#!/usr/bin/env python3
import re
import sys
from argparse import ArgumentParser
field_file = "nodes.ads"
kind_file = "iirs.ads"
node_file = "iirs.ads"
template_file = "iirs.adb.in"
meta_base_file = "nodes_meta"
prefix_name = "Iir_Kind_"
prefix_range_name = "Iir_Kinds_"
type_name = "Iir_Kind"
node_type = "Iir"
conversions = ["uc", "pos", "grp"]
class FuncDesc:
def __init__(self, name, fields, conv, acc, pname, ptype, rname, rtype):
self.name = name
self.fields = fields # List of physical fields used
self.conv = conv
self.acc = acc # access: Chain, Chain_Next, Ref, Of_Ref, Maybe_Ref,
# Forward_Ref, Maybe_Forward_Ref
self.pname = pname # Parameter mame
self.ptype = ptype # Parameter type
self.rname = rname # value name (for procedure)
self.rtype = rtype # value type
class NodeDesc:
def __init__(self, name, format, fields, attrs):
self.name = name
self.format = format
self.fields = fields # {field: FuncDesc} dict, defined for all fields
self.attrs = attrs # A {attr: FuncDesc} dict
self.order = [] # List of fields name, in order of appearance.
class line:
def __init__(self, string, no):
self.l = string
self.n = no
class EndOfFile(Exception):
def __init__(self, filename):
self.filename = filename
def __str__(self):
return "end of file " + self.filename
class linereader:
def __init__(self, filename):
self.filename = filename
self.f = open(filename)
self.lineno = 0
self.l = ""
def get(self):
self.l = self.f.readline()
if not self.l:
raise EndOfFile(self.filename)
self.lineno = self.lineno + 1
return self.l
class ParseError(Exception):
def __init__(self, lr, msg):
self.lr = lr
self.msg = msg
def __str__(self):
return ("Parse error at {lr.filename}:{lr.lineno}: {msg}".format(lr=self.lr, msg=self.msg))
# Return fields description.
# This is a dictionary. The keys represent the possible format of a node.
# The values are dictionaries representing fields. Keys are fields name, and
# values are fields type.
def read_fields(file):
fields = {}
formats = []
lr = linereader(file)
# Search for 'type Format_Type is'
while lr.get() != " type Format_Type is\n":
pass
# Skip '('
if lr.get() != " (\n":
raise Exception("no open parenthesis after Format_Type")
# Read formats
l = lr.get()
pat_field_name = re.compile(" Format_(\w+),?\n")
while l != " );\n":
m = pat_field_name.match(l)
if m is None:
print(l)
raise Exception("bad literal within Format_Type")
name = m.group(1)
formats.append(name)
fields[name] = {}
l = lr.get()
# Read fields
l = lr.get()
pat_fields = re.compile(" -- Fields of Format_(\w+):\n")
pat_field_desc = re.compile(" -- (\w+) : (\w+).*\n")
common_desc = {}
# Read until common fields.
while l != " -- Common fields are:\n":
l = lr.get()
format_name = "Common"
nbr_formats = 0
while True:
# 1) Read field description
l = lr.get()
desc = common_desc.copy()
while True:
m = pat_field_desc.match(l)
if m is None:
break
desc[m.group(1)] = m.group(2)
l = lr.get()
# print 'For: ' + format_name + ': ' + m.group(1)
# 2) Disp
if format_name == "Common":
common_desc = desc
else:
fields[format_name] = desc
# 3) Read next format
if l == "\n":
if nbr_formats == len(fields):
break
else:
l = lr.get()
# One for a format
m = pat_fields.match(l)
if m is not None:
format_name = m.group(1)
if format_name not in fields:
raise ParseError(lr, "Format " + format_name + " is unknown")
nbr_formats = nbr_formats + 1
else:
raise ParseError(lr, "unhandled format line")
return (formats, fields)
# Read kinds and kinds ranges.
def read_kinds(filename):
lr = linereader(filename)
kinds = []
# Search for 'type Iir_Kind is'
while lr.get() != " type " + type_name + " is\n":
pass
# Skip '('
if lr.get() != " (\n":
raise ParseError(lr, 'no open parenthesis after "type ' + type_name + '"')
# Read literals
pat_node = re.compile(" " + prefix_name + "(\w+),?( +-- .*)?\n")
pat_comment = re.compile("( +-- .*)?\n")
while True:
l = lr.get()
if l == " );\n":
break
m = pat_node.match(l)
if m:
kinds.append(m.group(1))
continue
m = pat_comment.match(l)
if not m:
raise ParseError(lr, "Unknown line within kind declaration")
# Check subtypes
pat_subtype = re.compile(" subtype " + r"(\w+) is " + type_name + " range\n")
pat_first = re.compile(" " + prefix_name + r"(\w+) ..\n")
pat_last = re.compile(" " + prefix_name + r"(\w+);\n")
pat_middle = re.compile(" --" + prefix_name + r"(\w+)\n")
kinds_ranges = {}
while True:
l = lr.get()
