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	"""
	Input UI for RoseTTAfold All Atom

	using two custom gradio components: gradio_molecule3d and gradio_cofoldinginput
	"""


	import gradio as gr
	from gradio_cofoldinginput import CofoldingInput

	from gradio_molecule3d import Molecule3D

	import json
	import yaml
	from openbabel import openbabel

	import zipfile
	import tempfile

	import os

	from Bio.PDB import PDBParser, PDBIO

	baseconfig = """job_name: "structure_prediction"
	output_path: ""
	checkpoint_path: RFAA_paper_weights.pt
	database_params:
	sequencedb: ""
	hhdb: "pdb100_2021Mar03/pdb100_2021Mar03"
	command: make_msa.sh
	num_cpus: 4
	mem: 64
	protein_inputs: null
	na_inputs: null
	sm_inputs: null
	covale_inputs: null
	residue_replacement: null

	chem_params:
	use_phospate_frames_for_NA: True
	use_cif_ordering_for_trp: True

	loader_params:
	n_templ: 4
	MAXLAT: 128
	MAXSEQ: 1024
	MAXCYCLE: 4
	BLACK_HOLE_INIT: False
	seqid: 150.0


	legacy_model_param:
	n_extra_block: 4
	n_main_block: 32
	n_ref_block: 4
	n_finetune_block: 0
	d_msa: 256
	d_msa_full: 64
	d_pair: 192
	d_templ: 64
	n_head_msa: 8
	n_head_pair: 6
	n_head_templ: 4
	d_hidden_templ: 64
	p_drop: 0.0
	use_chiral_l1: True
	use_lj_l1: True
	use_atom_frames: True
	recycling_type: "all"
	use_same_chain: True
	lj_lin: 0.75
	SE3_param:
	num_layers: 1
	num_channels: 32
	num_degrees: 2
	l0_in_features: 64
	l0_out_features: 64
	l1_in_features: 3
	l1_out_features: 2
	num_edge_features: 64
	n_heads: 4
	div: 4
	SE3_ref_param:
	num_layers: 2
	num_channels: 32
	num_degrees: 2
	l0_in_features: 64
	l0_out_features: 64
	l1_in_features: 3
	l1_out_features: 2
	num_edge_features: 64
	n_heads: 4
	div: 4
	"""

	def convert_format(input_file, jobname, chain, deleteIndexes, attachmentIndex):

	conv = openbabel.OBConversion()
	conv.SetInAndOutFormats('cdjson', 'sdf')

	# Add options
	conv.AddOption("c", openbabel.OBConversion.OUTOPTIONS, "1")
	with open(f"{jobname}_sm_{chain}.json", "w+") as fp:
	fp.write(input_file)
	mol = openbabel.OBMol()
	conv.ReadFile(mol, f"{jobname}_sm_{chain}.json")

	deleted_count = 0
	# delete atoms in delete indexes
	for index in sorted(deleteIndexes, reverse=True):
	if index < attachmentIndex:
	deleted_count += 1
	atom = mol.GetAtom(index)
	mol.DeleteAtom(atom)

	attachmentIndex -= deleted_count

	conv.WriteFile(mol, f"{jobname}_sm_{chain}.sdf")
	return attachmentIndex


	def prepare_input(input, jobname, baseconfig, hard_case):
	input_categories = {"protein":"protein_inputs", "DNA":"na_inputs","RNA":"na_inputs", "ligand":"sm_inputs"}

	# convert input to yaml format
	yaml_dict = {"defaults":["base"], "job_name":jobname, "output_path": jobname}
	list_of_input_files = []

	if len(input["chains"]) == 0:
	raise gr.Error("At least one chain must be provided")
	for chain in input["chains"]:
	if input_categories[chain["class"]] not in yaml_dict.keys():
	yaml_dict[input_categories[chain["class"]]] = {}

