def __init__(self, tb_name, fct_name, no_simd=False):
Base_gen.__init__(self, tb_name, fct_name, 'scalar')
Nt2_tb_struct.__init__(self)
self.tb_files = self.get_rel_tb_unique_files(tb_name)
self.fct_files = self.get_rel_tb_fcts_files(tb_name, fct_name)
self.unique_files = self.get_rel_tb_unique_files(tb_name)
self.no_simd = no_simd
def __init__(self,tb_name,fct_name,no_simd=False) :
Base_gen.__init__(self, tb_name, fct_name, 'scalar')
Nt2_tb_struct.__init__(self)
self.tb_files = self.get_rel_tb_unique_files(tb_name)
self.fct_files = self.get_rel_tb_fcts_files(tb_name,fct_name)
self.unique_files = self.get_rel_tb_unique_files(tb_name)
self.no_simd = no_simd
def create_one_bench(tb_name,
fct_name,
mode) :
print("tb %s fct %s with %s mode"%(tb_name,fct_name,mode))
bg = Base_gen(tb_name,fct_name,mode)
print(bg.get_module_style(tb_name))
bbg = Bench_gen(bg)
return bbg.get_gen_result()
def create_one_bench(tb_name, fct_name, mode, simd_type):
print("tb %s -> fct -> %s with %s mode -> simd_type %s" %
(tb_name, fct_name, mode, simd_type))
bg = Base_gen(tb_name, fct_name, mode)
## print(bg.get_module_style(tb_name))
bbg = Bench_gen(bg, simd_type)
return bbg.get_gen_result()
def create_one_exhaustive(tb_name,
fct_name,
mode = 'simd') :
print("tb %s -> fct -> %s with %s mode"%(tb_name,fct_name,mode))
bg = Base_gen(tb_name,fct_name,mode)
## print(bg.get_module_style(tb_name))
bbg = Exhaustive_gen(bg)
return bbg.get_gen_result()
def create_one_unit(self, fct_name, mode, part, platform):
# if self.verbose :
print("%s with %s with %s" % (fct_name, mode, part))
bg = Base_gen(self.tb_name, fct_name, mode)
ghg = Global_header_gen(bg, part)
r = ghg.get_gen_result()
dl = bg.get_fct_dict_list()
for rank, d in enumerate(dl):
df = d.get('functor', False)
if not df: df = self.Default_df
if df.get('no_simd_tests', False): return []
types = []
if mode == 'simd':
types = bg.recover('simd_types', df, [])
if len(types) == 0:
types = bg.recover('types', df, ['real_'])
ret_arity = int(df["ret_arity"])
d_unit = d.get("unit", {})
for typ in types:
thg = Type_header_test_gen(bg, d, typ, rank)
r += thg.get_gen_beg()
if self.verbose: print("part = %s" % part)
if ("unit" == part) and d_unit.get("specific_values", None):
svt = Specific_values_test_gen(bg, d, typ, ret_arity,
platform)
s = svt.get_gen_result()
## print(s)
## raise SystemExit
## if not s : return False
r += s
if ("cover" == part) and d_unit.get("verif_test", None):
vtg = Random_verif_test_gen(bg, d, typ, platform)
s = vtg.get_gen_result()
## print(s)
## raise SystemExit
## if not s : return False
r += s
r += thg.get_gen_end()
return r
def create_one_unit(self, fct_name, mode, part,platform) :
# if self.verbose :
print("%s with %s with %s"%(fct_name,mode,part))
bg = Base_gen(self.tb_name,fct_name,mode)
ghg = Global_header_gen(bg,part)
r = ghg.get_gen_result()
dl = bg.get_fct_dict_list()
for rank,d in enumerate(dl) :
df = d.get('functor',False)
if not df : df = self.Default_df
if df.get('no_simd_tests',False) : return []
types = []
if mode == 'simd':
types = bg.recover('simd_types',df,[])
if len(types) == 0:
types = bg.recover('types',df,['real_'])
ret_arity = int(df["ret_arity"])
d_unit = d.get("unit",{})
for typ in types :
thg = Type_header_test_gen(bg,d,typ,rank)
r+=thg.get_gen_beg()