# Start of methods is also end of subtypes.
if l == " -- General methods.\n":
break
# Found a subtype.
m = pat_subtype.match(l)
if m:
# Check first bound
name = m.group(1)
if not name.startswith(prefix_range_name):
raise ParseError(lr, "incorrect prefix for subtype")
name = name[len(prefix_range_name):]
l = lr.get()
mf = pat_first.match(l)
if not mf:
raise ParseError(lr, "badly formatted first bound of subtype")
first = kinds.index(mf.group(1))
idx = first
has_middle = None
# Read until last bound
while True:
l = lr.get()
ml = pat_middle.match(l)
if ml:
# Check element in the middle
n = ml.group(1)
if n not in kinds:
raise ParseError(lr, "unknown kind " + n + " in subtype")
if kinds.index(n) != idx + 1:
raise ParseError(
lr, "missing " + kinds[idx + 1] + " in subtype"
)
has_middle = True
idx = idx + 1
else:
# Check last bound
ml = pat_last.match(l)
if ml:
last = kinds.index(ml.group(1))
if last != idx + 1 and has_middle:
raise ParseError(
lr, "missing " + kinds[idx] + " in subtype"
)
break
raise ParseError(lr, "unhandled line in subtype")
kinds_ranges[name] = kinds[first: last + 1]
return (kinds, kinds_ranges)
# Read functions
def read_methods(filename):
lr = linereader(filename)
funcs = []
pat_field = re.compile(r" -- Field: ([\w,]+)( \w+)?( \(\w+\))?\n")
pat_conv = re.compile(r"^ \((\w+)\)$")
pat_func = re.compile(r" function Get_(\w+) \((\w+) : (\w+)\) return (\w+);\n")
pat_proc = re.compile(r" procedure Set_(\w+) \((\w+) : (\w+); (\w+) : (\w+)\);\n")
pat_end = re.compile("end [A-Za-z.]+;\n")
while True:
l = lr.get()
# Start of methods
if l == " -- General methods.\n":
break
while True:
l = lr.get()
if pat_end.match(l):
break
m = pat_field.match(l)
if m:
fields = m.group(1).split(",")
# Extract access modifier
acc = m.group(2)
if acc:
acc = acc.strip()
# Extract conversion
conv = m.group(3)
if conv:
mc = pat_conv.match(conv)
if not mc:
raise ParseError(lr, "conversion ill formed")
conv = mc.group(1)
if conv not in conversions:
raise ParseError(lr, "unknown conversion " + conv)
else:
conv = None
if len(fields) > 1 and conv != "grp":
raise ParseError(lr, "bad conversion for multiple fields")
# Read function
l = lr.get()
mf = pat_func.match(l)
if not mf:
raise ParseError(lr, "function declaration expected after Field")
# Read procedure
l = lr.get()
mp = pat_proc.match(l)
if not mp:
raise ParseError(lr, "procedure declaration expected after function")
# Consistency check between function and procedure
if mf.group(1) != mp.group(1):
raise ParseError(lr, "function and procedure name mismatch")
if mf.group(2) != mp.group(2):
raise ParseError(lr, "parameter name mismatch with function")
if mf.group(3) != mp.group(3):
raise ParseError(lr, "parameter type mismatch with function")
if mf.group(4) != mp.group(5):
raise ParseError(lr, "result type mismatch with function")
funcs.append(
FuncDesc(
mf.group(1),
fields,
conv,
acc,
mp.group(2),
mp.group(3),
mp.group(4),
mp.group(5),
)
)
