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view DEPENDENCIES/mingw32/Python27/Lib/site-packages/numpy/f2py/auxfuncs.py @ 133:4acb5d8d80b6 tip
Don't fail environmental check if README.md exists (but .txt and no-suffix don't)
| author | Chris Cannam |
|---|---|
| date | Tue, 30 Jul 2019 12:25:44 +0100 |
| parents | 2a2c65a20a8b |
| children |
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#!/usr/bin/env python """ Auxiliary functions for f2py2e. Copyright 1999,2000 Pearu Peterson all rights reserved, Pearu Peterson <pearu@ioc.ee> Permission to use, modify, and distribute this software is given under the terms of the NumPy (BSD style) LICENSE. NO WARRANTY IS EXPRESSED OR IMPLIED. USE AT YOUR OWN RISK. $Date: 2005/07/24 19:01:55 $ Pearu Peterson """ from __future__ import division, absolute_import, print_function import pprint import sys import types from functools import reduce from . import __version__ from . import cfuncs f2py_version = __version__.version errmess=sys.stderr.write #outmess=sys.stdout.write show=pprint.pprint options={} debugoptions=[] wrapfuncs = 1 def outmess(t): if options.get('verbose', 1): sys.stdout.write(t) def debugcapi(var): return 'capi' in debugoptions def _isstring(var): return 'typespec' in var and var['typespec']=='character' and (not isexternal(var)) def isstring(var): return _isstring(var) and not isarray(var) def ischaracter(var): return isstring(var) and 'charselector' not in var def isstringarray(var): return isarray(var) and _isstring(var) def isarrayofstrings(var): # leaving out '*' for now so that # `character*(*) a(m)` and `character a(m,*)` # are treated differently. Luckily `character**` is illegal. return isstringarray(var) and var['dimension'][-1]=='(*)' def isarray(var): return 'dimension' in var and (not isexternal(var)) def isscalar(var): return not (isarray(var) or isstring(var) or isexternal(var)) def iscomplex(var): return isscalar(var) and var.get('typespec') in ['complex', 'double complex'] def islogical(var): return isscalar(var) and var.get('typespec')=='logical' def isinteger(var): return isscalar(var) and var.get('typespec')=='integer' def isreal(var): return isscalar(var) and var.get('typespec')=='real' def get_kind(var): try: return var['kindselector']['*'] except KeyError: try: return var['kindselector']['kind'] except KeyError: pass def islong_long(var): if not isscalar(var): return 0 if var.get('typespec') not in ['integer', 'logical']: return 0 return get_kind(var)=='8' def isunsigned_char(var): if not isscalar(var): return 0 if var.get('typespec') != 'integer': return 0 return get_kind(var)=='-1' def isunsigned_short(var): if not isscalar(var): return 0 if var.get('typespec') != 'integer': return 0 return get_kind(var)=='-2' def isunsigned(var): if not isscalar(var): return 0 if var.get('typespec') != 'integer': return 0 return get_kind(var)=='-4' def isunsigned_long_long(var): if not isscalar(var): return 0 if var.get('typespec') != 'integer': return 0 return get_kind(var)=='-8' def isdouble(var): if not isscalar(var): return 0 if not var.get('typespec')=='real': return 0 return get_kind(var)=='8' def islong_double(var): if not isscalar(var): return 0 if not var.get('typespec')=='real': return 0 return get_kind(var)=='16' def islong_complex(var): if not iscomplex(var): return 0 return get_kind(var)=='32' def iscomplexarray(var): return isarray(var) and var.get('typespec') in ['complex', 'double complex'] def isint1array(var): return isarray(var) and var.get('typespec')=='integer' \ and get_kind(var)=='1' def isunsigned_chararray(var): return isarray(var) and var.get('typespec') in ['integer', 'logical']\ and get_kind(var)=='-1' def isunsigned_shortarray(var): return isarray(var) and var.get('typespec') in ['integer', 'logical']\ and get_kind(var)=='-2' def isunsignedarray(var): return isarray(var) and var.get('typespec') in ['integer', 'logical']\ and get_kind(var)=='-4' def isunsigned_long_longarray(var): return isarray(var) and var.get('typespec') in ['integer', 'logical']\ and get_kind(var)=='-8' def issigned_chararray(var): return isarray(var) and var.get('typespec') in ['integer', 'logical']\ and get_kind(var)=='1' def issigned_shortarray(var): return isarray(var) and var.get('typespec') in ['integer', 'logical']\ and get_kind(var)=='2' def issigned_array(var): return isarray(var) and var.get('typespec') in ['integer', 'logical']\ and get_kind(var)=='4' def issigned_long_longarray(var): return isarray(var) and var.get('typespec') in ['integer', 'logical']\ and get_kind(var)=='8' def isallocatable(var): return 'attrspec' in var and 'allocatable' in var['attrspec'] def ismutable(var): return not (not 'dimension' in var or isstring(var)) def ismoduleroutine(rout): return 'modulename' in rout def ismodule(rout): return ('block' in rout and 'module'==rout['block']) def isfunction(rout): return ('block' in rout and 'function'==rout['block']) #def isfunction_wrap(rout): # return wrapfuncs and (iscomplexfunction(rout) or isstringfunction(rout)) and (not isexternal(rout)) def isfunction_wrap(rout): if isintent_c(rout): return 0 return wrapfuncs and isfunction(rout) and (not isexternal(rout)) def issubroutine(rout): return ('block' in rout and 'subroutine'==rout['block']) def issubroutine_wrap(rout): if isintent_c(rout): return 0 return issubroutine(rout) and hasassumedshape(rout) def hasassumedshape(rout): if rout.get('hasassumedshape'): return True for a in rout['args']: for d in rout['vars'].get(a, {}).get('dimension', []): if d==':': rout['hasassumedshape'] = True return True return False def isroutine(rout): return isfunction(rout) or issubroutine(rout) def islogicalfunction(rout): if not isfunction(rout): return 0 if 'result' in rout: a=rout['result'] else: a=rout['name'] if a in rout['vars']: return islogical(rout['vars'][a]) return 0 def islong_longfunction(rout): if not isfunction(rout): return 0 if 'result' in rout: a=rout['result'] else: a=rout['name'] if a in rout['vars']: return islong_long(rout['vars'][a]) return 0 def islong_doublefunction(rout): if not isfunction(rout): return 0 if 'result' in rout: a=rout['result'] else: a=rout['name'] if a in rout['vars']: return islong_double(rout['vars'][a]) return 0 def iscomplexfunction(rout): if not isfunction(rout): return 0 if 'result' in rout: a=rout['result'] else: a=rout['name'] if a in rout['vars']: return iscomplex(rout['vars'][a]) return 0 def iscomplexfunction_warn(rout): if iscomplexfunction(rout): outmess("""\ ************************************************************** Warning: code with a function returning complex value may not work correctly with your Fortran compiler. Run the following test before using it in your applications: $(f2py install dir)/test-site/{b/runme_scalar,e/runme} When using GNU gcc/g77 compilers, codes should work correctly. **************************************************************\n""") return 1 return 0 def isstringfunction(rout): if not isfunction(rout): return 0 if 'result' in rout: a=rout['result'] else: a=rout['name'] if a in rout['vars']: return isstring(rout['vars'][a]) return 0 def hasexternals(rout): return 'externals' in rout and rout['externals'] def isthreadsafe(rout): return 'f2pyenhancements' in rout and 'threadsafe' in rout['f2pyenhancements'] def hasvariables(rout): return 'vars' in rout and rout['vars'] def isoptional(var): return ('attrspec' in var and 'optional' in var['attrspec'] and 'required' not in var['attrspec']) and isintent_nothide(var) def isexternal(var): return ('attrspec' in var and 'external' in var['attrspec']) def isrequired(var): return not isoptional(var) and isintent_nothide(var) def isintent_in(var): if 'intent' not in var: return 1 if 'hide' in var['intent']: return 0 if 'inplace' in var['intent']: return 0 if 'in' in var['intent']: return 1 if 'out' in var['intent']: return 0 if 'inout' in var['intent']: return 0 if 'outin' in var['intent']: return 0 return 1 def isintent_inout(var): return 'intent' in var and ('inout' in var['intent'] or 'outin' in var['intent']) and 'in' not in var['intent'] and 'hide' not in var['intent'] and 'inplace' not in var['intent'] def isintent_out(var): return 'out' in var.get('intent', []) def isintent_hide(var): return ('intent' in var and ('hide' in var['intent'] or ('out' in var['intent'] and 'in' not in var['intent'] and (not l_or(isintent_inout, isintent_inplace)(var))))) def isintent_nothide(var): return not isintent_hide(var) def isintent_c(var): return 'c' in var.get('intent', []) # def isintent_f(var): # return not isintent_c(var) def isintent_cache(var): return 'cache' in var.get('intent', []) def isintent_copy(var): return 'copy' in var.get('intent', []) def isintent_overwrite(var): return 'overwrite' in var.get('intent', []) def isintent_callback(var): return 'callback' in var.get('intent', []) def isintent_inplace(var): return 'inplace' in var.get('intent', []) def isintent_aux(var): return 'aux' in var.get('intent', []) def isintent_aligned4(var): return 'aligned4' in var.get('intent', []) def isintent_aligned8(var): return 'aligned8' in var.get('intent', []) def isintent_aligned16(var): return 'aligned16' in var.get('intent', []) isintent_dict = {isintent_in: 'INTENT_IN', isintent_inout: 'INTENT_INOUT', isintent_out: 'INTENT_OUT', isintent_hide: 'INTENT_HIDE', isintent_cache: 'INTENT_CACHE', isintent_c: 'INTENT_C', isoptional: 'OPTIONAL', isintent_inplace: 'INTENT_INPLACE', isintent_aligned4: 'INTENT_ALIGNED4', isintent_aligned8: 'INTENT_ALIGNED8', isintent_aligned16: 'INTENT_ALIGNED16', } def isprivate(var): return 'attrspec' in var and 'private' in var['attrspec'] def hasinitvalue(var): return '=' in var def hasinitvalueasstring(var): if not hasinitvalue(var): return 0 return var['='][0] in ['"', "'"] def hasnote(var): return 'note' in var def hasresultnote(rout): if not isfunction(rout): return 0 if 'result' in rout: a=rout['result'] else: a=rout['name'] if a in rout['vars']: return hasnote(rout['vars'][a]) return 0 def hascommon(rout): return 'common' in rout def containscommon(rout): if hascommon(rout): return 1 if hasbody(rout): for b in rout['body']: if containscommon(b): return 1 return 0 def containsmodule(block): if ismodule(block): return 1 if not hasbody(block): return 0 for b in block['body']: if containsmodule(b): return 1 return 0 def hasbody(rout): return 'body' in rout def hascallstatement(rout): return getcallstatement(rout) is not None def istrue(var): return 1 def isfalse(var): return 0 class F2PYError(Exception): pass class throw_error: def __init__(self, mess): self.mess = mess def __call__(self, var): mess = '\n\n var = %s\n Message: %s\n' % (var, self.mess) raise F2PYError(mess) def l_and(*f): l, l2='lambda v', [] for i in range(len(f)): l='%s,f%d=f[%d]'%(l, i, i) l2.append('f%d(v)'%(i)) return eval('%s:%s'%(l, ' and '.join(l2))) def l_or(*f): l, l2='lambda v', [] for i in range(len(f)): l='%s,f%d=f[%d]'%(l, i, i) l2.append('f%d(v)'%(i)) return eval('%s:%s'%(l, ' or '.join(l2))) def l_not(f): return eval('lambda v,f=f:not f(v)') def isdummyroutine(rout): try: return rout['f2pyenhancements']['fortranname']=='' except KeyError: return 0 def getfortranname(rout): try: name = rout['f2pyenhancements']['fortranname'] if name=='': raise KeyError if not name: errmess('Failed to use fortranname from %s\n'%(rout['f2pyenhancements'])) raise KeyError except KeyError: name = rout['name'] return name def getmultilineblock(rout,blockname,comment=1,counter=0): try: r = rout['f2pyenhancements'].get(blockname) except KeyError: return if not r: return if counter > 0 and isinstance(r, str): return if isinstance(r, list): if counter>=len(r): return r = r[counter] if r[:3]=="'''": if comment: r = '\t/* start ' + blockname + ' multiline ('+repr(counter)+') */\n' + r[3:] else: r = r[3:] if r[-3:]=="'''": if comment: r = r[:-3] + '\n\t/* end multiline ('+repr(counter)+')*/' else: r = r[:-3] else: errmess("%s multiline block should end with `'''`: %s\n" \ % (blockname, repr(r))) return r def getcallstatement(rout): return getmultilineblock(rout, 'callstatement') def getcallprotoargument(rout,cb_map={}): r = getmultilineblock(rout, 'callprotoargument', comment=0) if r: return r if hascallstatement(rout): outmess('warning: callstatement is defined without callprotoargument\n') return from .capi_maps import getctype arg_types, arg_types2 = [], [] if