if self.verbose : print("part = %s"%part)
if ("unit"==part) and d_unit.get("specific_values",None) :
svt = Specific_values_test_gen(bg,d,typ,ret_arity,platform)
s = svt.get_gen_result()
## print(s)
## raise SystemExit
## if not s : return False
r += s
if ("cover" == part) and d_unit.get("verif_test",None) :
vtg = Random_verif_test_gen(bg,d,typ,platform)
s = vtg.get_gen_result()
## print(s)
## raise SystemExit
## if not s : return False
r += s
r+=thg.get_gen_end()
return r
def create_unit(tb_name,fct_name,mode) :
bg = Base_gen(tb_name,fct_name,mode)
ghg = Global_header_gen(bg)
r = ghg.get_gen_result()
dl = bg.get_fct_dict_list()
for d in dl :
types = bg.recover("types",d["functor"],[])
d_unit = d["unit"]
for typ in types :
thg = Type_header_test_gen(bg,d,typ)
r+=thg.get_gen_beg()
if d_unit.get("specific_values",None) :
print("specific")
svt = Specific_values_test_gen(bg,d,typ)
r += svt. get_gen_result()
if d_unit.get("verif_test",None) :
print("verif")
vtg = Random_verif_test_gen(bg,d,typ)
r += vtg. get_gen_result()
r+=thg.get_gen_end()
return r
def create_unit(tb_name, fct_name, mode):
bg = Base_gen(tb_name, fct_name, mode)
ghg = Global_header_gen(bg)
r = ghg.get_gen_result()
if True: # try :
dl = bg.get_fct_dict_list()
for rank, d in enumerate(dl):
origin = "types" if mode == 'scalar' else 'simd_types'
types = bg.recover(origin, d["functor"], ["real_convert_"])
ret_arity = int(d["functor"]["ret_arity"])
d_unit = d["unit"]
for typ in types:
thg = Type_header_test_gen(bg, d, typ, rank)
r += thg.get_gen_beg()
if d_unit.get("specific_values", None):
svt = Specific_values_test_gen(bg, d, typ, ret_arity, mode)
r += svt.get_gen_result()
if d_unit.get("verif_test", None):
vtg = Random_verif_test_gen(bg, d, typ, mode)
r += vtg.get_gen_result()
r += thg.get_gen_end()
return r
def create_unit(tb_name,fct_name,mode,parts =["verif","values"]) :
bg = Base_gen(tb_name,fct_name,mode)
ghg = Global_header_gen(bg)
r = ghg.get_gen_result()
if True:# try :
dl = bg.get_fct_dict_list()
for rank, d in enumerate(dl) :
origin ="types" if mode == 'scalar' else 'simd_types'
types = bg.recover(origin,d["functor"],["real_convert_"])
ret_arity = int(d["functor"]["ret_arity"])
d_unit = d["unit"]
for typ in types :
thg = Type_header_test_gen(bg,d,typ,rank)
r+=thg.get_gen_beg()
if ("values" in parts) and d_unit.get("specific_values",None) :
svt = Specific_values_test_gen(bg,d,typ,ret_arity,mode)
r += svt. get_gen_result()
if ("verif" in parts) and d_unit.get("verif_test",None) :
vtg = Random_verif_test_gen(bg,d,typ,mode)
r += vtg. get_gen_result()
r+=thg.get_gen_end()
return r
def __init__(self,
tb_name=None,
fct_name=None,
mode=None,
d=None,
bg=None,
index=0,
arity=None,
repfunc=None,
repinclude=None):
self.bg = bg if tb_name is None else Base_gen(tb_name, fct_name, mode)
self.name = self.bg.get_fct_name()
self.tb_name = self.bg.get_tb_name()
self.mode = self.bg.get_fct_mode()
self.d = self.__get_dict(d, index, arity)
self.typs = self.get_types()
self.types_str = stringize(self.typs)
## self.repfunc = self.bg.get_fct_name()+'_rn' if repfunc is None else repfunc
## self.repinclude = "#include <nt2/toolbox/crlibm/functions/"+self.repfunc+'.hpp>' if repinclude is None else repinclude
self.prefix = "nt2" if self.bg.get_tb_name().find(
