
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "import sys\n",
        "sys.path.insert(0, \".\")\n",
        "\n",
        "import torch\n",
        "import numpy as np\n",
        "import pandas as pd\n",
        "\n",
        "from diffusion import Diffusion\n",
        "from configs.finetune_config import (\n",
        "    DiffusionConfig, RoFormerConfig, NoiseConfig,\n",
        "    TrainingConfig, SamplingConfig, EvalConfig, OptimConfig, MCTSConfig,\n",
        ")\n",
        "from tokenizer.my_tokenizers import SMILES_SPE_Tokenizer\n",
        "from td3b.direction_oracle import DirectionalOracle\n",
        "from td3b.td3b_scoring import TD3BRewardFunction, create_td3b_reward_function\n",
        "from scoring.functions.binding import BindingAffinity\n",
        "from utils.app import PeptideAnalyzer\n",
        "\n",
        "device = torch.device(\"cuda\" if torch.cuda.is_available() else \"cpu\")\n",
        "print(f\"Using device: {device}\")\n",
        "if torch.cuda.is_available():\n",
        "    print(f\"GPU: {torch.cuda.get_device_name(0)}\")\n",
        "    print(f\"Memory: {torch.cuda.get_device_properties(0).total_mem / 1e9:.1f} GB\")"
      ]
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "# Load tokenizer\n",
        "tokenizer = SMILES_SPE_Tokenizer(\"tokenizer/new_vocab.txt\", \"tokenizer/new_splits.txt\")\n",
        "print(f\"Tokenizer vocab size: {len(tokenizer)}\")\n",
        "\n",
        "# Load diffusion model\n",
        "print(\"\\nLoading TD3B model...\")\n",
        "cfg = DiffusionConfig(\n",
        "    roformer=RoFormerConfig(hidden_size=768, n_layers=8, n_heads=8),\n",
        "    noise=NoiseConfig(),\n",
        "    training=TrainingConfig(sampling_eps=1e-3),\n",
        "    sampling=SamplingConfig(steps=128, sampling_eps=1e-3),\n",
        "    eval_cfg=EvalConfig(), optim=OptimConfig(lr=3e-4), mcts=MCTSConfig(),\n",
        ")\n",
        "model = Diffusion(config=cfg, tokenizer=tokenizer, device=device).to(device)\n",
        "\n",
        "ckpt = torch.load(\"checkpoints/td3b.ckpt\", map_location=device, weights_only=False)\n",
        "state_dict = ckpt.get(\"model_state_dict\") or ckpt.get(\"state_dict\") or ckpt\n",
        "model.load_state_dict(state_dict, strict=False)\n",
        "model.eval()\n",
        "model.tokenizer = tokenizer\n",
        "print(\"TD3B model loaded!\")\n",
        "\n",
        "# Load Direction Oracle\n",
        "print(\"\\nLoading Direction Oracle...\")\n",
        "oracle = DirectionalOracle(\n",
        "    model_ckpt=\"checkpoints/direction_oracle.pt\",\n",
        "    tr2d2_checkpoint=\"checkpoints/pretrained.ckpt\",\n",
        "    tokenizer_vocab=\"tokenizer/new_vocab.txt\",\n",
        "    tokenizer_splits=\"tokenizer/new_splits.txt\",\n",
        "    device=device,\n",
        ")\n",
        "oracle.eval()\n",
        "print(\"Direction Oracle loaded!\")\n",
        "\n",
        "# Load Affinity Predictor\n",
        "print(\"\\nLoading Affinity Predictor...\")\n",
        "analyzer = PeptideAnalyzer()\n",
        "print(\"\\nAll models loaded!\")"
      ]
    },
    {
      "cell_type": "markdown",
      "source": [
        "## 3. Define Helper Functions"
      ],
      "metadata": {}
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "def sample_sequences(model, batch_size, seq_length, num_steps=128, eps=1e-5):\n",
        "    \"\"\"Sample sequences from the diffusion model.\"\"\"\n",
        "    x = model.sample_prior(batch_size, seq_length).to(model.device, dtype=torch.long)\n",
        "    timesteps = torch.linspace(1, eps, num_steps + 1, device=model.device)\n",
        "    dt = torch.tensor((1 - eps) / num_steps, device=model.device)\n",
        "\n",
        "    for i in range(num_steps):\n",
        "        t = timesteps[i] * torch.ones(x.shape[0], 1, device=model.device)\n",
