Mercurial > repos > bimib > marea_2
view marea_2/flux_to_map.py @ 300:d91eba7f377b draft
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| author | luca_milaz |
|---|---|
| date | Mon, 05 Aug 2024 10:35:05 +0000 |
| parents | 67b200f39946 |
| children | 52f00d58bd39 |
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from __future__ import division import csv from enum import Enum import re import sys import numpy as np import pandas as pd import itertools as it import scipy.stats as st import lxml.etree as ET import math import utils.general_utils as utils from PIL import Image import os import copy import argparse import pyvips from PIL import Image, ImageDraw, ImageFont from typing import Tuple, Union, Optional, List, Dict ERRORS = [] ########################## argparse ########################################## ARGS :argparse.Namespace def process_args() -> argparse.Namespace: """ Interfaces the script of a module with its frontend, making the user's choices for various parameters available as values in code. Args: args : Always obtained (in file) from sys.argv Returns: Namespace : An object containing the parsed arguments """ parser = argparse.ArgumentParser( usage = "%(prog)s [options]", description = "process some value's genes to create a comparison's map.") #General: parser.add_argument( '-td', '--tool_dir', type = str, required = True, help = 'your tool directory') parser.add_argument('-on', '--control', type = str) parser.add_argument('-ol', '--out_log', help = "Output log") #Computation details: parser.add_argument( '-co', '--comparison', type = str, default = '1vs1', choices = ['manyvsmany', 'onevsrest', 'onevsmany']) parser.add_argument( '-pv' ,'--pValue', type = float, default = 0.1, help = 'P-Value threshold (default: %(default)s)') parser.add_argument( '-fc', '--fChange', type = float, default = 1.5, help = 'Fold-Change threshold (default: %(default)s)') parser.add_argument( '-op', '--option', type = str, choices = ['datasets', 'dataset_class'], help='dataset or dataset and class') parser.add_argument( '-idf', '--input_data_fluxes', type = str, help = 'input dataset fluxes') parser.add_argument( '-icf', '--input_class_fluxes', type = str, help = 'sample group specification fluxes') parser.add_argument( '-idsf', '--input_datas_fluxes', type = str, nargs = '+', help = 'input datasets fluxes') parser.add_argument( '-naf', '--names_fluxes', type = str, nargs = '+', help = 'input names fluxes') #Output: parser.add_argument( "-gs", "--generate_svg", type = utils.Bool("generate_svg"), default = True, help = "choose whether to generate svg") parser.add_argument( "-gp", "--generate_pdf", type = utils.Bool("generate_pdf"), default = True, help = "choose whether to generate pdf") parser.add_argument( '-cm', '--custom_map', type = str, help='custom map to use') parser.add_argument( '-mc', '--choice_map', type = utils.Model, default = utils.Model.HMRcore, choices = [utils.Model.HMRcore, utils.Model.ENGRO2, utils.Model.Custom]) args :argparse.Namespace = parser.parse_args() args.net = True return args ############################ dataset input #################################### def read_dataset(data :str, name :str) -> pd.DataFrame: """ Tries to read the dataset from its path (data) as a tsv and turns it into a DataFrame. Args: data : filepath of a dataset (from frontend input params or literals upon calling) name : name associated with the dataset (from frontend input params or literals upon calling) Returns: pd.DataFrame : dataset in a runtime operable shape Raises: sys.exit : if there's no data (pd.errors.EmptyDataError) or if the dataset has less than 2 columns """ try: dataset = pd.read_csv(data, sep = '\t', header = 0, engine='python') except pd.errors.EmptyDataError: sys.exit('Execution aborted: wrong format of ' + name + '\n') if len(dataset.columns) < 2: sys.exit('Execution aborted: wrong format of ' + name + '\n') return dataset ############################ dataset name ##################################### def name_dataset(name_data :str, count :int) -> str: """ Produces a unique name for a dataset based on what was provided by the user. The default name for any dataset is "Dataset", thus if the user didn't change it this function appends f"_{count}" to make it unique. Args: name_data : name associated with the dataset (from frontend input params) count : counter from 1 to make these names unique (external) Returns: str : the name made unique """ if str(name_data) == 'Dataset': return str(name_data) + '_' + str(count) else: return str(name_data) ############################ map_methods ###################################### FoldChange = Union[float, int, str] # Union[float, Literal[0, "-INF", "INF"]] def fold_change(avg1 :float, avg2 :float) -> FoldChange: """ Calculates the fold change between two gene expression values. Args: avg1 : average expression value from one dataset avg2 : average expression value from the other dataset Returns: FoldChange : 0 : when both input values are 0 "-INF" : when avg1 is 0 "INF" : when avg2 is 0 float : for any other combination of values """ if avg1 == 0 and avg2 == 0: return 0 elif avg1 == 0: return '-INF' elif avg2 == 0: return 'INF' else: # (threshold_F_C - 1) / (abs(threshold_F_C) + 1) con threshold_F_C > 1 return (avg1 - avg2) / (abs(avg1) + abs(avg2)) def fix_style(l :str, col :Optional[str], width :str, dash :str) -> str: """ Produces a "fixed" style string to assign to a reaction arrow in the SVG map, assigning style properties to the corresponding values passed as input params. Args: l : current style string of an SVG element col : new value for the "stroke" style property width : new value for the "stroke-width" style property dash : new value for the "stroke-dasharray" style property Returns: str : the fixed style string """ tmp = l.split(';') flag_col = False flag_width = False flag_dash = False for i in range(len(tmp)): if tmp[i].startswith('stroke:'): tmp[i] = 'stroke:' + col flag_col = True if tmp[i].startswith('stroke-width:'): tmp[i] = 'stroke-width:' + width flag_width = True if tmp[i].startswith('stroke-dasharray:'): tmp[i] = 'stroke-dasharray:' + dash flag_dash = True if not flag_col: tmp.append('stroke:' + col) if not flag_width: tmp.append('stroke-width:' + width) if not flag_dash: tmp.append('stroke-dasharray:' + dash) return ';'.join(tmp) # The type of d values is collapsed, losing precision, because the dict containst lists instead of tuples, please fix! def fix_map(d :Dict[str, List[Union[float, FoldChange]]], core_map :ET.ElementTree, threshold_P_V :float, threshold_F_C :float, max_z_score :float) -> ET.ElementTree: """ Edits the selected SVG map based on the p-value and fold change data (d) and some significance thresholds also passed as inputs. Args: d : dictionary mapping a p-value and a fold-change value (values) to each reaction ID as encoded in the SVG map (keys) core_map : SVG map to modify threshold_P_V : threshold for a p-value to be considered significant threshold_F_C : threshold for a fold change value to be considered significant max_z_score : highest z-score (absolute value) Returns: ET.ElementTree : the modified core_map Side effects: core_map : mut """ maxT = 12 minT = 2 grey = '#BEBEBE' blue = '#6495ed' red = '#ecac68' for el in core_map.iter(): el_id = str(el.get('id')) if el_id.startswith('R_'): tmp = d.get(el_id[2:]) if tmp != None: p_val :float = tmp[0] f_c = tmp[1] z_score = tmp[2] if p_val < threshold_P_V: if not isinstance(f_c, str): if abs(f_c) < ((threshold_F_C - 1) / (abs(threshold_F_C) + 1)): # col = grey width = str(minT) else: if f_c < 0: col = blue elif f_c > 0: col = red width = str(max((abs(z_score) * maxT) / max_z_score, minT)) else: if f_c == '-INF': col = blue elif f_c == 'INF': col = red width = str(maxT) dash = 'none' else: dash = '5,5' col = grey width = str(minT) el.set('style', fix_style(el.get('style', ""), col, width, dash)) return core_map def getElementById(reactionId :str, metabMap :ET.ElementTree) -> utils.Result[ET.Element, utils.Result.ResultErr]: """ Finds any element in the given map with the given ID. ID uniqueness in an svg file is recommended but not enforced, if more than one element with the exact ID is found only the first will be returned. Args: reactionId (str): exact ID of the requested element. metabMap (ET.ElementTree): metabolic map containing the element. Returns: utils.Result[ET.Element, ResultErr]: result of the search, either the first match found or a ResultErr. """ return utils.Result.Ok( f"//*[@id=\"{reactionId}\"]").map( lambda xPath : metabMap.xpath(xPath)[0]).mapErr( lambda _ : utils.Result.ResultErr(f"No elements with ID \"{reactionId}\" found in map")) # ^^^ we shamelessly ignore the contents of the IndexError, it offers nothing to the user. def styleMapElement(element :ET.Element, styleStr :str) -> None: currentStyles :str = element.get("style", "") if re.search(r";stroke:[^;]+;stroke-width:[^;]+;stroke-dasharray:[^;]+$", currentStyles): currentStyles = ';'.join(currentStyles.split(';')[:-3]) element.set("style", currentStyles + styleStr) class ReactionDirection(Enum): Unknown = "" Direct = "_F" Inverse = "_B" @classmethod def fromDir(cls, s :str) -> "ReactionDirection": # vvv as long as there's so few variants