'.') == -1 else '::'.join(self.bg.get_tb_name().split('.')[0:-1])
dd = d.get("call_types", None)
if dd is None:
return "T"
elif type(dd) is str:
return dd
else:
return dd[i]
if __name__ == "__main__":
from pprint import PrettyPrinter
from unit_base_gen import Base_gen
from unit_type_header_gen import Type_header_test_gen
from unit_specific_values_gen import Specific_values_test_gen
print __doc__
bg = Base_gen("exponential", 'pipo', 'scalar')
dl = bg.get_fct_dict_list()
## r = []
## for d in dl :
## types = bg.recover("types",d["functor"],[])
## d_unit = d["unit"]
## for typ in types :
## thg = Type_header_test_gen(bg,d,typ,0)
## r+=thg.get_gen_beg()
## if d_unit.get("specific_values",None) :
## svt = Specific_values_test_gen(bg,d,typ,ret_arity,mode)
## r += svt. get_gen_result()
## if d_unit.get("random_tuple_test",None) :
## rtg = Random_tuple_test_gen(bg,d,typ,mode)
## r += rtg. get_gen_result()
## r+=thg.get_gen_end()
for i in range(0, ret_arity):
s1 = re.sub("\$i\$", str(i), Call)
s1 = re.sub("\$call_param_res\$", rep[i], s1)
s1 = re.sub("\$specific_thresh\$", thr[i], s1)
if self.mode == 'simd':
s1 = re.sub("T", "vT", s1)
r.append(s1)
r.append(" }")
return r
if __name__ == "__main__":
from pprint import PrettyPrinter
from unit_base_gen import Base_gen
from unit_type_header_gen import Type_header_test_gen
## print (__doc__)
bg = Base_gen("exponential", 'pipo', 'scalar')
dl = bg.get_fct_dict_list()
r = []
for d in dl:
types = bg.recover("types", d["functor"], [])
d_unit = d["unit"]
for typ in types:
thg = Type_header_test_gen(bg, d, typ)
r += thg.get_gen_beg()
if d_unit.get("specific_values", None):
svt = Specific_values_test_gen(bg, d, typ)
r += svt.get_gen_result()
r += thg.get_gen_end()
PrettyPrinter().pprint(r)
sys.path.pop(0)
dd = d.get("call_types",None)
if dd is None :
return "T"
elif type(dd) is str :
return dd
else :
return dd[i]
if __name__ == "__main__" :
from pprint import PrettyPrinter
from unit_base_gen import Base_gen
from unit_type_header_gen import Type_header_test_gen
from unit_specific_values_gen import Specific_values_test_gen
print __doc__
bg = Base_gen("exponential",'pipo','scalar')
dl = bg.get_fct_dict_list()
## r = []
## for d in dl :
## types = bg.recover("types",d["functor"],[])
## d_unit = d["unit"]
## for typ in types :
## thg = Type_header_test_gen(bg,d,typ,0)
## r+=thg.get_gen_beg()
## if d_unit.get("specific_values",None) :
## svt = Specific_values_test_gen(bg,d,typ,ret_arity,mode)
## r += svt. get_gen_result()
## if d_unit.get("random_tuple_test",None) :
## rtg = Random_tuple_test_gen(bg,d,typ,mode)
## r += rtg. get_gen_result()
## r+=thg.get_gen_end()
if calls[j][0] == 'i':
param += tpl % (iprefix + calls[j], rge[0],
rge[1])
elif calls[j][0] == 's':
param += tpl % (calls[j][1:], rge[0],
rge[1])
else:
param += tpl % (prefix + calls[j], rge[0],
rge[1])
r.append(call % param)
r += ["}"]
txt += r + txtf
if tb_name.find('.') != -1:
for i, l in enumerate(txt):
txt[i] = re.sub('nt2::', 'boost::simd::', l)
h = Headers(os.path.join(self.bg.get_nt2_rel_tb_path(tb_name), 'bench',
mode),
name,
inner=txt,
guard_begin=[],
guard_end=[]).txt()
return h.split('\n')
if __name__ == "__main__":
print __doc__
from pprint import PrettyPrinter
bg = Base_gen("exponential", 'pipo', 'simd')