        "        _, x = model.single_reverse_step(x, t=t, dt=dt)\n",
        "        x = x.to(model.device)\n",
        "\n",
        "    mask_pos = (x == model.mask_index)\n",
        "    if mask_pos.any():\n",
        "        t = timesteps[-2] * torch.ones(x.shape[0], 1, device=model.device)\n",
        "        _, x = model.single_noise_removal(x, t=t, dt=dt)\n",
        "    return x\n",
        "\n",
        "\n",
        "def generate_binders(target_seq, direction=\"agonist\", num_pool=32,\n",
        "                     num_keep=8, alpha=0.1, seq_length=200):\n",
        "    \"\"\"\n",
        "    Generate directional binders for a target protein.\n",
        "    \n",
        "    Args:\n",
        "        target_seq: Target protein amino acid sequence\n",
        "        direction: 'agonist' or 'antagonist'\n",
        "        num_pool: Number of candidates to generate\n",
        "        num_keep: Number of final samples after resampling\n",
        "        alpha: Temperature for weighted resampling\n",
        "        seq_length: Binder sequence length (in SMILES tokens)\n",
        "    \n",
        "    Returns:\n",
        "        DataFrame with generated binders and scores\n",
        "    \"\"\"\n",
        "    d_star = 1.0 if direction == \"agonist\" else -1.0\n",
        "    \n",
        "    # Build reward function\n",
        "    affinity_pred = BindingAffinity(\n",
        "        prot_seq=target_seq, tokenizer=tokenizer,\n",
        "        base_path=\".\", device=device, emb_model=model.backbone\n",
        "    )\n",
        "    reward_fn = create_td3b_reward_function(\n",
        "        affinity_predictor=affinity_pred,\n",
        "        directional_oracle=oracle,\n",
        "        target_protein_seq=target_seq,\n",
        "        target_direction=direction,\n",
        "        peptide_tokenizer=tokenizer,\n",
        "        device=device,\n",
        "    )\n",
        "    \n",
        "    # Generate candidates\n",
        "    with torch.no_grad():\n",
        "        x_pool = sample_sequences(model, num_pool, seq_length)\n",
        "    sequences = tokenizer.batch_decode(x_pool)\n",
        "    \n",
        "    # Score all\n",
        "    rewards, info = reward_fn(sequences)\n",
        "    affinities = info[\"affinities\"]\n",
        "    directions = info[\"directions\"]\n",
        "    \n",
        "    # Weighted resampling (Algorithm 2)\n",
        "    rewards_t = torch.as_tensor(rewards, device=device)\n",
        "    weights = torch.softmax(rewards_t / max(alpha, 1e-6), dim=0)\n",
        "    idx = torch.multinomial(weights, num_samples=num_keep, replacement=True)\n",
        "    chosen = idx.cpu().numpy()\n",
        "    \n",
        "    # Filter to valid peptides only\n",
        "    results = []\n",
        "    for i in chosen:\n",
        "        is_valid = analyzer.is_peptide(sequences[i])\n",
        "        da = float(directions[i] > 0.5) if d_star > 0 else float(directions[i] < 0.5)\n",
        "        results.append({\n",
        "            \"sequence\": sequences[i],\n",
        "            \"direction\": direction,\n",
        "            \"is_valid\": is_valid,\n",
        "            \"affinity\": float(affinities[i]),\n",
        "            \"gated_reward\": float(rewards[i]),\n",
        "            \"p_agonist\": float(directions[i]),\n",
        "            \"direction_accuracy\": da,\n",
        "        })\n",
        "    \n",
        "    df = pd.DataFrame(results)\n",
        "    return df"
      ]
    },
    {
      "cell_type": "markdown",
      "source": [
        "## 4. Generate Binders\n",
        "\n",
        "Let's generate **agonist** and **antagonist** binders for a test target and compare the Direction Oracle predictions."
