Source code for sas.sasgui.perspectives.pr.inversion_state

"""
    Handling of P(r) inversion states
"""
################################################################################
#This software was developed by the University of Tennessee as part of the
#Distributed Data Analysis of Neutron Scattering Experiments (DANSE)
#project funded by the US National Science Foundation.
#
#See the license text in license.txt
#
#copyright 2009, University of Tennessee
################################################################################


import time
import os
import sys
import logging
from lxml import etree
from sas.sasgui.guiframe.dataFitting import Data1D
from sas.sascalc.dataloader.readers.cansas_reader import Reader as CansasReader
from sas.sascalc.dataloader.readers.cansas_reader import get_content

logger = logging.getLogger(__name__)

PRNODE_NAME = 'pr_inversion'
CANSAS_NS = "cansas1d/1.0"

# Translation of names between stored and object data
## List of P(r) inversion inputs
in_list = [["nterms", "nfunc"],
           ["d_max", "d_max"],
           ["alpha", "alpha"],
           ["slit_width", "width"],
           ["slit_height", "height"],
           ["qmin", "qmin"],
           ["qmax", "qmax"],
           ["estimate_bck", "estimate_bck"],
           ["bck_value", "bck_value"]]

## List of P(r) inversion outputs
out_list = [["elapsed", "elapsed"],
            ["rg", "rg"],
            ["iq0", "iq0"],
            ["bck", "bck"],
            ["chi2", "chi2"],
            ["osc", "osc"],
            ["pos", "pos"],
            ["pos_err", "pos_err"],
            ["alpha_estimate", "alpha_estimate"],
            ["nterms_estimate", "nterms_estimate"]]