return funcs
# Read description for one node
# LR is the line reader. NAMES is the list of (node name, format)
# (one description may describe several nodes).
# A comment start at column 2 or 4 or later.
def read_nodes_fields(lr, names, fields, nodes, funcs_dict):
pat_only = re.compile(" -- Only for " + prefix_name + "(\w+):\n")
pat_only_bad = re.compile(" -- *Only for.*\n")
pat_field = re.compile(" -- Get/Set_(\w+) \((Alias )?([\w,]+)\)\n")
pat_comment = re.compile(" --(| [^ ].*| .*)\n")
# Create nodes
cur_nodes = []
for (nm, fmt) in names:
if fmt not in fields:
raise ParseError(lr, 'unknown format "{}"'.format(fmt))
n = NodeDesc(nm, fmt, {x: None for x in fields[fmt]}, {})
nodes[nm] = n
cur_nodes.append(n)
# Skip comments
l = lr.l
while pat_comment.match(l):
l = lr.get()
# Look for fields
while l != "\n":
# Skip comments
while pat_comment.match(l):
l = lr.get()
# Handle 'Only ...'
m = pat_only.match(l)
if m:
only_nodes = []
while True:
name = m.group(1)
n = nodes.get(name, None)
if n is None:
raise ParseError(lr, "node is unknown")
if n not in cur_nodes:
raise ParseError(lr, "node not currently described")
only_nodes.append(n)
l = lr.get()
m = pat_only.match(l)
if not m:
break
else:
# By default a field applies to all nodes.
only_nodes = cur_nodes
# Skip comments
while pat_comment.match(l):
l = lr.get()
# Handle field: '-- Get/Set_FUNC (Alias? FIELD)'
m = pat_field.match(l)
if not m:
if pat_only_bad.match(l):
raise ParseError(lr, "misleading 'Only for' comment")
else:
raise ParseError(lr, "bad line in node description")
func = m.group(1)
alias = m.group(2)
fields = m.group(3).split(",")
# Check the function exists and if the field is correct.
if func not in funcs_dict:
raise ParseError(lr, "unknown function")
func = funcs_dict[func]
if func.fields != fields:
raise ParseError(lr, "fields mismatch")
for c in only_nodes:
for f in fields:
if f not in c.fields:
raise ParseError(lr, "field " + f + " does not exist in node")
if not alias:
for f in fields:
if c.fields[f]:
raise ParseError(lr, "field " + f + " already used")
c.fields[f] = func
c.order.append(f)
c.attrs[func.name] = func
l = lr.get()
def read_nodes(filename, kinds, kinds_ranges, fields, funcs):
"""Read description for all nodes."""
lr = linereader(filename)
funcs_dict = {x.name: x for x in funcs}
nodes = {}
# Skip until start
while lr.get() != " -- Start of " + type_name + ".\n":
pass
pat_decl = re.compile(" -- " + prefix_name + "(\w+) \((\w+)\)\n")
pat_decls = re.compile(" -- " + prefix_range_name + "(\w+) \((\w+)\)\n")
pat_comment_line = re.compile(" --+\n")
pat_comment_box = re.compile(" --( .*)?\n")
while True:
l = lr.get()
if l == " -- End of " + type_name + ".\n":
break
if l == "\n":
continue
m = pat_decl.match(l)
if m:
# List of nodes being described by the current description.
names = []
# Declaration of the first node
while True:
name = m.group(1)
if name not in kinds:
raise ParseError(lr, "unknown node")
fmt = m.group(2)
names.append((name, fmt))
if name in nodes:
raise ParseError(lr, "node {} already described".format(name))
# There might be several nodes described at once.
l = lr.get()
m = pat_decl.match(l)
if not m:
break
read_nodes_fields(lr, names, fields, nodes, funcs_dict)
continue
m = pat_decls.match(l)
if m:
# List of nodes being described by the current description.
name = m.group(1)
fmt = m.group(2)
names = [(k, fmt) for k in kinds_ranges[name]]
lr.get()
read_nodes_fields(lr, names, fields, nodes, funcs_dict)
continue
if pat_comment_line.match(l) or pat_comment_box.match(l):
continue
raise ParseError(lr, "bad line in node description")
for k in kinds:
if k not in nodes:
raise ParseError(lr, 'no description for "{}"'.format(k))
return nodes
def gen_choices(choices):
"""Generate a choice 'when A | B ... Z =>' using elements of CHOICES."""
is_first = True
for c in choices:
ch = prefix_name + c
if is_first:
is_first = False
print(" when " + ch, end='')
else:
print()
print(" | " + ch, end='')
print(" =>")
def gen_get_format(formats, nodes, kinds=None):
"""Generate the Get_Format function."""