I actually condone the if spam: if s == ReactionDirection.Direct.value: return ReactionDirection.Direct if s == ReactionDirection.Inverse.value: return ReactionDirection.Inverse return ReactionDirection.Unknown @classmethod def fromReactionId(cls, reactionId :str) -> "ReactionDirection": return ReactionDirection.fromDir(reactionId[-2:]) def getArrowBodyElementId(reactionId :str) -> str: if reactionId.endswith("_RV"): reactionId = reactionId[:-3] #TODO: standardize _RV elif ReactionDirection.fromReactionId(reactionId) is not ReactionDirection.Unknown: reactionId = reactionId[:-2] return f"R_{reactionId}" def getArrowHeadElementId(reactionId :str) -> Tuple[str, str]: """ We attempt extracting the direction information from the provided reaction ID, if unsuccessful we provide the IDs of both directions. Args: reactionId : the provided reaction ID. Returns: Tuple[str, str]: either a single str ID for the correct arrow head followed by an empty string or both options to try. """ if reactionId.endswith("_RV"): reactionId = reactionId[:-3] #TODO: standardize _RV elif ReactionDirection.fromReactionId(reactionId) is not ReactionDirection.Unknown: return reactionId[:-3:-1] + reactionId[:-2], "" return f"F_{reactionId}", f"B_{reactionId}" class ArrowColor(Enum): """ Encodes possible arrow colors based on their meaning in the enrichment process. """ Invalid = "#BEBEBE" # gray, fold-change under treshold Transparent = "#ffffff00" # white, not significant p-value UpRegulated = "#ecac68" # red, up-regulated reaction DownRegulated = "#6495ed" # blue, down-regulated reaction UpRegulatedInv = "#FF0000" # ^^^ different shade of red (actually orange), up-regulated net value for a reversible reaction with # conflicting enrichment in the two directions. DownRegulatedInv = "#0000FF" # ^^^ different shade of blue (actually purple), down-regulated net value for a reversible reaction with # conflicting enrichment in the two directions. @classmethod def fromFoldChangeSign(cls, foldChange :float, *, useAltColor = False) -> "ArrowColor": colors = (cls.DownRegulated, cls.DownRegulatedInv) if foldChange < 0 else (cls.UpRegulated, cls.UpRegulatedInv) return colors[useAltColor] def __str__(self) -> str: return self.value class Arrow: """ Models the properties of a reaction arrow that change based on enrichment. """ MIN_W = 2 MAX_W = 12 def __init__(self, width :int, col: ArrowColor, *, isDashed = False) -> None: """ (Private) Initializes an instance of Arrow. Args: width : width of the arrow, ideally to be kept within Arrow.MIN_W and Arrow.MAX_W (not enforced). col : color of the arrow. isDashed : whether the arrow should be dashed, meaning the associated pValue resulted not significant. Returns: None : practically, a Arrow instance. """ self.w = width self.col = col self.dash = isDashed def applyTo(self, reactionId :str, metabMap :ET.ElementTree, styleStr :str) -> None: if getElementById(reactionId, metabMap).map(lambda el : styleMapElement(el, styleStr)).isErr: ERRORS.append(reactionId) def styleReactionElements(self, metabMap :ET.ElementTree, reactionId :str, *, mindReactionDir = True) -> None: if not mindReactionDir: return self.applyTo(getArrowBodyElementId(reactionId), metabMap, self.toStyleStr()) # Now we style the arrow head(s): idOpt1, idOpt2 = getArrowHeadElementId(reactionId) self.applyTo(idOpt1, metabMap, self.toStyleStr(downSizedForTips = True)) if idOpt2: self.applyTo(idOpt2, metabMap, self.toStyleStr(downSizedForTips = True)) def styleReactionElements_custom(self, metabMap :ET.ElementTree, reactionId :str, isNegative:bool) -> None: self.applyTo(getArrowBodyElementId(reactionId), metabMap, self.toStyleStr()) idOpt1, idOpt2 = getArrowHeadElementId(reactionId) if(isNegative): self.applyTo(idOpt2, metabMap, self.toStyleStr(downSizedForTips = True)) self.col = ArrowColor.Transparent self.applyTo(idOpt1, metabMap, self.toStyleStr(downSizedForTips = True)) #trasp else: self.applyTo(idOpt1, metabMap, self.toStyleStr(downSizedForTips = True)) self.col = ArrowColor.Transparent self.applyTo(idOpt2, metabMap, self.toStyleStr(downSizedForTips = True)) #trasp def getMapReactionId(self, reactionId :str, mindReactionDir :bool) -> str: """ Computes the reaction ID as encoded in the map for a given reaction ID from the dataset. Args: reactionId: the reaction ID, as encoded in the dataset. mindReactionDir: if True forward (F_) and backward (B_) directions will be encoded in the result. Returns: str : the ID of an arrow's body or tips in the map. """ # we assume the reactionIds also don't encode reaction dir if they don't mind it when styling the map. if not mindReactionDir: return "R_" + reactionId #TODO: this is clearly something we need to make consistent in fluxes return (reactionId[:-3:-1] + reactionId[:-2]) if reactionId[:-2] in ["_F", "_B"] else f"F_{reactionId}" # "Pyr_F" --> "F_Pyr" def toStyleStr(self, *, downSizedForTips = False) -> str: """ Collapses the styles of this Arrow into a str, ready to be applied as part of the "style" property on an svg element. Returns: str : the styles string. """ width = self.w if downSizedForTips: width *= 0.8 return f";stroke:{self.col};stroke-width:{width};stroke-dasharray:{'5,5' if self.dash else 'none'}" # vvv These constants could be inside the class itself a static properties, but python # was built by brainless organisms so here we are! INVALID_ARROW = Arrow(Arrow.MIN_W, ArrowColor.Invalid) INSIGNIFICANT_ARROW = Arrow(Arrow.MIN_W, ArrowColor.Invalid, isDashed = True) def applyFluxesEnrichmentToMap(fluxesEnrichmentRes :Dict[str, Union[Tuple[float, FoldChange], Tuple[float, FoldChange, float, float]]], metabMap :ET.ElementTree, maxNumericZScore :float) -> None: """ Applies fluxes enrichment results to the provided metabolic map. Args: fluxesEnrichmentRes : fluxes enrichment results. metabMap : the metabolic map to edit. maxNumericZScore : biggest finite z-score value found. Side effects: metabMap : mut Returns: None """ for reactionId, values in fluxesEnrichmentRes.items(): pValue = values[0] foldChange = values[1] z_score = values[2] if isinstance(foldChange, str): foldChange = float(foldChange) if pValue >= ARGS.pValue: # pValue above tresh: dashed arrow INSIGNIFICANT_ARROW.styleReactionElements(metabMap, reactionId) INSIGNIFICANT_ARROW.styleReactionElements(metabMap, reactionId, mindReactionDir = False) continue if abs(foldChange) < (ARGS.fChange - 1) / (abs(ARGS.fChange) + 1): INVALID_ARROW.styleReactionElements(metabMap, reactionId) INVALID_ARROW.styleReactionElements(metabMap, reactionId, mindReactionDir = False) continue width = Arrow.MAX_W if not math.isinf(foldChange): try: width = max(abs(z_score * Arrow.MAX_W) / maxNumericZScore, Arrow.MIN_W) except ZeroDivisionError: pass #if not reactionId.endswith("_RV"): # RV stands for reversible reactions # Arrow(width, ArrowColor.fromFoldChangeSign(foldChange)).styleReactionElements(metabMap, reactionId) # continue #reactionId = reactionId[:-3] # Remove "_RV" inversionScore = (values[3] < 0) + (values[4] < 0) # Compacts the signs of averages into 1 easy to check score if inversionScore == 2: foldChange *= -1 # ^^^ Style the inverse direction with the opposite sign netValue # If the score is 1 (opposite signs) we use alternative colors vvv arrow = Arrow(width, ArrowColor.fromFoldChangeSign(foldChange, useAltColor = inversionScore == 1)) # vvv These 2 if statements can both be true and can both happen if ARGS.net: # style arrow head(s): arrow.styleReactionElements(metabMap, reactionId + ("_B" if inversionScore == 2 else "_F")) arrow.applyTo(("F_" if inversionScore == 2 else "B_") + reactionId, metabMap, f";stroke:{ArrowColor.Transparent};stroke-width:0;stroke-dasharray:None") arrow.styleReactionElements(metabMap, reactionId, mindReactionDir = False) ############################ split class ###################################### def split_class(classes :pd.DataFrame, resolve_rules :Dict[str, List[float]]) -> Dict[str, List[List[float]]]: """ Generates a :dict that groups together data from a :DataFrame based on classes the data is related to. Args: classes : a :DataFrame of only string values, containing class information (rows) and keys to query the resolve_rules :dict resolve_rules : a :dict containing :float data Returns: dict : the dict with data grouped by class Side effects: classes : mut """ class_pat :Dict[str, List[List[float]]] = {} for i in range(len(classes)): classe :str = classes.iloc[i, 1] if pd.isnull(classe): continue l :List[List[float]] = [] for j in range(i, len(classes)): if classes.iloc[j, 1] == classe: pat_id :str = classes.iloc[j, 0] tmp = resolve_rules.get(pat_id, None) if tmp != None: l.append(tmp) classes.iloc[j, 1] = None if l: class_pat[classe] = list(map(list, zip(*l))) continue utils.logWarning( f"Warning: no sample found in class \"{classe}\", the class has been disregarded", ARGS.out_log) return class_pat ############################ conversion ############################################## #conversion from svg to png def svg_to_png_with_background(svg_path :utils.FilePath, png_path :utils.FilePath, dpi :int = 72, scale :int = 1, size :Optional[float] = None) -> None: """ Internal utility to convert an SVG to PNG (forced opaque) to aid in PDF conversion. Args: svg_path : path to SVG file png_path : path for new PNG file dpi : dots per inch of the generated PNG scale : scaling factor for the generated PNG, computed internally when a size is provided size : final effective width of the generated PNG Returns: None """ if size: image = pyvips.Image.new_from_file(svg_path.show(), dpi=dpi, scale=1) scale = size / image.width image = image.resize(scale) else: image = pyvips.Image.new_from_file(svg_path.show(), dpi=dpi, scale=scale) white_background = pyvips.Image.black(image.width, image.height).new_from_image([255, 255, 255]) white_background = white_background.affine([scale, 0, 0, scale]) if white_background.bands != image.bands: white_background = white_background.extract_band(0) composite_image = white_background.composite2(image, 'over') composite_image.write_to_file(png_path.show()) #funzione unica, lascio fuori i file e li passo in input #conversion from png to pdf def convert_png_to_pdf(png_file :utils.FilePath, pdf_file :utils.FilePath) -> None: """ Internal utility to convert a PNG to PDF to aid from SVG conversion. Args: png_file : path to PNG file pdf_file : path to new PDF file Returns: None """ image = Image.open(png_file.show()) image = image.convert("RGB") image.save(pdf_file.show(), "PDF", resolution=100.0) #function called to reduce redundancy in the code def convert_to_pdf(file_svg :utils.FilePath, file_png :utils.FilePath, file_pdf :utils.FilePath) -> None: """ Converts the SVG map at the provided path to PDF. Args: file_svg : path to SVG file file_png : path to PNG file file_pdf : path to new PDF file Returns: None """ svg_to_png_with_background(file_svg, file_png) try: convert_png_to_pdf(file_png, file_pdf) print(f'PDF file {file_pdf.filePath} successfully generated.') except Exception as e: raise utils.DataErr(file_pdf.show(), f'Error generating PDF file: {e}') ############################ map ############################################## def buildOutputPath(dataset1Name :str, dataset2Name = "rest", *, details = "", ext :utils.FileFormat) -> utils.FilePath: """ Builds a FilePath instance from the names of confronted datasets ready to point to a location in the "result/" folder, used by this tool for output files in collections. Args: dataset1Name : _description_ dataset2Name : _description_. Defaults to "rest". details : _description_ ext : _description_ Returns: utils.FilePath : _description_ """ # This function returns a util data structure but is extremely specific to this module. # RAS also uses collections as output and as such might benefit from a method like this, but I'd wait # TODO: until a third tool with multiple outputs appears before porting this to utils. return utils.FilePath( f"{dataset1Name}_vs_{dataset2Name}" + (f" ({details})" if details else ""), # ^^^ yes this string is built every time even if the form is the same for the same 2 datasets in # all output files: I don't care, this was never the performance bottleneck of the tool and # there is no other net gain in saving and re-using the built string. ext, prefix = "result") FIELD_NOT_AVAILABLE = '/' def writeToCsv(rows: List[list], fieldNames :List[str], outPath :utils.FilePath) -> None: fieldsAmt = len(fieldNames) with open(outPath.show(), "w", newline = "") as fd: writer = csv.DictWriter(fd, fieldnames = fieldNames, delimiter = '\t') writer.writeheader() for row in rows: sizeMismatch = fieldsAmt - len(row) if sizeMismatch > 0: row.extend([FIELD_NOT_AVAILABLE] * sizeMismatch) writer.writerow({ field : data for field, data in zip(fieldNames, row) }) OldEnrichedScores = Dict[str, List[Union[float, FoldChange]]] #TODO: try to use Tuple whenever possible def writeTabularResult(enrichedScores : OldEnrichedScores, outPath :utils.FilePath) -> None: fieldNames = ["ids", "P_Value", "fold change"] fieldNames.extend(["average_1", "average_2"]) writeToCsv([ [reactId] + values for reactId, values in enrichedScores.items() ], fieldNames, outPath) def temp_thingsInCommon(tmp :Dict[str, List[Union[float, FoldChange]]], core_map :ET.ElementTree, max_z_score :float, dataset1Name :str, dataset2Name = "rest") -> None: # this function compiles the things always in common between comparison modes after enrichment. # TODO: organize, name better. writeTabularResult(tmp, buildOutputPath(dataset1Name, dataset2Name, details = "Tabular Result", ext = utils.FileFormat.TSV)) for reactId, enrichData in tmp.items(): tmp[reactId] = tuple(enrichData) applyFluxesEnrichmentToMap(tmp, core_map, max_z_score) def computePValue(dataset1Data: List[float], dataset2Data: List[float]) -> Tuple[float, float]: """ Computes the statistical significance score (P-value) of the comparison between coherent data from two datasets. The data is supposed to, in both datasets: - be related to the same reaction ID; - be ordered by sample, such that the item at position i in both lists is related to the same sample or cell line. Args: dataset1Data : data from the 1st dataset. dataset2Data : data from the 2nd dataset. Returns: tuple: (P-value, Z-score) - P-value from a Kolmogorov-Smirnov test on the provided data. - Z-score of the difference between means of the two datasets. """ # Perform Kolmogorov-Smirnov test ks_statistic, p_value = st.ks_2samp(dataset1Data, dataset2Data) # Calculate means and standard deviations mean1 = np.mean(dataset1Data) mean2 = np.mean(dataset2Data) std1 = np.std(dataset1Data, ddof=1) std2 = np.std(dataset2Data, ddof=1) n1 = len(dataset1Data) n2 = len(dataset2Data) # Calculate Z-score z_score = (mean1 - mean2) / np.sqrt((std1**2 / n1) + (std2**2 / n2)) return p_value, z_score def compareDatasetPair(dataset1Data :List[List[float]], dataset2Data :List[List[float]], ids :List[str]) -> Tuple[Dict[str, List[Union[float, FoldChange]]], float]: #TODO: the following code still suffers from "dumbvarnames-osis" tmp :Dict[str, List[Union[float, FoldChange]]] = {} count = 0 max_z_score = 0 for l1, l2 in zip(dataset1Data, dataset2Data): reactId = ids[count] count += 1 if not reactId: continue # we skip ids that have already been processed try: p_value, z_score = computePValue(l1, l2) avg1 = sum(l1) / len(l1) avg2 = sum(l2) / len(l2) avg = fold_change(avg1, avg2) if not isinstance(z_score, str) and max_z_score < abs(z_score): max_z_score = abs(z_score) tmp[reactId] = [float(p_value), avg, z_score, avg1, avg2] except (TypeError, ZeroDivisionError): continue return tmp, max_z_score def computeEnrichment(metabMap :ET.ElementTree, class_pat :Dict[str, List[List[float]]], ids :List[str]) -> None: """ Compares clustered data based on a given comparison mode and applies enrichment-based styling on the provided metabolic map. Args: metabMap : SVG map to modify. class_pat : the clustered data. ids : ids for data association. Returns: None Raises: sys.exit : if there are less than 2 classes for comparison Side effects: metabMap : mut ids : mut """ class_pat = { k.strip() : v for k, v in class_pat.items() } #TODO: simplfy this stuff vvv and stop using sys.exit (raise the correct utils error) if (not class_pat) or (len(class_pat.keys()) < 2): sys.exit('Execution aborted: classes provided for comparisons are less than two\n') if ARGS.comparison == "manyvsmany": for i, j in it.combinations(class_pat.keys(), 2): #TODO: these 2 functions are always called in pair and in this order and need common data, # some clever refactoring would be appreciated. comparisonDict, max_z_score = compareDatasetPair(class_pat.get(i), class_pat.get(j), ids) temp_thingsInCommon(comparisonDict, metabMap, max_z_score, i, j) elif ARGS.comparison == "onevsrest": for single_cluster in class_pat.keys(): t :List[List[List[float]]] = [] for k in class_pat.keys(): if k != single_cluster: t.append(class_pat.get(k)) rest :List[List[float]] = [] for i in t: rest = rest + i comparisonDict, max_z_score = compareDatasetPair(class_pat.get(single_cluster), rest, ids) temp_thingsInCommon(comparisonDict, metabMap, max_z_score, single_cluster) elif ARGS.comparison == "onevsmany": controlItems = class_pat.get(ARGS.control) for otherDataset in class_pat.keys(): if otherDataset == ARGS.control: continue comparisonDict, max_z_score = compareDatasetPair(controlItems, class_pat.get(otherDataset), ids) temp_thingsInCommon(comparisonDict, metabMap, max_z_score, ARGS.control, otherDataset) def createOutputMaps(dataset1Name :str, dataset2Name :str, core_map :ET.ElementTree) -> None: svgFilePath = buildOutputPath(dataset1Name, dataset2Name, details = "SVG Map", ext = utils.FileFormat.SVG) utils.writeSvg(svgFilePath, core_map) if ARGS.generate_pdf: pngPath = buildOutputPath(dataset1Name, dataset2Name, details = "PNG Map", ext = utils.FileFormat.PNG) pdfPath = buildOutputPath(dataset1Name, dataset2Name, details = "PDF Map", ext = utils.FileFormat.PDF) convert_to_pdf(svgFilePath, pngPath, pdfPath) if not ARGS.generate_svg: os.remove(svgFilePath.show()) ClassPat = Dict[str, List[List[float]]] def getClassesAndIdsFromDatasets(datasetsPaths :List[str], datasetPath :str, classPath :str, names :List[str]) -> Tuple[List[str], ClassPat]: # TODO: I suggest creating dicts with ids as keys instead of keeping class_pat and ids separate, # for the sake of everyone's sanity. class_pat :ClassPat = {} if ARGS.option == 'datasets': num = 1 #TODO: the dataset naming function could