bbg = Bench_gen(bg)
PrettyPrinter().pprint(bbg.get_gen_result())
if self.stampit:
st = d.get("stamp", "")
st = re.sub("\d+/\d+/\d+",
datetime.datetime.now().strftime("%d/%m/%Y"), st)
s = re.sub("\$stamp\$", '/// ' + st, s)
else:
s = re.sub("\$stamp\$", '/// ', s)
fs = d.get("first_stamp", "")
fs = re.sub("modified", "created", fs)
s = re.sub("\$first_stamp\$", '/// ' + fs, s)
s = re.sub("\$no_ulp\$",
"" if d.get("no_ulp", False) != True else "no_ulp_", s)
m = re.search('\$notes\$', s)
if m:
s = []
beg = '/// '
n = d.get("notes", [])
for l in n:
ll = l.split('\n')
for lll in ll:
s.append(beg + lll.lstrip())
return s
if __name__ == "__main__":
print __doc__
from pprint import PrettyPrinter
bg = Base_gen("exponential", 'exp', 'scalar')
ghg = Global_header_gen(bg, 'cover')
PrettyPrinter().pprint(ghg.get_gen_result())
r.append(" }")
return r
def __add(s, r):
if isinstance(s, str):
return r.append(s)
elif isinstance(s, list):
return r.extend(s)
return r
if __name__ == "__main__":
from pprint import PrettyPrinter
from unit_base_gen import Base_gen
from unit_type_header_gen import Type_header_test_gen
## print (__doc__)
bg = Base_gen("arithmetic", 'abs', 'scalar')
dl = bg.get_fct_dict_list()
r = []
for d in dl:
ret_arity = int(extract(d, "", "", "functor", "ret_arity"))
types = bg.recover("types", d["functor"], [])
d_unit = d["unit"]
for typ in types:
thg = Type_header_test_gen(bg, d, typ, 0)
r += thg.get_gen_beg()
if d_unit.get("specific_values", None):
svt = Specific_values_test_gen(bg, d, typ, ret_arity, 'scalar')
r += svt.get_gen_result()
r += thg.get_gen_end()
PrettyPrinter().pprint(r)
s=re.sub("\$rturn\$", d["functor"]["rturn"].get(typ,d["functor"]["rturn"]["default"]),s)
m = re.match("( *)\$type_defs\$.*",s)
if m :
s = []
beg = m.groups()[0]
tpdefs = d["functor"].get("type_defs",None)
if tpdefs is not None :
for l in tpdefs :
s.append( beg+l)
else :
s= ""
return s
if __name__ == "__main__" :
from pprint import PrettyPrinter
from unit_base_gen import Base_gen
print __doc__
bg = Base_gen("exponential",'pipo','scalar')
dl = bg.get_fct_dict_list()
r = []
for d in dl :
types = bg.recover("types",d["functor"],[])
for typ in types :
thg = Type_header_test_gen(bg,d,typ)
r+=thg.get_gen_beg()
r+=thg.get_gen_end()
PrettyPrinter().pprint(r)
sys.path.pop(0)
sys.path.pop(0)
types = self.types if types is None else listify(types)
dictres = {}
main = self.get_fct_exhaustive_main_path(self.mode)
dictres[main] = self.gen_main_file()
for typ in types:
path = self.get_fct_exhaustive_include_path(self.mode, typ)
dictres[path] = self.gen_include_file(path, typ)
return dictres
def create_main_and_includes(self, types=None, wr=False):
dictres = self.dgen_main_and_includes(types)
for path in dictres.keys():
print(path)
self.write_file(path,
dictres[path],
check=False,
backup=True,
wr=wr)
if __name__ == "__main__":
print __doc__
from pprint import PrettyPrinter
bg = Base_gen("trigonometric", 'sin', 'simd')
bbg = Exhaustive_gen(bg)
## PrettyPrinter().pprint(bbg.gen_global_header().split('\n'))
## PrettyPrinter().pprint(bbg.gen_test_func_forwarding().split('\n'))
## PrettyPrinter().pprint(bbg.gen_test_func('float').split('\n'))
## PrettyPrinter().pprint(bbg.gen_main_func().split('\n'))
machin = bbg.create_main_and_includes(wr=True)