	if input_categories[chain["class"]] in ["protein_inputs", "na_inputs"]:
	#write fasta
	with open(f"{jobname}_{chain['chain']}.fasta", "w+") as fp:
	fp.write(f">chain A\n{chain['sequence']}")
	if input_categories[chain["class"]] == "na_inputs":
	entry = {"input_type":chain["class"].lower(), "fasta":f"{jobname}/{jobname}_{chain['chain']}.fasta"}
	else:
	entry = {"fasta_file": f"{jobname}/{jobname}_{chain['chain']}.fasta"}
	list_of_input_files.append(f"{jobname}_{chain['chain']}.fasta")
	yaml_dict[input_categories[chain["class"]]][chain['chain']] = entry

	if input_categories[chain['class']] == "sm_inputs":
	if "smiles" in chain.keys():
	entry = {"input_type": "smiles", "input": chain["smiles"]}
	elif "sdf" in chain.keys():
	# write to file
	with open(f"{jobname}_sm_{chain['chain']}.sdf", "w+") as fp:
	fp.write(chain["sdf"])
	list_of_input_files.append(f"{jobname}_sm_{chain['chain']}.sdf")
	entry = {"input_type": "sdf", "input": f"{jobname}/{jobname}_sm_{chain['chain']}.sdf"}
	elif "name" in chain.keys():
	list_of_input_files.append(f"metal_sdf/{chain['name']}_ideal.sdf")
	entry = {"input_type": "sdf", "input": f"{jobname}/{chain['name']}_ideal.sdf"}
	yaml_dict["sm_inputs"][chain['chain']] = entry

	covale_inputs = []
	if len(input["covMods"])>0:
	yaml_dict["covale_inputs"]=""

	for covMod in input["covMods"]:
	new_attachment_index = covMod["attachmentIndex"]
	if len(covMod["deleteIndexes"])>0:
	new_attachment_index = convert_format(covMod["mol"],jobname, covMod["ligand"], covMod["deleteIndexes"], covMod["attachmentIndex"])
	chirality_ligand = "null"
	chirality_protein = "null"
	if covMod["protein_symmetry"] in ["CW", "CCW"]:
	chirality_protein = covMod["protein_symmetry"]
	if covMod["ligand_symmetry"] in ["CW", "CCW"]:
	chirality_ligand = covMod["ligand_symmetry"]
	covale_inputs.append(((covMod[ "protein"], covMod["residue"], covMod["atom"]), (covMod["ligand"], new_attachment_index), (chirality_protein, chirality_ligand)))
	if len(input["covMods"])>0:
	yaml_dict["covale_inputs"] = json.dumps(json.dumps(covale_inputs))[1:-1].replace("'", "\"")

	if hard_case:
	yaml_dict["loader_params"]= {}
	yaml_dict["loader_params"]["MAXCYCLE"] = 10
	# write yaml to tmp
	with open(f"/tmp/{jobname}.yaml", "w+") as fp:
	# need to convert single quotes to double quotes
	fp.write(yaml.dump(yaml_dict).replace("'", "\""))

	# write baseconfig
	with open(f"/tmp/base.yaml", "w+") as fp:
	fp.write(baseconfig)

	list_of_input_files.append(f"/tmp/{jobname}.yaml")
	list_of_input_files.append(f"/tmp/base.yaml")
	# convert dictionary to YAML
	with zipfile.ZipFile(os.path.join("/tmp/", f"{jobname}.zip"), 'w') as zip_archive:
	for file in set(list_of_input_files):
	zip_archive.write(file, arcname= os.path.join(jobname,os.path.basename(file)),compress_type=zipfile.ZIP_DEFLATED)

	return yaml.dump(yaml_dict).replace("'", "\""),os.path.join("/tmp/", f"{jobname}.zip")


	def convert_bfactors(pdb_path):
	with open(pdb_path, 'r') as f:
	lines = f.readlines()
	for i,line in enumerate(lines):
	# multiple each bfactor by 100
	if line[0:6] == 'ATOM ' or line[0:6] == 'HETATM':
	bfactor = float(line[60:66])
	bfactor *= 100
	line = line[:60] + f'{bfactor:6.2f}' + line[66:]
	lines[i] = line
	with open(pdb_path.replace(".pdb", "_processed.pdb"), 'w') as f:
	f.write(''.join(lines))