be a generator for path, name in zip(datasetsPaths, names): name = name_dataset(name, num) resolve_rules_float, ids = getDatasetValues(path, name) if resolve_rules_float != None: class_pat[name] = list(map(list, zip(*resolve_rules_float.values()))) num += 1 elif ARGS.option == "dataset_class": classes = read_dataset(classPath, "class") classes = classes.astype(str) resolve_rules_float, ids = getDatasetValues(datasetPath, "Dataset Class (not actual name)") if resolve_rules_float != None: class_pat = split_class(classes, resolve_rules_float) return ids, class_pat #^^^ TODO: this could be a match statement over an enum, make it happen future marea dev with python 3.12! (it's why I kept the ifs) #TODO: create these damn args as FilePath objects def getDatasetValues(datasetPath :str, datasetName :str) -> Tuple[ClassPat, List[str]]: """ Opens the dataset at the given path and extracts the values (expected nullable numerics) and the IDs. Args: datasetPath : path to the dataset datasetName (str): dataset name, used in error reporting Returns: Tuple[ClassPat, List[str]]: values and IDs extracted from the dataset """ dataset = read_dataset(datasetPath, datasetName) IDs = pd.Series.tolist(dataset.iloc[:, 0].astype(str)) dataset = dataset.drop(dataset.columns[0], axis = "columns").to_dict("list") return { id : list(map(utils.Float("Dataset values, not an argument"), values)) for id, values in dataset.items() }, IDs def jet_colormap(value): """ Generate an RGB color based on a single numeric value using a colormap similar to MATLAB's 'jet'. Args: value (float): A numeric value to be mapped to a color. Returns: numpy.ndarray: An array of RGB color components (in the range [0, 1]). """ # Ensure value is a single numeric value value = abs(value) # Define the red, green, and blue color components red = np.clip(1.5 - np.abs(4 * (value - 0.75)), 0, 1) green = np.clip(1.5 - np.abs(4 * (value - 0.5)), 0, 1) blue = np.clip(1.5 - np.abs(4 * (value - 0.25)), 0, 1) # Combine the color components into an RGB array rgb = np.array([red, green, blue]) return rgb def rgb_to_hex(rgb): """ Convert RGB values (0-1 range) to hexadecimal color format. Args: rgb (numpy.ndarray): An array of RGB color components (in the range [0, 1]). Returns: str: The color in hexadecimal format (e.g., '#ff0000' for red). """ # Convert RGB values (0-1 range) to hexadecimal format rgb = (rgb * 255).astype(int) return '#{:02x}{:02x}{:02x}'.format(rgb[0], rgb[1], rgb[2]) def save_colormap_image(min_value:float, max_value:float, path:str): """ Create and save an image of the colormap showing the gradient and its range. Args: min_value (float): The minimum value of the colormap range. max_value (float): The maximum value of the colormap range. filename (str): The filename for saving the image. """ # Define image size and create a new image width = 256 height = 50 image = Image.new('RGB', (width, height), color='white') draw = ImageDraw.Draw(image) # Create the gradient for x in range(width): value = (x / (width - 1)) * (max_value - min_value) + min_value color_arr = jet_colormap((value - min_value) / (max_value - min_value)) color = tuple(int(c * 255) for c in color_arr) draw.line([(x, 0), (x, height)], fill=color) # Add text for min and max values font = ImageFont.load_default() draw.text((10, height - 20), f'{min_value:.2f}', fill='white', font=font) draw.text((width - 50, height - 20), f'{max_value:.2f}', fill='white', font=font) # Save the image image.save(path.show()) pass def computeEnrichmentMeanMedian(metabMap: ET.ElementTree, class_pat: Dict[str, List[List[float]]], ids: List[str]) -> None: """ Compute and visualize the metabolic map based on mean and median of the input fluxes. The fluxes are normalised across classes/datasets and visualised using the jet colormap. Args: metabMap (ET.ElementTree): An XML tree representing the metabolic map. class_pat (Dict[str, List[List[float]]]): A dictionary where keys are class names and values are lists of enrichment values. ids (List[str]): A list of reaction IDs to be used for coloring arrows. Returns: None """ # Create copies only if they are needed metabMap_mean = copy.deepcopy(metabMap) metabMap_median = copy.deepcopy(metabMap) # Compute medians and means medians = {key: np.median(np.array(value), axis=1) for key, value in class_pat.items()} means = {key: np.mean(np.array(value), axis=1) for key, value in class_pat.items()} # Normalize medians and means max_flux_medians = max(np.max(np.abs(arr)) for arr in medians.values()) max_flux_means = max(np.max(np.abs(arr)) for arr in means.values()) min_flux_medians = min(np.min(np.abs(arr)) for