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nsiqcppstyle_lexer.py
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nsiqcppstyle_lexer.py
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# -----------------------------------------------------------------------------
# ply: lex.py
#
# Copyright (C) 2001-2009,
# David M. Beazley (Dabeaz LLC)
# All rights reserved.
#
# Redistribution and use in source and binary forms, with or without
# modification, are permitted provided that the following conditions are
# met:
#
# * Redistributions of source code must retain the above copyright notice,
# this list of conditions and the following disclaimer.
# * Redistributions in binary form must reproduce the above copyright notice,
# this list of conditions and the following disclaimer in the documentation
# and/or other materials provided with the distribution.
# * Neither the name of the David Beazley or Dabeaz LLC may be used to
# endorse or promote products derived from this software without
# specific prior written permission.
#
# THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
# "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
# LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
# A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
# OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
# SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
# LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
# DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
# THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
# (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
# OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
# -----------------------------------------------------------------------------
__version__ = "3.2"
__tabversion__ = "3.2" # Version of table file used
import copy
import re
import types
from nsiqcppstyle_util import *
# This tuple contains known string types
StringTypes = (str, bytes)
# Extract the code attribute of a function.
def func_code(f):
return f.__code__
# This regular expression is used to match valid token names
_is_identifier = re.compile(r"^[a-zA-Z0-9_]+$")
# Exception thrown when invalid token encountered and no default error
# handler is defined.
class LexError(Exception):
def __init__(self, message, s):
self.args = (message,)
self.text = s
# Token class. This class is used to represent the tokens produced.
class LexToken:
def __str__(self):
return "LexToken(%s,%r,%d,%d,%d, %s, %s)" % (
self.type,
self.value,
self.lineno,
self.column,
self.lexpos,
self.inactive,
self.pp,
)
def __repr__(self):
return str(self)
# This object is a stand-in for a logging object created by the
# logging module.
class PlyLogger:
def __init__(self, f):
self.f = f
def critical(self, msg, *args, **kwargs):
self.f.write((msg % args) + "\n")
def warning(self, msg, *args, **kwargs):
self.f.write("WARNING: " + (msg % args) + "\n")
def error(self, msg, *args, **kwargs):
self.f.write("ERROR: " + (msg % args) + "\n")
info = critical
debug = critical
# Null logger is used when no output is generated. Does nothing.
class NullLogger:
def __getattribute__(self, name):
return self
def __call__(self, *args, **kwargs):
return self
# -----------------------------------------------------------------------------
# === Lexing Engine ===
#
# The following Lexer class implements the lexer runtime. There are only
# a few public methods and attributes:
#
# input() - Store a new string in the lexer
# token() - Get the next token
# clone() - Clone the lexer
#
# lineno - Current line number
# lexpos - Current position in the input string
# -----------------------------------------------------------------------------
class Lexer:
def __init__(self):
self.lexre = None # Master regular expression. This is a list of
self.lexretext = None # Current regular expression strings
self.lexstatere = {} # Dictionary mapping lexer states to master regexs
self.lexstateretext = {} # Dictionary mapping lexer states to regex strings
self.lexstaterenames = {} # Dictionary mapping lexer states to symbol names
self.lexstate = "INITIAL" # Current lexer state
self.lexstatestack = [] # Stack of lexer states
self.lexstateinfo = None # State information
self.lexstateignore = {} # Dictionary of ignored characters for each state
self.lexstateerrorf = {} # Dictionary of error functions for each state
self.lexreflags = 0 # Optional re compile flags
self.lexdata = None # Actual input data (as a string)
self.lexpos = 0 # Current position in input text
self.lexlen = 0 # Length of the input text
self.lexerrorf = None # Error rule (if any)
self.lextokens = None # List of valid tokens
self.lexignore = "" # Ignored characters
self.lexliterals = "" # Literal characters that can be passed through
self.lexmodule = None # Module
self.lineno = 1 # Current line number
self.lexoptimize = 0 # Optimized mode
def clone(self, object=None):
c = copy.copy(self)