print(" function Get_Format (Kind : " + type_name + ") " + "return Format_Type is")
print(" begin")
print(" case Kind is")
for f in formats:
choices = [k for k in kinds if nodes[k].format == f]
gen_choices(choices)
print(" return Format_" + f + ";")
print(" end case;")
print(" end Get_Format;")
def gen_subprg_header(decl):
if len(decl) < 76:
print(decl + " is")
else:
print(decl)
print(" is")
print(" begin")
def gen_assert(func):
print(" pragma Assert (" + func.pname + " /= Null_" + node_type + ");")
cond = "(Has_" + func.name + " (Get_Kind (" + func.pname + ")),"
msg = '"no field ' + func.name + '");'
if len(cond) < 60:
print(" pragma Assert " + cond)
print(" " + msg)
else:
print(" pragma Assert")
print(" " + cond)
print(" " + msg)
def get_field_type(fields, f):
for fld in list(fields.values()):
if f in fld:
return fld[f]
return None
def gen_get_set(func, nodes, fields):
"""Generate Get_XXX/Set_XXX subprograms for FUNC."""
rtype = func.rtype
# If the function needs several fields, it must be user defined
if func.conv == "grp":
print(" type %s_Conv is record" % rtype)
for f in func.fields:
print(" %s: %s;" % (f, get_field_type(fields, f)))
print(" end record;")
print(" pragma Pack (%s_Conv);" % rtype)
print(" pragma Assert (%s_Conv'Size = %s'Size);" % (rtype, rtype))
print()
else:
f = func.fields[0]
g = "Get_" + f + " (" + func.pname + ")"
s = func.rname
if func.conv:
if func.conv == "uc":
field_type = get_field_type(fields, f)
g = field_type + "_To_" + rtype + " (" + g + ")"
s = rtype + "_To_" + field_type + " (" + s + ")"
elif func.conv == "pos":
g = rtype + "'Val (" + g + ")"
s = rtype + "'Pos (" + s + ")"
subprg = (
" function Get_"
+ func.name
+ " ("
+ func.pname
+ " : "
+ func.ptype
+ ") return "
+ rtype
)
if func.conv == "grp":
print(subprg)
print(" is")
print(" function To_%s is new Ada.Unchecked_Conversion" % func.rtype)
print(" (%s_Conv, %s);" % (rtype, rtype))
print(" Conv : %s_Conv;" % rtype)
print(" begin")
else:
gen_subprg_header(subprg)
gen_assert(func)
if func.conv == "grp":
for f in func.fields:
print(" Conv.%s := Get_%s (%s);" % (f, f, func.pname))
g = "To_%s (Conv)" % rtype
print(" return " + g + ";")
print(" end Get_" + func.name + ";")
print()
subprg = (
" procedure Set_"
+ func.name
+ " ("
+ func.pname
+ " : "
+ func.ptype
+ "; "
+ func.rname
+ " : "
+ func.rtype
+ ")"
)
if func.conv == "grp":
print(subprg)
print(" is")
print(" function To_%s_Conv is new Ada.Unchecked_Conversion" % func.rtype)
print(" (%s, %s_Conv);" % (rtype, rtype))
print(" Conv : %s_Conv;" % rtype)
print(" begin")
else:
gen_subprg_header(subprg)
gen_assert(func)
if func.conv == "grp":
print(" Conv := To_%s_Conv (%s);" % (rtype, func.rname))
for f in func.fields:
print(" Set_%s (%s, Conv.%s);" % (f, func.pname, f))
else:
print(" Set_" + f + " (" + func.pname + ", " + s + ");")
print(" end Set_" + func.name + ";")
print()
def funcs_of_node(n):
return sorted([fv.name for fv in list(n.fields.values()) if fv])
def gen_has_func_spec(name, suff):
spec = " function Has_" + name + " (K : " + type_name + ")"
ret = " return Boolean" + suff
if len(spec) < 60:
print(spec + ret)
else:
print(spec)
print(" " + ret)
def do_disp_formats():
for fmt in fields:
print("Fields of Format_" + fmt)
fld = fields[fmt]
for k in fld:
print(" " + k + " (" + fld[k] + ")")
def do_disp_kinds():
print("Kinds are:")
for k in kinds:
print(" " + prefix_name + k)