      ],
      "metadata": {}
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "# Load test targets\n",
        "test_df = pd.read_csv(\"data/test.csv\")\n",
        "print(f\"Test set: {len(test_df)} target-binder pairs\")\n",
        "\n",
        "# Pick first target for demo\n",
        "target_row = test_df.iloc[0]\n",
        "TARGET_SEQ = target_row[\"Target_Sequence\"]\n",
        "TARGET_UID = target_row[\"Target_UniProt_ID\"]\n",
        "print(f\"\\nTarget: {TARGET_UID}\")\n",
        "print(f\"Sequence length: {len(TARGET_SEQ)} aa\")\n",
        "print(f\"Sequence: {TARGET_SEQ[:60]}...\")"
      ]
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "%%time\n",
        "# Generate AGONIST binders\n",
        "print(\"Generating agonist binders (d*=+1)...\")\n",
        "torch.manual_seed(42)\n",
        "np.random.seed(42)\n",
        "df_agonist = generate_binders(TARGET_SEQ, direction=\"agonist\", num_pool=32, num_keep=8)\n",
        "\n",
        "print(f\"\\nGenerated {len(df_agonist)} samples ({df_agonist['is_valid'].sum()} valid)\")\n",
        "print(f\"Mean p(agonist): {df_agonist['p_agonist'].mean():.3f}\")\n",
        "print(f\"Mean affinity: {df_agonist['affinity'].mean():.2f}\")\n",
        "print(f\"Mean gated reward: {df_agonist['gated_reward'].mean():.2f}\")"
      ]
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "%%time\n",
        "# Generate ANTAGONIST binders\n",
        "print(\"Generating antagonist binders (d*=-1)...\")\n",
        "torch.manual_seed(42)\n",
        "np.random.seed(42)\n",
        "df_antagonist = generate_binders(TARGET_SEQ, direction=\"antagonist\", num_pool=32, num_keep=8)\n",
        "\n",
        "print(f\"\\nGenerated {len(df_antagonist)} samples ({df_antagonist['is_valid'].sum()} valid)\")\n",
        "print(f\"Mean p(agonist): {df_antagonist['p_agonist'].mean():.3f}\")\n",
        "print(f\"Mean affinity: {df_antagonist['affinity'].mean():.2f}\")\n",
        "print(f\"Mean gated reward: {df_antagonist['gated_reward'].mean():.2f}\")"
      ]
    },
    {
      "cell_type": "markdown",
      "source": [
        "## 5. Compare Directional Control"
      ],
      "metadata": {}
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "import matplotlib.pyplot as plt\n",
        "\n",
        "fig, axes = plt.subplots(1, 3, figsize=(15, 4))\n",
        "\n",
        "# Plot 1: Direction Oracle p(agonist)\n",
        "axes[0].hist(df_agonist[\"p_agonist\"], bins=20, alpha=0.7, label=\"d*=+1 (agonist)\", color=\"#e74c3c\")\n",
        "axes[0].hist(df_antagonist[\"p_agonist\"], bins=20, alpha=0.7, label=\"d*=-1 (antagonist)\", color=\"#3498db\")\n",
        "axes[0].axvline(0.5, color=\"gray\", linestyle=\"--\", label=\"threshold\")\n",
        "axes[0].set_xlabel(\"p(agonist)\")\n",
        "axes[0].set_ylabel(\"Count\")\n",
        "axes[0].set_title(\"Direction Oracle Predictions\")\n",
        "axes[0].legend()\n",
        "\n",
        "# Plot 2: Binding Affinity\n",
        "axes[1].hist(df_agonist[\"affinity\"], bins=20, alpha=0.7, label=\"Agonist\", color=\"#e74c3c\")\n",
        "axes[1].hist(df_antagonist[\"affinity\"], bins=20, alpha=0.7, label=\"Antagonist\", color=\"#3498db\")\n",
        "axes[1].set_xlabel(\"Predicted Binding Affinity\")\n",
        "axes[1].set_ylabel(\"Count\")\n",
        "axes[1].set_title(\"Binding Affinity Distribution\")\n",
        "axes[1].legend()\n",
        "\n",
        "# Plot 3: Gated Reward\n",
        "axes[2].hist(df_agonist[\"gated_reward\"], bins=20, alpha=0.7, label=\"Agonist\", color=\"#e74c3c\")\n",
        "axes[2].hist(df_antagonist[\"gated_reward\"], bins=20, alpha=0.7, label=\"Antagonist\", color=\"#3498db\")\n",
        "axes[2].set_xlabel(\"Gated Reward\")\n",
        "axes[2].set_ylabel(\"Count\")\n",
        "axes[2].set_title(\"Gated Reward Distribution\")\n",
        "axes[2].legend()\n",
        "\n",
        "plt.tight_layout()\n",
        "plt.savefig(\"td3b_results.png\", dpi=150, bbox_inches=\"tight\")\n",
        "plt.show()\n",
        "\n",
        "print(\"\\nSummary:\")\n",
        "print(f\"  Agonist mode:    p(agonist)={df_agonist['p_agonist'].mean():.3f}  Affinity={df_agonist['affinity'].mean():.2f}  Gated={df_agonist['gated_reward'].mean():.2f}\")\n",
        "print(f\"  Antagonist mode: p(agonist)={df_antagonist['p_agonist'].mean():.3f}  Affinity={df_antagonist['affinity'].mean():.2f}  Gated={df_antagonist['gated_reward'].mean():.2f}\")\n",
        "print(f\"  Directional gap: Δp = {df_agonist['p_agonist'].mean() - df_antagonist['p_agonist'].mean():.3f}\")"
      ]
    },
    {
      "cell_type": "markdown",
      "source": [
        "## 6. Run on Multiple Targets\n",
        "\n",
        "Generate binders for the first 5 test targets and compute aggregate metrics."