# If the object parameter has been supplied, it means we are attaching the
# lexer to a new object. In this case, we have to rebind all methods in
# the lexstatere and lexstateerrorf tables.
if object:
newtab = {}
for key, ritem in self.lexstatere.items():
newre = []
for cre, findex in ritem:
newfindex = []
for f in findex:
if not f or not f[0]:
newfindex.append(f)
continue
newfindex.append((getattr(object, f[0].__name__), f[1]))
newre.append((cre, newfindex))
newtab[key] = newre
c.lexstatere = newtab
c.lexstateerrorf = {}
for key, ef in self.lexstateerrorf.items():
c.lexstateerrorf[key] = getattr(object, ef.__name__)
c.lexmodule = object
return c
# ------------------------------------------------------------
# _writetab_impl() - Perform actual file write of lexer
# information to a table file
# ------------------------------------------------------------
def _writetab_impl(self, tabfile, tf):
tf.write(f"# {tabfile}.py. This file automatically created by PLY (version {__version__}). Don't edit!\n")
tf.write(f"_tabversion = {__version__!r}\n")
tf.write(f"_lextokens = {self.lextokens!r}\n")
tf.write(f"_lexreflags = {self.lexreflags!r}\n")
tf.write(f"_lexliterals = {self.lexliterals!r}\n")
tf.write(f"_lexstateinfo = {self.lexstateinfo!r}\n")
tabre = {}
# Collect all functions in the initial state
initial = self.lexstatere["INITIAL"]
initialfuncs = []
for part in initial:
for f in part[1]:
if f and f[0]:
initialfuncs.append(f)
for key, lre in self.lexstatere.items():
titem = []
for i in range(len(lre)):
titem.append((self.lexstateretext[key][i], _funcs_to_names(lre[i][1], self.lexstaterenames[key][i])))
tabre[key] = titem
tf.write(f"_lexstatere = {tabre!r}\n")
tf.write(f"_lexstateignore = {self.lexstateignore!r}\n")
taberr = {}
for key, ef in self.lexstateerrorf.items():
if ef:
taberr[key] = ef.__name__
else:
taberr[key] = None
tf.write(f"_lexstateerrorf = {taberr!r}\n")
# ------------------------------------------------------------
# writetab() - Write lexer information to a table file
# ------------------------------------------------------------
def writetab(self, tabfile, outputdir=""):
if isinstance(tabfile, types.ModuleType):
return
basetabfilename = tabfile.split(".")[-1]
filename = os.path.join(outputdir, basetabfilename) + ".py"
with open(filename, "w") as tf:
self._writetab_impl(tabfile, tf)
# ------------------------------------------------------------
# readtab() - Read lexer information from a tab file
# ------------------------------------------------------------
def readtab(self, tabfile, fdict):
if isinstance(tabfile, types.ModuleType):
lextab = tabfile
elif sys.version_info[0] < 3:
exec(f"import {tabfile} as lextab")
else:
env = {}
exec(f"import {tabfile} as lextab", env, env)
lextab = env["lextab"]
if getattr(lextab, "_tabversion", "0.0") != __version__:
msg = "Inconsistent PLY version"
raise ImportError(msg)
self.lextokens = lextab._lextokens
self.lexreflags = lextab._lexreflags
self.lexliterals = lextab._lexliterals
self.lexstateinfo = lextab._lexstateinfo
self.lexstateignore = lextab._lexstateignore
self.lexstatere = {}
self.lexstateretext = {}
for key, lre in lextab._lexstatere.items():
titem = []
txtitem = []
for i in range(len(lre)):
titem.append((re.compile(lre[i][0], lextab._lexreflags), _names_to_funcs(lre[i][1], fdict)))
txtitem.append(lre[i][0])
self.lexstatere[key] = titem
self.lexstateretext[key] = txtitem
self.lexstateerrorf = {}
for key, ef in lextab._lexstateerrorf.items():
self.lexstateerrorf[key] = fdict[ef]
self.begin("INITIAL")
# ------------------------------------------------------------
# input() - Push a new string into the lexer
# ------------------------------------------------------------
def input(self, s):
# Pull off the first character to see if s looks like a string
c = s[:1]
if not isinstance(c, StringTypes):
msg = "Expected a string"
raise ValueError(msg)
self.lexdata = s
self.lexpos = 0
self.lexlen = len(s)
# ------------------------------------------------------------
# begin() - Changes the lexing state
# ------------------------------------------------------------
def begin(self, state):
if state not in self.lexstatere:
msg = "Undefined state"
raise ValueError(msg)
self.lexre = self.lexstatere[state]
self.lexretext = self.lexstateretext[state]
self.lexignore = self.lexstateignore.get(state, "")
self.lexerrorf = self.lexstateerrorf.get(state, None)
self.lexstate = state
# ------------------------------------------------------------
# push_state() - Changes the lexing state and saves old on stack
# ------------------------------------------------------------
def push_state(self, state):
self.lexstatestack.append(self.lexstate)
self.begin(state)
# ------------------------------------------------------------
# pop_state() - Restores the previous state
# ------------------------------------------------------------
def pop_state(self):
self.begin(self.lexstatestack.pop())
# ------------------------------------------------------------
# current_state() - Returns the current lexing state
# ------------------------------------------------------------
def current_state(self):
return self.lexstate
# ------------------------------------------------------------
# skip() - Skip ahead n characters
# ------------------------------------------------------------
def skip(self, n):
self.lexpos += n
# ------------------------------------------------------------
# opttoken() - Return the next token from the Lexer
#
# Note: This function has been carefully implemented to be as fast
# as possible. Don't make changes unless you really know what
# you are doing
# ------------------------------------------------------------
def token(self):
# Make local copies of frequently referenced attributes
lexpos = self.lexpos
lexlen = self.lexlen
lexignore = self.lexignore
lexdata = self.lexdata
while lexpos < lexlen:
# This code provides some short-circuit code for whitespace, tabs,
# and other ignored characters
if lexdata[lexpos] in lexignore:
lexpos += 1
continue
# Look for a regular expression match
for lexre, lexindexfunc in self.lexre:
m = lexre.match(lexdata, lexpos)
if not m:
continue
# Create a token for return
tok = LexToken()
tok.additional = ""
tok.value = m.group()
tok.lineno = self.lineno
tok.lexpos = lexpos
i = m.lastindex
func, tok.type = lexindexfunc[i]
if not func:
# If no token type was set, it's an ignored token
if tok.type:
self.lexpos = m.end()
return tok
lexpos = m.end()
break
lexpos = m.end()
# If token is processed by a function, call it
tok.lexer = self # Set additional attributes useful in token rules
self.lexmatch = m
self.lexpos = lexpos
newtok = func(tok)
# Every function must return a token, if nothing, we just move
# to next token
if not newtok:
# This is here in case user has updated lexpos.
lexpos = self.lexpos
lexignore = self.lexignore # This is here in case there was a state change
break
# Verify type of the token. If not in the token map, raise an
# error
if not self.lexoptimize and newtok.type not in self.lextokens:
raise LexError(
"%s:%d: Rule '%s' returned an unknown token type '%s'"
% (func_code(func).co_filename, func_code(func).co_firstlineno, func.__name__, newtok.type),
lexdata[lexpos:],
)
return newtok
else:
# No match, see if in literals
if lexdata[lexpos] in self.lexliterals:
tok = LexToken()
tok.value = lexdata[lexpos]
tok.lineno = self.lineno
tok.type = tok.value
tok.lexpos = lexpos
self.lexpos = lexpos + 1
return tok
# No match. Call t_error() if defined.
if self.lexerrorf:
tok = LexToken()
tok.value = self.lexdata[lexpos:]
tok.lineno = self.lineno
tok.type = "error"
tok.lexer = self
tok.lexpos = lexpos
self.lexpos = lexpos
newtok = self.lexerrorf(tok)
if lexpos == self.lexpos:
# Error method didn't change text position at all. This
# is an error.
msg = f"Scanning error. Illegal character '{lexdata[lexpos]}'"
raise LexError(msg, lexdata[lexpos:])
lexpos = self.lexpos
if not newtok:
continue
return newtok
self.lexpos = lexpos
raise LexError("Illegal character '%s' at index %d" % (lexdata[lexpos], lexpos), lexdata[lexpos:])
self.lexpos = lexpos + 1
if self.lexdata is None:
msg = "No input string given with input()"
raise RuntimeError(msg)
return None
# Iterator interface
def __iter__(self):
return self
def next(self):
t = self.token()
if t is None:
raise StopIteration
return t
__next__ = next
# -----------------------------------------------------------------------------
# ==== Lex Builder ===
#
# The functions and classes below are used to collect lexing information
# and build a Lexer object from it.
# -----------------------------------------------------------------------------
# -----------------------------------------------------------------------------
# get_caller_module_dict()
#
# This function returns a dictionary containing all of the symbols defined within
# a caller further down the call stack. This is used to get the environment
# associated with the yacc() call if none was provided.
# -----------------------------------------------------------------------------
def get_caller_module_dict(levels):
try:
raise RuntimeError
except RuntimeError:
e, b, t = sys.exc_info() # @UnusedVariable
f = t.tb_frame
while levels > 0:
f = f.f_back
levels -= 1
ldict = f.f_globals.copy()
if f.f_globals != f.f_locals:
ldict.update(f.f_locals)
return ldict
# -----------------------------------------------------------------------------
# _funcs_to_names()
#
# Given a list of regular expression functions, this converts it to a list
# suitable for output to a table file
# -----------------------------------------------------------------------------
def _funcs_to_names(funclist, namelist):
result = []
for f, name in zip(funclist, namelist):
if f and f[0]:
result.append((name, f[1]))
else:
result.append(f)
return result
# -----------------------------------------------------------------------------
# _names_to_funcs()
#
# Given a list of regular expression function names, this converts it back to
# functions.
# -----------------------------------------------------------------------------
def _names_to_funcs(namelist, fdict):
result = []
for n in namelist:
if n and n[0]:
result.append((fdict[n[0]], n[1]))
else:
result.append(n)
return result
# -----------------------------------------------------------------------------
# _form_master_re()
#
# This function takes a list of all of the regex components and attempts to
# form the master regular expression. Given limitations in the Python re
# module, it may be necessary to break the master regex into separate expressions.
# -----------------------------------------------------------------------------
def _form_master_re(relist, reflags, ldict, toknames):
if not relist:
return []
regex = "|".join(relist)
try:
lexre = re.compile(regex, re.VERBOSE | reflags)
# Build the index to function map for the matching engine
lexindexfunc = [None] * (max(lexre.groupindex.values()) + 1)
lexindexnames = lexindexfunc[:]
for f, i in lexre.groupindex.items():
handle = ldict.get(f, None)
if type(handle) in (types.FunctionType, types.MethodType):
lexindexfunc[i] = (handle, toknames[f])
lexindexnames[i] = f
elif handle is not None:
lexindexnames[i] = f
if f.find("ignore_") > 0:
lexindexfunc[i] = (None, None)
else:
lexindexfunc[i] = (None, toknames[f])
return [(lexre, lexindexfunc)], [regex], [lexindexnames]
except Exception:
m = int(len(relist) / 2)
if m == 0:
m = 1
llist, lre, lnames = _form_master_re(relist[:m], reflags, ldict, toknames)
rlist, rre, rnames = _form_master_re(relist[m:], reflags, ldict, toknames)
return llist + rlist, lre + rre, lnames + rnames
# -----------------------------------------------------------------------------
# def _statetoken(s,names)
#
# Given a declaration name s of the form "t_" and a dictionary whose keys are
# state names, this function returns a tuple (states,tokenname) where states
# is a tuple of state names and tokenname is the name of the token. For example,
# calling this with s = "t_foo_bar_SPAM" might return (('foo','bar'),'SPAM')
# -----------------------------------------------------------------------------
def _statetoken(s, names):
parts = s.split("_")
for i in range(1, len(parts)):
if parts[i] not in names and parts[i] != "ANY":
break
states = tuple(parts[1:i]) if i > 1 else ("INITIAL",)
if "ANY" in states:
states = tuple(names)
tokenname = "_".join(parts[i:])
return (states, tokenname)