def do_disp_funcs():
print("Functions are:")
for f in funcs:
s = "{0} ({1}: {2}".format(f.name, f.fields, f.rtype)
if f.acc:
s += " acc:" + f.acc
if f.conv:
s += " conv:" + f.conv
s += ")"
print(s)
def do_disp_types():
print("Types are:")
s = set([])
for f in funcs:
s |= {f.rtype}
for t in sorted(s):
print(" " + t)
def do_disp_nodes():
for k in kinds:
v = nodes[k]
print(prefix_name + k + " (" + v.format + ")")
flds = [fk for fk, fv in list(v.fields.items()) if fv]
for fk in sorted(flds):
print(" " + fk + ": " + v.fields[fk].name)
def do_get_format():
gen_get_format(formats, nodes)
def do_body():
lr = linereader(template_file)
while True:
l = lr.get().rstrip()
print(l)
if l == " -- Subprograms":
gen_get_format(formats, nodes, kinds)
print()
for f in funcs:
gen_get_set(f, nodes, fields)
if l[0:3] == "end":
break
def get_types():
s = set([])
for f in funcs:
s |= {f.rtype}
return [t for t in sorted(s)]
def get_attributes():
s = set([])
for f in funcs:
if f.acc:
s |= {f.acc}
res = [t for t in sorted(s)]
res.insert(0, "None")
return res
def gen_enum(prefix, vals):
last = None
for v in vals:
if last:
print(last + ",")
last = prefix + v
print(last)
def do_meta_specs():
lr = linereader(meta_base_file + ".ads.in")
types = get_types()
while True:
l = lr.get().rstrip()
if l == " -- TYPES":
gen_enum(" Type_", types)
elif l == " -- FIELDS":
gen_enum(" Field_", [f.name for f in funcs])
elif l == " -- ATTRS":
gen_enum(" Attr_", get_attributes())
elif l == " -- FUNCS":
for t in types:
print(" function Get_" + t)
print(" (N : " + node_type + "; F : Fields_Enum) return " + t + ";")
print(" procedure Set_" + t)
print(" (N : " + node_type + "; F : Fields_Enum; V: " + t + ");")
print()
for f in funcs:
gen_has_func_spec(f.name, ";")
elif l[0:3] == "end":
print(l)
break
else:
print(l)
def do_meta_body():
lr = linereader(meta_base_file + ".adb.in")
while True:
l = lr.get().rstrip()
if l == " -- FIELDS_TYPE":
last = None
for f in funcs:
if last:
print(last + ",")
last = " Field_" + f.name + " => Type_" + f.rtype
print(last)
elif l == " -- FIELD_IMAGE":
for f in funcs:
print(" when Field_" + f.name + " =>")
print(' return "' + f.name.lower() + '";')
elif l == " -- IIR_IMAGE":
for k in kinds:
print(" when " + prefix_name + k + " =>")
print(' return "' + k.lower() + '";')
elif l == " -- FIELD_ATTRIBUTE":
for f in funcs:
print(" when Field_" + f.name + " =>")
if f.acc:
attr = f.acc
else:
attr = "None"
print(" return Attr_" + attr + ";")
elif l == " -- FIELDS_ARRAY":
last = None
nodes_types = [node_type, node_type + "_List", node_type + "_Flist"]
for k in kinds:
v = nodes[k]
if last:
print(last + ",")
last = None
print(" -- " + prefix_name + k)
# Get list of physical fields for V, in some order.
if flag_keep_order:
flds = v.order
else:
# First non Iir and no Iir_List.
flds = sorted(
[
fk
for fk, fv in list(v.fields.items())
if fv and fv.rtype not in nodes_types
]
)
# Then Iir and Iir_List in order of appearance
flds += (fv for fv in v.order if v.fields[fv].rtype in nodes_types)
# Print the corresponding node field, but remove duplicate due
# to 'grp'.
fldsn = []
for fk in flds:
if last:
print(last + ",")
# Remove duplicate
fn = v.fields[fk].name
if fn not in fldsn:
last = " Field_" + fn
fldsn.append(fn)
else:
last = None
if last:
print(last)
elif l == " -- FIELDS_ARRAY_POS":
pos = -1
last = None
for k in kinds:
v = nodes[k]