[docs]class InversionState(object): """ Class to hold the state information of the InversionControl panel. """ def __init__(self): """ Default values """ # Input self.file = None self.estimate_bck = False self.timestamp = time.time() self.bck_value = 0.0 # Inversion parameters self.nfunc = None self.d_max = None self.alpha = None # Slit parameters self.height = None self.width = None # Q range self.qmin = None self.qmax = None # Outputs self.elapsed = None self.rg = None self.iq0 = None self.bck = None self.chi2 = None self.osc = None self.pos = None self.pos_err = None # Estimates self.alpha_estimate = None self.nterms_estimate = None # Data self.q = None self.iq_obs = None self.iq_calc = None # Coefficients self.coefficients = None self.covariance = None def __str__(self): """ Pretty print :return: string representing the state """ state = "File: %s\n" % self.file state += "Timestamp: %s\n" % self.timestamp state += "Estimate bck: %s\n" % str(self.estimate_bck) state += "Bck Value: %s\n" % str(self.bck_value) state += "No. terms: %s\n" % str(self.nfunc) state += "D_max: %s\n" % str(self.d_max) state += "Alpha: %s\n" % str(self.alpha) state += "Slit height: %s\n" % str(self.height) state += "Slit width: %s\n" % str(self.width) state += "Qmin: %s\n" % str(self.qmin) state += "Qmax: %s\n" % str(self.qmax) state += "\nEstimates:\n" state += " Alpha: %s\n" % str(self.alpha_estimate) state += " Nterms: %s\n" % str(self.nterms_estimate) state += "\nOutputs:\n" state += " Elapsed: %s\n" % str(self.elapsed) state += " Rg: %s\n" % str(self.rg) state += " I(q=0): %s\n" % str(self.iq0) state += " Bck: %s\n" % str(self.bck) state += " Chi^2: %s\n" % str(self.chi2) state += " Oscillation:%s\n" % str(self.osc) state += " Positive: %s\n" % str(self.pos) state += " 1-sigma pos:%s\n" % str(self.pos_err) return state
[docs] def toXML(self, file="pr_state.prv", doc=None, entry_node=None): """ Writes the state of the InversionControl panel to file, as XML. Compatible with standalone writing, or appending to an already existing XML document. In that case, the XML document is required. An optional entry node in the XML document may also be given. :param file: file to write to :param doc: XML document object [optional] :param entry_node: XML node within the XML document at which we will append the data [optional] """ #TODO: Get this to work from xml.dom.minidom import getDOMImplementation # Check whether we have to write a standalone XML file if doc is None: impl = getDOMImplementation() doc_type = impl.createDocumentType(PRNODE_NAME, "1.0", "1.0") newdoc = impl.createDocument(None, PRNODE_NAME, doc_type) top_element = newdoc.documentElement else: # We are appending to an existing document newdoc = doc top_element = newdoc.createElement(PRNODE_NAME) if entry_node is None: newdoc.documentElement.appendChild(top_element) else: entry_node.appendChild(top_element) attr = newdoc.createAttribute("version") attr.nodeValue = '1.0' top_element.setAttributeNode(attr) # File name element = newdoc.createElement("filename") if self.file is not None: element.appendChild(newdoc.createTextNode(str(self.file))) else: element.appendChild(newdoc.createTextNode(str(file))) top_element.appendChild(element) element = newdoc.createElement("timestamp") element.appendChild(newdoc.createTextNode(time.ctime(self.timestamp))) attr = newdoc.createAttribute("epoch") attr.nodeValue = str(self.timestamp) element.setAttributeNode(attr) top_element.appendChild(element) # Inputs inputs = newdoc.createElement("inputs") top_element.appendChild(inputs) for item in in_list: element = newdoc.createElement(item[0]) element.appendChild(newdoc.createTextNode(str(getattr(self, item[1])))) inputs.appendChild(element) # Outputs outputs = newdoc.createElement("outputs") top_element.appendChild(outputs) for item in out_list: element = newdoc.createElement(item[0]) element.appendChild(newdoc.createTextNode(str(getattr(self, item[1])))) outputs.appendChild(element) # Save output coefficients and its covariance matrix element = newdoc.createElement("coefficients") element.appendChild(newdoc.createTextNode(str(self.coefficients))) outputs.appendChild(element) element = newdoc.createElement("covariance") element.appendChild(newdoc.createTextNode(str(self.covariance))) outputs.appendChild(element) # Save the file if doc is None: fd = open(file, 'w') fd.write(newdoc.toprettyxml()) fd.close() return None else: return newdoc
[docs] def fromXML(self, file=None, node=None): """ Load a P(r) inversion state from a file :param file: .prv file :param node: node of a XML document to read from """ if file is not None: msg = "InversionState no longer supports non-CanSAS" msg += " format for P(r) files" raise RuntimeError, msg if node.get('version') and node.get('version') == '1.0': # Get file name entry = get_content('ns:filename', node) if entry is not None: self.file = entry.text.strip() # Get time stamp entry = get_content('ns:timestamp', node) if entry is not None and entry.get('epoch'): try: self.timestamp = float(entry.get('epoch')) except: msg = "InversionState.fromXML: Could not read " msg += "timestamp\n %s" % sys.exc_value logger.error(msg) # Parse inversion inputs entry = get_content('ns:inputs', node) if entry is not None: for item in in_list: input_field = get_content('ns:%s' % item[0], entry) if input_field is not None: try: setattr(self, item[1], float(input_field.text.strip())) except: setattr(self, item[1], None) input_field = get_content('ns:estimate_bck', entry) if input_field is not None: try: self.estimate_bck = input_field.text.strip() == 'True' except: self.estimate_bck = False # Parse inversion outputs entry = get_content('ns:outputs', node) if entry is not None: # Output parameters (scalars) for item in out_list: input_field = get_content('ns:%s' % item[0], entry) if input_field is not None: try: setattr(self, item[1], float(input_field.text.strip())) except: setattr(self, item[1], None) # Look for coefficients # Format is [value, value, value, value] coeff = get_content('ns:coefficients', entry) if coeff is not None: # Remove brackets c_values = coeff.text.strip().replace('[', '') c_values = c_values.replace(']', '') toks = c_values.split() self.coefficients = [] for c in toks: try: self.coefficients.append(float(c)) except: # Bad data, skip. We will count the number of # coefficients at the very end and deal with # inconsistencies then. pass # Sanity check if not len(self.coefficients) == self.nfunc: # Inconsistent number of coefficients. # Don't keep the data. err_msg = "InversionState.fromXML: inconsistant " err_msg += "number of coefficients: " err_msg += "%d %d" % (len(self.coefficients), self.nfunc) logger.error(err_msg) self.coefficients = None # Look for covariance matrix # Format is [ [value, value], [value, value] ] coeff = get_content('ns:covariance', entry) if coeff is not None: # Parse rows rows = coeff.text.strip().split('[') self.covariance = [] for row in rows: row = row.strip() if len(row) == 0: continue # Remove end bracket row = row.replace(']', '') c_values = row.split() cov_row = [] for c in c_values: try: cov_row.append(float(c)) except: # Bad data, skip. We will count the number of # coefficients at the very end and deal with # inconsistencies then. pass # Sanity check: check the number of entries in the row if len(cov_row) == self.nfunc: self.covariance.append(cov_row) # Sanity check: check the number of rows in the covariance # matrix if not len(self.covariance) == self.nfunc: # Inconsistent dimensions of the covariance matrix. # Don't keep the data. err_msg = "InversionState.fromXML: " err_msg += "inconsistant dimensions of the " err_msg += " covariance matrix: " err_msg += "%d %d" % (len(self.covariance), self.nfunc) logger.error(err_msg) self.covariance = None
[docs]class Reader(CansasReader): """ Class to load a .prv P(r) inversion file """ ## File type type_name = "P(r)" ## Wildcards type = ["P(r) files (*.prv)|*.prv", "SASView files (*.svs)|*.svs"] ## List of allowed extensions ext = ['.prv', '.PRV', '.svs', '.SVS'] def __init__(self, call_back, cansas=True): """ Initialize the call-back method to be called after we load a file :param call_back: call-back method :param cansas: True = files will be written/read in CanSAS format False = write CanSAS format """ ## Call back method to be executed after a file is read self.call_back = call_back ## CanSAS format flag self.cansas = cansas self.state = None
[docs] def read(self, path): """ Load a new P(r) inversion state from file :param path: file path :return: None """ if self.cansas: return self._read_cansas(path) else: return self._read_standalone(path)
def _read_standalone(self, path): """ Load a new P(r) inversion state from file. The P(r) node is assumed to be the top element. :param path: file path :return: None """ # Read the new state from file state = InversionState() state.fromXML(file=path) # Call back to post the new state self.state = state #self.call_back(state) return None def _parse_prstate(self, entry): """ Read a p(r) inversion result from an XML node :param entry: XML node to read from :return: InversionState object """ state = None # Locate the P(r) node try: nodes = entry.xpath('ns:%s' % PRNODE_NAME, namespaces={'ns': CANSAS_NS}) if nodes != []: # Create an empty state state = InversionState() state.fromXML(node=nodes[0]) except: msg = "XML document does not contain P(r) " msg += "information.\n %s" % sys.exc_value logger.info(msg) return state def _read_cansas(self, path): """ Load data and P(r) information from a CanSAS XML file. :param path: file path :return: Data1D object if a single SASentry was found, or a list of Data1D objects if multiple entries were found, or None of nothing was found :raise RuntimeError: when the file can't be opened :raise ValueError: when the length of the data vectors are inconsistent """ output = [] if os.path.isfile(path): basename = os.path.basename(path) root, extension = os.path.splitext(basename) #TODO: eventually remove the check for .xml once # the P(r) writer/reader is truly complete. if extension.lower() in self.ext or extension.lower() == '.xml': tree = etree.parse(path, parser=etree.ETCompatXMLParser()) # Check the format version number # Specifying the namespace will take care of the file #format version root = tree.getroot() entry_list = root.xpath('/ns:SASroot/ns:SASentry', namespaces={'ns': CANSAS_NS}) for entry in entry_list: prstate = self._parse_prstate(entry) #prstate could be None when .svs file is loaded #in this case, skip appending to output if prstate is not None: sas_entry, _ = self._parse_entry(entry) sas_entry.meta_data['prstate'] = prstate sas_entry.filename = prstate.file output.append(sas_entry) else: raise RuntimeError, "%s is not a file" % path # Return output consistent with the loader's api if len(output) == 0: return None elif len(output) == 1: # Call back to post the new state self.call_back(output[0].meta_data['prstate'], datainfo=output[0]) #self.state = output[0].meta_data['prstate'] return output[0] else: return output
[docs] def write(self, filename, datainfo=None, prstate=None): """ Write the content of a Data1D as a CanSAS XML file :param filename: name of the file to write :param datainfo: Data1D object :param prstate: InversionState object """ # Sanity check if self.cansas: doc = self.write_toXML(datainfo, prstate) # Write the XML document fd = open(filename, 'w') fd.write(doc.toprettyxml()) fd.close() else: prstate.toXML(file=filename)
[docs] def write_toXML(self, datainfo=None, state=None): """ Write toXML, a helper for write() : return: xml doc """ if datainfo is None: datainfo = Data1D(x=[], y=[]) elif not issubclass(datainfo.__class__, Data1D): msg = "The cansas writer expects a Data1D " msg += "instance: %s" % str(datainfo.__class__.__name__) raise RuntimeError, msg # Create basic XML document doc, sasentry = self._to_xml_doc(datainfo) # Add the invariant information to the XML document if state is not None: doc = state.toXML(doc=doc, entry_node=sasentry) return doc