	def run_rf2aa(jobname, zip_archive):
	current_dir = os.getcwd()
	try:
	with zipfile.ZipFile(zip_archive, 'r') as zip_ref:
	zip_ref.extractall(os.path.join(current_dir))
	os.system(f"python -m rf2aa.run_inference --config-name {jobname}.yaml --config-path {current_dir}/{jobname}")
	# scale pLDDT to 0-100 range in pdb output file
	convert_bfactors(f"{current_dir}/{jobname}/{jobname}.pdb")

	except Exception as e:
	raise gr.Error(f"Error running RFAA: {e}")
	return f"{current_dir}/{jobname}/{jobname}_processed.pdb"



	def predict(input, jobname, dry_run, baseconfig, hard_case):
	yaml_input, zip_archive = prepare_input(input, jobname, baseconfig, hard_case)

	reps = []

	for chain in input["chains"]:
	if chain["class"] in ["protein", "RNA", "DNA"]:
	reps.append({
	"model": 0,
	"chain": chain["chain"],
	"resname": "",
	"style": "cartoon",
	"color": "alphafold",
	"residue_range": "",
	"around": 0,
	"byres": False
	})
	elif chain["class"] == "ligand" and "name" not in chain.keys():
	reps.append({
	"model": 0,
	"chain": chain["chain"],
	"resname": "LG1",
	"style": "stick",
	"color": "whiteCarbon",
	"residue_range": "",
	"around": 0,
	"byres": False
	})
	else:
	reps.append({
	"model": 0,
	"chain": chain["chain"],
	"resname": "LG1",
	"style": "sphere",
	"color": "whiteCarbon",
	"residue_range": "",
	"around": 0,
	"byres": False
	})
	if dry_run:
	return gr.Code(yaml_input, visible=True), gr.File(zip_archive, visible=True), gr.Markdown(f"""You can run your RFAA job using the following command: <pre>python -m rf2aa.run_inference --config-name {jobname}.yaml --config-path absolute/path/to/unzipped/{jobname}</pre>""", visible=True), Molecule3D(visible=False)
	else:
	pdb_file = run_rf2aa(jobname, zip_archive)
	return gr.Code(yaml_input, visible=True), gr.File(zip_archive, visible=True),gr.Markdown(visible=False), Molecule3D(pdb_file,reps=reps,visible=True)

	with gr.Blocks() as demo:
	gr.Markdown("# RoseTTAFold All Atom UI")
	gr.Markdown("""This UI allows you to generate input files for RoseTTAFold All Atom (RFAA) using the CofoldingInput widget. The input files can be used to run RFAA on your local machine. <br />
	If you launch the UI directly on your local machine you can also directly run the RFAA prediction. <br />
	More information in the official GitHub repository: [baker-laboratory/RoseTTAFold-All-Atom](https://github.com/baker-laboratory/RoseTTAFold-All-Atom)
	""")
	jobname = gr.Textbox("job1", label="Job Name")
	with gr.Tab("Input"):
	inp=CofoldingInput(label="Input")
	hard_case = gr.Checkbox(False, label="Hard case (increase MAXCYCLE to 10)")
	# only allow running the predictions if local
	if os.environ.get("SPACE_HOST")!=None:
	dry_run = gr.Checkbox(True, label="Only generate input files (dry run)", interactive=False)
	else:
	dry_run = gr.Checkbox(True, label="Only generate input files (dry run)")
	with gr.Tab("Base config"):
	base_config = gr.Code(baseconfig, label="Base config")
	btn = gr.Button("Run")
	config_file = gr.Code(label="YAML Hydra config for RFAA", visible=True)
	runfiles = gr.File(label="files to run RFAA", visible=False)
	instructions = gr.Markdown(visible=False)

	out = Molecule3D(visible=False)

	btn.click(predict, inputs=[inp, jobname, dry_run, base_config, hard_case], outputs=[config_file, runfiles, instructions, out])

	if __name__ == "__main__":
	demo.launch(share=True)