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molclaw-diffdock-auto
Run automated DiffDock protein-ligand docking and return confidence-based result summaries.
用 Codex 或 Claude 帮你安装 复制这段 Prompt,粘贴到 Codex、Claude 或其他助手里,让它检查 Skill 页面并帮你完成安装。
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Run automated DiffDock protein-ligand docking and return confidence-based result summaries.
用 Codex 或 Claude 帮你安装 复制这段 Prompt,粘贴到 Codex、Claude 或其他助手里,让它检查 Skill 页面并帮你完成安装。
基于 SOC 职业分类
| name | molclaw-diffdock-auto |
| description | Run automated DiffDock protein-ligand docking and return confidence-based result summaries. |
| license | MIT license |
| metadata | {"skill-author":"PJLab"} |
Note:
drugsda-file-transfer before execution.drugsda-fix_pdb before execution.The description of tool diffdock_auto.
Automate DiffDock protein–ligand docking for single or batch inputs, run inference (unless `dry_run`), and return per-complex confidence summaries and produced files for prioritization.
Args:
protein_path (str|None): Protein PDB file path for single docking.
ligand (str|None): SMILES string or ligand file path (.sdf/.mol/.mol2/.pdb) for single docking.
protein_sequence (str|None): Protein sequence to trigger ESMFold when no PDB is available.
protein_ligand_csv (str|None): CSV path with `protein_path` and `ligand` columns for batch runs.
complex_name (str|None): Optional complex identifier for a single docking task.
inference_steps (int): Number of diffusion steps. Default: 20.
samples_per_complex (int): Number of generated samples per complex. Default: 40.
batch_size (int): Batch size for DiffDock inference. Default: 10.
device (str): Compute device, 'cuda' or 'cpu'. Default: 'cuda'.
dry_run (bool): If True, only validate inputs and skip DiffDock execution.
Return:
status (str): 'success' or 'error'.
msg (str): Human-readable summary or error message.
output_dir (str|None): Path to the run-specific output directory under tool_result/diffdoc_result.
summary_metrics (dict|None): Global metrics such as num_complexes, best_confidence, average_confidence, median_confidence.
quality_distribution (dict|None): Counts grouped by quality labels (Excellent/Good/Medium/Low).
complex_results (dict|None): Sanitized per-complex analysis dictionaries.
summary_csv (str|None): Path to docking_summary.csv when exported.
files (List[str]|None): Sorted file list produced in output_dir.
How to use tool diffdock_auto :
response = await client.session.call_tool(
"diffdock_auto",
arguments={
"protein_path": "/abs/path/outputok.pdb",
"ligand": "CC(C)Cc1ccc(C)cc1",
"inference_steps": 20,
"samples_per_complex": 40,
"batch_size": 10,
"device": "cuda",
"dry_run": False
}
)
result = client.parse_result(response)
summary_metrics = result["summary_metrics"]
# 1) Main mode: single protein-ligand docking (from readme usage/test)
{
"protein_path": "/abs/path/outputok.pdb",
"ligand": "CC(C)Cc1ccc(C)cc1",
"dry_run": False
}
# 2) Variant mode: batch docking with CSV input (from diffdock_auto_main usage)
{
"protein_ligand_csv": "/abs/path/batch_input.csv",
"inference_steps": 20,
"samples_per_complex": 60,
"batch_size": 15,
"dry_run": False
}
# 3) Variant mode: input validation only (dry run)
{``
"protein_path": "/abs/path/outputok.pdb",
"ligand": "CC(C)Cc1ccc(C)cc1",
"device": "cpu",
"dry_run": True
}
After calling this tool, you MUST download all output structure files from the MCP server to the local workspace using server_file_to_base64. A tool call is NOT considered complete until its output files have been downloaded and verified locally (ls -la <file> — size must be > 0).
import base64, os
response = await client.session.call_tool(
"server_file_to_base64",
arguments={"file_path": result["output_file"]} # or relevant output field
)
dl = client.parse_result(response)
local_path = "stepNN_descriptive_name.ext"
with open(local_path, "wb") as f:
f.write(base64.b64decode(dl["base64_string"]))
assert os.path.getsize(local_path) > 0, f"Download failed: {local_path}"
Download policy: All structure output files are Category A (user-critical) — essential for user verification, downstream analysis, and reproducibility. When in doubt, download. Over-collection is always preferred over under-collection.
DiffDock's confidence score is ONLY valid for comparing poses of the SAME molecule. NEVER use DiffDock confidence to rank DIFFERENT molecules against each other. For cross-molecule ranking, use QuickVina docking scores, EquiScore, or Boltz-2 binding probability instead.
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