# Create a set to remove duplicate for 'grp'.
flds = set([fv.name for fk, fv in list(v.fields.items()) if fv])
pos += len(flds)
if last:
print(last + ",")
last = " " + prefix_name + k + " => {}".format(pos)
print(last)
elif l == " -- FUNCS_BODY":
# Build list of types
s = set([])
for f in funcs:
s |= {f.rtype}
types = [t for t in sorted(s)]
for t in types:
print(" function Get_" + t)
print(" (N : " + node_type + "; F : Fields_Enum) return " + t + " is")
print(" begin")
print(" pragma Assert (Fields_Type (F) = Type_" + t + ");")
print(" case F is")
for f in funcs:
if f.rtype == t:
print(" when Field_" + f.name + " =>")
print(" return Get_" + f.name + " (N);")
print(" when others =>")
print(" raise Internal_Error;")
print(" end case;")
print(" end Get_" + t + ";")
print()
print(" procedure Set_" + t)
print(" (N : " + node_type + "; F : Fields_Enum; V: " + t + ") is")
print(" begin")
print(" pragma Assert (Fields_Type (F) = Type_" + t + ");")
print(" case F is")
for f in funcs:
if f.rtype == t:
print(" when Field_" + f.name + " =>")
print(" Set_" + f.name + " (N, V);")
print(" when others =>")
print(" raise Internal_Error;")
print(" end case;")
print(" end Set_" + t + ";")
print()
for f in funcs:
gen_has_func_spec(f.name, " is")
choices = [k for k in kinds if f.name in nodes[k].attrs]
if len(choices) == 0:
print(" pragma Unreferenced (K);")
print(" begin")
if len(choices) == 0:
print(" return False;")
elif len(choices) == 1:
print(" return K = " + prefix_name + choices[0] + ";")
else:
print(" case K is")
gen_choices(choices)
print(" return True;")
print(" when others =>")
print(" return False;")
print(" end case;")
print(" end Has_" + f.name + ";")
print()
elif l[0:3] == "end":
print(l)
break
else:
print(l)
actions = {
"disp-nodes": do_disp_nodes,
"disp-kinds": do_disp_kinds,
"disp-formats": do_disp_formats,
"disp-funcs": do_disp_funcs,
"disp-types": do_disp_types,
"get_format": do_get_format,
"body": do_body,
"meta_specs": do_meta_specs,
"meta_body": do_meta_body,
}
def _generateCLIParser() -> ArgumentParser:
""""""
parser = ArgumentParser(description="Meta-grammar processor")
parser.add_argument("action", choices=list(actions.keys()), default="disp-nodes")
parser.add_argument(
"--field-file",
dest="field_file",
default="nodes.ads",
help="specify file which defines fields",
)
parser.add_argument(
"--kind-file",
dest="kind_file",
default="iirs.ads",
help="specify file which defines nodes kind",
)
parser.add_argument(
"--node-file",
dest="node_file",
default="iirs.ads",
help="specify file which defines nodes and methods",
)
parser.add_argument(
"--template-file",
dest="template_file",
default="iirs.adb.in",
help="specify template body file",
)
parser.add_argument(
"--meta-basename",
dest="meta_basename",
default="nodes_meta",
help="specify base name of meta files",
)
parser.add_argument(
"--kind-type", dest="kind_type", default="Iir_Kind", help="name of kind type"
)
parser.add_argument(
"--kind-prefix",
dest="kind_prefix",
default="Iir_Kind_",
help="prefix for kind literals",
)
parser.add_argument(
"--kind-range-prefix",
dest="kind_range_prefix",
default="Iir_Kinds_",
help="prefix for kind subtype (range)",
)
parser.add_argument(
"--node-type", dest="node_type", default="Iir", help="name of the node type"
)
parser.add_argument(
"--keep-order",
dest="flag_keep_order",
action="store_true",
help="keep field order of nodes",
)
parser.set_defaults(flag_keep_order=False)
return parser
def main():
parser = _generateCLIParser()
args = parser.parse_args()
# At some point, it would be simpler to create a class...
global formats, fields, nodes, kinds, kinds_ranges, funcs
global type_name, prefix_name, template_file, node_type, meta_base_file
global prefix_range_name, flag_keep_order, kind_file
type_name = args.kind_type
prefix_name = args.kind_prefix
prefix_range_name = args.kind_range_prefix
template_file = args.template_file
node_type = args.node_type
meta_base_file = args.meta_basename
flag_keep_order = args.flag_keep_order
field_file = args.field_file
kind_file = args.kind_file
node_file = args.node_file
try:
(formats, fields) = read_fields(field_file)
(kinds, kinds_ranges) = read_kinds(kind_file)
funcs = read_methods(node_file)
nodes = read_nodes(node_file, kinds, kinds_ranges, fields, funcs)
except ParseError as e:
print(e, file=sys.stderr)
print("in {0}:{1}:{2}".format(e.lr.filename, e.lr.lineno, e.lr.l), file=sys.stderr)
sys.exit(1)
f = actions.get(args.action, None)
if not f:
print("Action {0} is unknown".format(args.action), file=sys.stderr)
sys.exit(1)
f()
if __name__ == "__main__":
main()