l_and(isstringfunction, l_not(isfunction_wrap))(rout): arg_types.extend(['char*', 'size_t']) for n in rout['args']: var = rout['vars'][n] if isintent_callback(var): continue if n in cb_map: ctype = cb_map[n]+'_typedef' else: ctype = getctype(var) if l_and(isintent_c, l_or(isscalar, iscomplex))(var): pass elif isstring(var): pass #ctype = 'void*' else: ctype = ctype+'*' if isstring(var) or isarrayofstrings(var): arg_types2.append('size_t') arg_types.append(ctype) proto_args = ','.join(arg_types+arg_types2) if not proto_args: proto_args = 'void' #print proto_args return proto_args def getusercode(rout): return getmultilineblock(rout, 'usercode') def getusercode1(rout): return getmultilineblock(rout, 'usercode', counter=1) def getpymethoddef(rout): return getmultilineblock(rout, 'pymethoddef') def getargs(rout): sortargs, args=[], [] if 'args' in rout: args=rout['args'] if 'sortvars' in rout: for a in rout['sortvars']: if a in args: sortargs.append(a) for a in args: if a not in sortargs: sortargs.append(a) else: sortargs=rout['args'] return args, sortargs def getargs2(rout): sortargs, args=[], rout.get('args', []) auxvars = [a for a in rout['vars'].keys() if isintent_aux(rout['vars'][a])\ and a not in args] args = auxvars + args if 'sortvars' in rout: for a in rout['sortvars']: if a in args: sortargs.append(a) for a in args: if a not in sortargs: sortargs.append(a) else: sortargs=auxvars + rout['args'] return args, sortargs def getrestdoc(rout): if 'f2pymultilines' not in rout: return None k = None if rout['block']=='python module': k = rout['block'], rout['name'] return rout['f2pymultilines'].get(k, None) def gentitle(name): l=(80-len(name)-6)//2 return '/*%s %s %s*/'%(l*'*', name, l*'*') def flatlist(l): if isinstance(l, list): return reduce(lambda x,y,f=flatlist:x+f(y), l, []) return [l] def stripcomma(s): if s and s[-1]==',': return s[:-1] return s def replace(str,d,defaultsep=''): if isinstance(d, list): return [replace(str, _m, defaultsep) for _m in d] if isinstance(str, list): return [replace(_m, d, defaultsep) for _m in str] for k in 2*list(d.keys()): if k=='separatorsfor': continue if 'separatorsfor' in d and k in d['separatorsfor']: sep=d['separatorsfor'][k] else: sep=defaultsep if isinstance(d[k], list): str=str.replace('#%s#'%(k), sep.join(flatlist(d[k]))) else: str=str.replace('#%s#'%(k), d[k]) return str def dictappend(rd, ar): if isinstance(ar, list): for a in ar: rd=dictappend(rd, a) return rd for k in ar.keys(): if k[0]=='_': continue if k in rd: if isinstance(rd[k], str): rd[k]=[rd[k]] if isinstance(rd[k], list): if isinstance(ar[k], list): rd[k]=rd[k]+ar[k] else: rd[k].append(ar[k]) elif isinstance(rd[k], dict): if isinstance(ar[k], dict): if k=='separatorsfor': for k1 in ar[k].keys(): if k1 not in rd[k]: rd[k][k1]=ar[k][k1] else: rd[k]=dictappend(rd[k], ar[k]) else: rd[k]=ar[k] return rd def applyrules(rules,d,var={}): ret={} if isinstance(rules, list): for r in rules: rr=applyrules(r, d, var) ret=dictappend(ret, rr) if '_break' in rr: break return ret if '_check' in rules and (not rules['_check'](var)): return ret if 'need' in rules: res = applyrules({'needs':rules['need']}, d, var) if 'needs' in res: cfuncs.append_needs(res['needs']) for k in rules.keys(): if k=='separatorsfor': ret[k]=rules[k]; continue if isinstance(rules[k], str): ret[k]=replace(rules[k], d) elif isinstance(rules[k], list): ret[k]=[] for i in rules[k]: ar=applyrules({k:i}, d, var) if k in ar: ret[k].append(ar[k]) elif k[0]=='_': continue elif isinstance(rules[k], dict): ret[k]=[] for k1 in rules[k].keys(): if isinstance(k1, types.FunctionType) and k1(var): if isinstance(rules[k][k1], list): for i in rules[k][k1]: if isinstance(i, dict): res=applyrules({'supertext':i}, d, var) if 'supertext' in res: i=res['supertext'] else: i='' ret[k].append(replace(i, d)) else: i=rules[k][k1] if isinstance(i, dict): res=applyrules({'supertext':i}, d) if 'supertext' in res: i=res['supertext'] else: i='' ret[k].append(replace(i, d)) else: errmess('applyrules: ignoring rule %s.\n'%repr(rules[k])) if isinstance(ret[k], list): if len(ret[k])==1: ret[k]=ret[k][0] if ret[k]==[]: del ret[k] return ret