      ],
      "metadata": {}
    },
    {
      "cell_type": "code",
      "execution_count": null,
      "metadata": {},
      "outputs": [],
      "source": [
        "N_TARGETS = 5  # Number of targets to evaluate (increase for full benchmark)\n",
        "\n",
        "all_results = []\n",
        "targets = test_df.drop_duplicates(\"Target_UniProt_ID\").head(N_TARGETS)\n",
        "\n",
        "for i, (_, row) in enumerate(targets.iterrows()):\n",
        "    uid = row[\"Target_UniProt_ID\"]\n",
        "    seq = row[\"Target_Sequence\"]\n",
        "    print(f\"[{i+1}/{N_TARGETS}] {uid} (len={len(seq)})\")\n",
        "    \n",
        "    for direction in [\"agonist\", \"antagonist\"]:\n",
        "        torch.manual_seed(42)\n",
        "        np.random.seed(42)\n",
        "        df = generate_binders(seq, direction=direction, num_pool=32, num_keep=8)\n",
        "        df[\"target_uid\"] = uid\n",
        "        all_results.append(df)\n",
        "        \n",
        "        d_star = 1.0 if direction == \"agonist\" else -1.0\n",
        "        da = df[\"direction_accuracy\"].mean()\n",
        "        print(f\"    {direction:>10s}: DA={da:.2f}  Aff={df['affinity'].mean():.2f}  Gated={df['gated_reward'].mean():.2f}  valid={df['is_valid'].sum()}/{len(df)}\")\n",
        "\n",
        "combined = pd.concat(all_results, ignore_index=True)\n",
        "\n",
        "print(f\"\\n{'='*60}\")\n",
        "print(f\"AGGREGATE METRICS ({N_TARGETS} targets)\")\n",
        "print(f\"{'='*60}\")\n",
        "for d_name, d_val in [(\"Agonist (d*=+1)\", \"agonist\"), (\"Antagonist (d*=-1)\", \"antagonist\")]:\n",
        "    sub = combined[combined[\"direction\"] == d_val]\n",
        "    valid = sub[sub[\"is_valid\"] == True]\n",
        "    print(f\"  {d_name}:\")\n",
        "    print(f\"    Affinity: {sub['affinity'].mean():.2f}\")\n",
        "    print(f\"    Direction Accuracy: {sub['direction_accuracy'].mean():.3f}\")\n",
        "    print(f\"    Gated Reward (all): {sub['gated_reward'].mean():.2f}\")\n",
        "    if len(valid) > 0:\n",
        "        print(f\"    Gated Reward (valid): {valid['gated_reward'].mean():.2f}\")\n",
        "    print(f\"    Valid: {sub['is_valid'].sum()}/{len(sub)}\")\n",
        "\n",
        "# Save\n",
        "combined.to_csv(\"td3b_demo_results.csv\", index=False)\n",
        "print(f\"\\nResults saved to td3b_demo_results.csv\")"
      ]
    },
    {
      "cell_type": "markdown",
      "source": [
        "## Citation\n",
        "\n",
        "```bibtex\n",
        "@article{caotd3b,\n",
        "  title={TD3B: Transition-Directed Discrete Diffusion for Allosteric Binder Generation},\n",
        "  author={Cao, Hanqun and Pal, Aastha and Tang, Sophia and Zhang, Yinuo and Zhang, Jingjie and Heng, Pheng-Ann and Chatterjee, Pranam}\n",
        "}\n",
        "```"
      ],
      "metadata": {}
    }
  ]
}