arr in medians.values()) min_flux_means = min(np.min(np.abs(arr)) for arr in means.values()) medians = {key: median / max_flux_medians for key, median in medians.items()} means = {key: mean / max_flux_means for key, mean in means.items()} save_colormap_image(min_flux_medians, max_flux_medians, utils.FilePath("Color map median", ext=utils.FileFormat.PNG, prefix="result")) save_colormap_image(min_flux_means, max_flux_means, utils.FilePath("Color map mean", ext=utils.FileFormat.PNG, prefix="result")) for key in class_pat: # Create color mappings for median and mean colors_median = {rxn_id: rgb_to_hex(jet_colormap(medians[key][i])) for i, rxn_id in enumerate(ids)} colors_mean = {rxn_id: rgb_to_hex(jet_colormap(means[key][i])) for i, rxn_id in enumerate(ids)} for i, rxn_id in enumerate(ids): isNegative = False if(medians[key][i] <0): isNegative = True # Apply median arrows apply_arrow(metabMap_median, rxn_id, colors_median[rxn_id], isNegative) # Apply mean arrows apply_arrow(metabMap_mean, rxn_id, colors_mean[rxn_id], isNegative) # Save and convert the SVG files save_and_convert(metabMap_mean, "mean", key) save_and_convert(metabMap_median, "median", key) def apply_arrow(metabMap, rxn_id, color, isNegative): """ Apply an arrow to a specific reaction in the metabolic map with a given color. Args: metabMap (ET.ElementTree): An XML tree representing the metabolic map. rxn_id (str): The ID of the reaction to which the arrow will be applied. color (str): The color of the arrow in hexadecimal format. Returns: None """ arrow = Arrow(width=5, col=color) arrow.styleReactionElements_custom(metabMap, rxn_id, isNegative) pass def save_and_convert(metabMap, map_type, key): """ Save the metabolic map as an SVG file and optionally convert it to PNG and PDF formats. Args: metabMap (ET.ElementTree): An XML tree representing the metabolic map. map_type (str): The type of map ('mean' or 'median'). key (str): The key identifying the specific map. Returns: None """ svgFilePath = utils.FilePath(f"SVG Map {map_type} - {key}", ext=utils.FileFormat.SVG, prefix="result") utils.writeSvg(svgFilePath, metabMap) if ARGS.generate_pdf: pngPath = utils.FilePath(f"PNG Map {map_type} - {key}", ext=utils.FileFormat.PNG, prefix="result") pdfPath = utils.FilePath(f"PDF Map {map_type} - {key}", ext=utils.FileFormat.PDF, prefix="result") convert_to_pdf(svgFilePath, pngPath, pdfPath) if not ARGS.generate_svg: os.remove(svgFilePath.show()) ############################ MAIN ############################################# def main() -> None: """ Initializes everything and sets the program in motion based on the fronted input arguments. Returns: None Raises: sys.exit : if a user-provided custom map is in the wrong format (ET.XMLSyntaxError, ET.XMLSchemaParseError) """ global ARGS ARGS = process_args() if os.path.isdir('result') == False: os.makedirs('result') core_map :ET.ElementTree = ARGS.choice_map.getMap( ARGS.tool_dir, utils.FilePath.fromStrPath(ARGS.custom_map) if ARGS.custom_map else None) # TODO: ^^^ ugly but fine for now, the argument is None if the model isn't custom because no file was given. # getMap will None-check the customPath and panic when the model IS custom but there's no file (good). A cleaner # solution can be derived from my comment in FilePath.fromStrPath ids, class_pat = getClassesAndIdsFromDatasets(ARGS.input_datas_fluxes, ARGS.input_data_fluxes, ARGS.input_class_fluxes, ARGS.names_fluxes) if(ARGS.choice_map == utils.Model.HMRcore): temp_map = utils.Model.HMRcore_no_legend computeEnrichmentMeanMedian(temp_map.getMap(ARGS.tool_dir), class_pat, ids) elif(ARGS.choice_map == utils.Model.ENGRO2): temp_map = utils.Model.ENGRO2_no_legend computeEnrichmentMeanMedian(temp_map.getMap(ARGS.tool_dir), class_pat, ids) else: computeEnrichmentMeanMedian(core_map, class_pat, ids) computeEnrichment(core_map, class_pat, ids) # create output files: TODO: this is the same comparison happening in "maps", find a better way to organize this if ARGS.comparison == "manyvsmany": for i, j in it.combinations(class_pat.keys(), 2): createOutputMaps(i, j, core_map) return if ARGS.comparison == "onevsrest": for single_cluster in class_pat.keys(): createOutputMaps(single_cluster, "rest", core_map) return for otherDataset in class_pat.keys(): if otherDataset != ARGS.control: createOutputMaps(i, j, core_map) if not ERRORS: return utils.logWarning( f"The following reaction IDs were mentioned in the dataset but weren't found in the map: {ERRORS}", ARGS.out_log) print('Execution succeded') ############################################################################### if __name__ == "__main__": main()