def __init__(self, WORK_DIR):
        #ch.create_config(open(CONFIG_FNAME,'w'))
        #Collect config file entries:
        #self.config_dict = ch.read_config(CONFIG_FNAME)
        #print(self.config_dict)

        #self.work_dir = self.ConfigParam['workdir']
        #self.work_dir='workspace'
        self.work_dir = WORK_DIR

        # Look for workspace, and if none exists create one:
        #if not os.path.exists(self.work_dir):
        #    os.makedirs(self.work_dir) # Create work space

        # Collect user arguments into a dictionary:
        self.parsed_dict = ap.parse_args()

        #self.user_seed=int(self.parsed_dict['user_seed'])

        cfg_fname = self.parsed_dict['cfg_fname']
        if (not cfg_fname):
            cfg_fname = CONFIG_FNAME
        cfg_path = os.path.dirname(cfg_fname)
        if (not cfg_path or cfg_path == "."):
            cfg_path = self.work_dir
        self.cfg_fname = cfg_path + '/' + basename(cfg_fname)
        #self.cfg_fname=self.work_dir+'/'+cfg_fname
        #self.config_dict = ch.read_config(CONFIG_FNAME)
        self.config_dict = ch.read_config(self.cfg_fname)
        #self.cfg_fname=self.work_dir+'/'+basename(cfg_fname)

        #Update the internal SEED, if user supplies this:
        if ((int(self.parsed_dict['SEED'])) !=
            (int(self.config_dict['SEED']))):
            self.config_dict['SEED'] = self.parsed_dict['SEED']

        #update the config_dict with USER_SEED from commandline:
        if ((int(self.parsed_dict['user_seed'])) !=
            (int(self.config_dict['USER_SEED']))):
            self.config_dict['USER_SEED'] = self.parsed_dict['user_seed']
        #Get .tpo filename:
        tpo_fname = self.parsed_dict['tpo_fname']
        #tpo_path=os.path.dirname(self.parsed_dict['tpo_fname'])
        #
        #fn_prefix=(basename(tpo_fname)).strip().\
        #          split(self.config_dict['TOPOLOGY_FNAME_EXTENSION'])[0]
        fn_prefix=tpo_fname.strip().\
                  split(self.config_dict['TOPOLOGY_FNAME_EXTENSION'])[0]

        # Get .tpo filename with absolute path:
        #if (not tpo_path or tpo_path=="."):
        #    tpo_path=self.work_dir
        #self.tpo_fname=tpo_path+'/'+basename(tpo_fname)
        self.tpo_fname = self.work_dir + '/' + tpo_fname

        # Get .prs filename with path:
        prs_fname = self.parsed_dict['prs_fname']
        # if .prs file is not supplied, create file name for it:
        if not prs_fname:
            self.prs_fname=self.work_dir+'/'+\
                           fn_prefix+\
                           self.config_dict['PARAMETER_RANGE_FNAME_EXTENSION']
        else:  #otherwise, append working directory with it:
            self.prs_fname = self.work_dir + '/' + prs_fname

        # Get .exp filename with path:
        self.exp_fname = self.work_dir + '/' + self.parsed_dict['exp_fname']

        # Get .params filename with path:
        self.params_input_fname = self.work_dir + '/' + self.parsed_dict[
            'params_input_fname']
        # threshold test results
        self.edge_stat_fname = self.work_dir + '/' + self.parsed_dict[
            'outfile'] + '.edge.stat.txt'

        # Create other output filenames based on .tpo file name prefix:
        self.cfg_fname=self.work_dir+fn_prefix+\
                       self.config_dict['CONFIG_FNAME_EXTENSION']
        self.params_fname=self.work_dir+'/'+\
                          fn_prefix+\
                          self.config_dict['PARAMETER_FNAME_EXTENSION']
        self.LCtrace_fname=self.work_dir+'/'+\
                           fn_prefix+\
                           LIMIT_CYLCE_FNAME_SUFFIX
        self.prs_fname_bak=self.work_dir+'/'+\
                           fn_prefix+\
                           self.config_dict[\
                           'PARAMETER_RANGE_FNAME_EXTENSION']+".bak"

        #input file name to read stable activations:
        self.fname_states_act = self.work_dir + '/' + fn_prefix + ".states.txt"

        #output files for C:
        #to write stable states:
        self.fname_states = self.work_dir + '/' + fn_prefix + ".states.exp.txt"
        self.fname_limitcycles = self.work_dir + '/' + fn_prefix + ".limitcycles.exp.txt"
        self.fname_summary = self.work_dir + '/' + fn_prefix + ".summary.txt"

        #create dictionary for file names to be used in C simulation:
        self.fname_dict_simu = OrderedDict()
        self.fname_dict_simu['FNAME_STATES'] = self.fname_states
        self.fname_dict_simu['FNAME_LIMITCYCLES'] = self.fname_limitcycles
        self.fname_dict_simu['FNAME_SUMMARY'] = self.fname_summary

        #file names for parameter ranges:MPR, DNR, TSH, HCO, and FCH:
        self.fname_dict_nodeprs = OrderedDict()
        self.fname_dict_nodeprs[
            'mpr'] = self.work_dir + '/' + fn_prefix + ".mpr.prs"
        self.fname_dict_nodeprs[
            'dnr'] = self.work_dir + '/' + fn_prefix + ".dnr.prs"

        self.fname_dict_edgeprs = OrderedDict()
        self.fname_dict_edgeprs[
            'tsh'] = self.work_dir + '/' + fn_prefix + ".tsh.prs"
        self.fname_dict_edgeprs[
            'hco'] = self.work_dir + '/' + fn_prefix + ".hco.prs"
        self.fname_dict_edgeprs[
            'fch'] = self.work_dir + '/' + fn_prefix + ".fch.prs"

        #output file names for parameters:MPR, DNR, TSH, HCO, and FCH:
        self.fname_dict_nodeparams = OrderedDict()
        self.fname_dict_nodeparams[
            'mpr'] = self.work_dir + '/' + fn_prefix + ".mpr.exp.txt"
        self.fname_dict_nodeparams[
            'dnr'] = self.work_dir + '/' + fn_prefix + ".dnr.exp.txt"

        self.fname_dict_edgeparams = OrderedDict()
        self.fname_dict_edgeparams[
            'tsh'] = self.work_dir + '/' + fn_prefix + ".tsh.exp.txt"
        self.fname_dict_edgeparams[
            'hco'] = self.work_dir + '/' + fn_prefix + ".hco.exp.txt"
        self.fname_dict_edgeparams[
            'fch'] = self.work_dir + '/' + fn_prefix + ".fch.exp.txt"

        #node_dict - gene/node names:
        self.node_dict = OrderedDict()

        #edge_dict - gene/node names:
        self.edge_dict = OrderedDict()

        #source_dict - maps target to source(s):
        self.source_dict = defaultdict(lambda: defaultdict(list))
        #self.source_dict=defaultdict(lambda: OrderedDict())

        #target_dict - maps source to target(s):
        self.target_dict = defaultdict(lambda: defaultdict(list))
        #self.target_dict=defaultdict(lambda: OrderedDict())

        #master_dict - maps each equation to a unique index:
        #Key:index
        #Value:(source,target,regulation type,TSH,HLC,FCH)
        #self.master_dict=defaultdict(list)
        #self.master_dict=defaultdict(tuple)
        self.master_dict = OrderedDict()

        #special data structures for C-interface:
        #node_id_dict - maps each gene/node to a unique id:
        self.node_id_dict = OrderedDict()

        #edge_id_dict - maps each equation to a unique id:
        self.edge_id_dict = OrderedDict()

        #edge_source_dict - maps each edge index to its source id:
        self.edge_source_dict = OrderedDict()

        #edge_target_dict - maps each edge index to its target id:
        self.edge_target_dict = OrderedDict()

        #edge_type_dict - maps each edge index to its type id:
        self.edge_type_dict = OrderedDict()

        return None
Exemple #2
0
def main():
    import ctypes
    clib = ctypes.cdll.LoadLibrary('./analyzer_clib.so')

    model_to_inspect = 2

    parsed_dict = ap.parse_args()
    print("here:")
    print("tpo file name: ", parsed_dict['fname_tpo'])
    print("EXP file name: ", parsed_dict['fname_exp'])
    print("TSH file name: ", parsed_dict['fname_params'])

    tpo_fname = parsed_dict['fname_tpo']

    tpo_path = os.path.dirname(parsed_dict['fname_tpo'])

    print(tpo_path)
    #fn_prefix=(basename(tpo_fname)).strip().\
    #    split(self.config_dict['TOPOLOGY_FNAME_EXTENSION'])[0]

    # Get .tpo filename with absolute path:
    print(CUR_DIR)
    if (not tpo_path or tpo_path == "."):
        tpo_path = CUR_DIR
    tpo_fname = tpo_path + '/' + tpo_fname

    tmp_fname = parsed_dict['fname_exp']
    exp_fname = CUR_DIR + '/' + parsed_dict['fname_exp']
    params_fname = CUR_DIR + '/' + parsed_dict['fname_params']

    CONFIG_FNAME = CUR_DIR + '/' + 'racipe.cfg'
    config_dict = ch.read_config(CONFIG_FNAME)
    build_network(tpo_fname, config_dict)

    sys.exit(0)
    #tpo_fname=self.parsed_dict['tpo_fname']

    #create an instance of Network class:
    network = nm.Network(CUR_DIR)

    #load network topology and parameter ranges:
    network.build_network()

    #obtain racipe config:
    config_dict = network.get_config_dict()
    SEED = int(config_dict['SEED'])
    user_seed = int(config_dict['USER_SEED'])
    #set the seed for model generation:
    clib.set_seed(ctypes.c_int(SEED * 2), ctypes.c_int(user_seed))

    ma.inspect_model(network, model_to_inspect)
    sys.exit(0)

    SEED = int(config_dict['SEED'])
    user_seed = int(config_dict['USER_SEED'])

    clib = ctypes.cdll.LoadLibrary('./simulation_clib.so')
    clib.randu.argtypes = (ctypes.c_double, ctypes.c_double)
    clib.randu.restype = ctypes.c_double
    #clib.set_seed(ctypes.c_int(SEED))
    #set seed for estimation of parameter ranges:
    clib.set_seed(ctypes.c_int(SEED), ctypes.c_int(user_seed))

    mode = network.process_network()

    #generate models:
    if (mode == 'A' or mode == 'P'):
        print('Generating models ...')
        #set seed for generating models:
        #clib.set_seed(ctypes.c_int(SEED*2))
        clib.set_seed(ctypes.c_int(SEED * 2), ctypes.c_int(user_seed))
        #mg.generate_models_usingPython(network)
        mg.generate_models_usingC(network)
    return None