# -----------------------------------------------------------------------------
# LexerReflect()
#
# This class represents information needed to build a lexer as extracted from a
# user's input file.
# -----------------------------------------------------------------------------
class LexerReflect:
def __init__(self, ldict, log=None, reflags=0):
self.ldict = ldict
self.error_func = None
self.tokens = []
self.reflags = reflags
self.stateinfo = {"INITIAL": "inclusive"}
self.files = {}
self.error = 0
if log is None:
self.log = PlyLogger(sys.stderr)
else:
self.log = log
# Get all of the basic information
def get_all(self):
self.get_tokens()
self.get_literals()
self.get_states()
self.get_rules()
# Validate all of the information
def validate_all(self):
self.validate_tokens()
self.validate_literals()
self.validate_rules()
return self.error
# Get the tokens map
def get_tokens(self):
tokens = self.ldict.get("tokens", None)
if not tokens:
self.log.error("No token list is defined")
self.error = 1
return
if not isinstance(tokens, (list, tuple)):
self.log.error("tokens must be a list or tuple")
self.error = 1
return
if not tokens:
self.log.error("tokens is empty")
self.error = 1
return
self.tokens = tokens
# Validate the tokens
def validate_tokens(self):
terminals = {}
for n in self.tokens:
if not _is_identifier.match(n):
self.log.error("Bad token name '%s'", n)
self.error = 1
if n in terminals:
self.log.warning("Token '%s' multiply defined", n)
terminals[n] = 1
# Get the literals specifier
def get_literals(self):
self.literals = self.ldict.get("literals", "")
# Validate literals
def validate_literals(self):
try:
for c in self.literals:
if not isinstance(c, StringTypes) or len(c) > 1:
self.log.error("Invalid literal %s. Must be a single character", repr(c))
self.error = 1
continue
except TypeError:
self.log.exception("Invalid literals specification. literals must be a sequence of characters")
self.error = 1
def get_states(self):
self.states = self.ldict.get("states", None)
# Build statemap
if self.states:
if not isinstance(self.states, (tuple, list)):
self.log.error("states must be defined as a tuple or list")
self.error = 1
else:
for s in self.states:
if not isinstance(s, tuple) or len(s) != 2:
self.log.error(
"Invalid state specifier %s. Must be a tuple (statename,'exclusive|inclusive')",
repr(s),
)
self.error = 1
continue
name, statetype = s
if not isinstance(name, StringTypes):
self.log.error("State name %s must be a string", repr(name))
self.error = 1
continue
if statetype not in ("inclusive", "exclusive"):
self.log.error("State type for state %s must be 'inclusive' or 'exclusive'", name)
self.error = 1
continue
if name in self.stateinfo:
self.log.error("State '%s' already defined", name)
self.error = 1
continue
self.stateinfo[name] = statetype
# Get all of the symbols with a t_ prefix and sort them into various
# categories (functions, strings, error functions, and ignore characters)
def get_rules(self):
tsymbols = [f for f in self.ldict if f[:2] == "t_"]
# Now build up a list of functions and a list of strings
self.toknames = {} # Mapping of symbols to token names
self.funcsym = {} # Symbols defined as functions
self.strsym = {} # Symbols defined as strings
self.ignore = {} # Ignore strings by state
self.errorf = {} # Error functions by state
for s in self.stateinfo:
self.funcsym[s] = []
self.strsym[s] = []
if len(tsymbols) == 0:
self.log.error("No rules of the form t_rulename are defined")
self.error = 1
return
for f in tsymbols:
t = self.ldict[f]
states, tokname = _statetoken(f, self.stateinfo)
self.toknames[f] = tokname
if callable(t):
if tokname == "error":
for s in states:
self.errorf[s] = t
elif tokname == "ignore":
line = func_code(t).co_firstlineno
file = func_code(t).co_filename
self.log.error("%s:%d: Rule '%s' must be defined as a string", file, line, t.__name__)
self.error = 1
else:
for s in states:
self.funcsym[s].append((f, t))
elif isinstance(t, StringTypes):
if tokname == "ignore":
for s in states:
self.ignore[s] = t
if "\\" in t:
self.log.warning("%s contains a literal backslash '\\'", f)
elif tokname == "error":
self.log.error("Rule '%s' must be defined as a function", f)
self.error = 1
else:
for s in states:
self.strsym[s].append((f, t))
else:
self.log.error("%s not defined as a function or string", f)
self.error = 1
# Sort the functions by line number
for f in self.funcsym.values():
if sys.version_info[0] < 3:
f.sort(lambda x, y: CmpObjects(func_code(x[1]).co_firstlineno, func_code(y[1]).co_firstlineno))
else:
# Python 3.0
f.sort(key=lambda x: func_code(x[1]).co_firstlineno)
# Sort the strings by regular expression length
for s in self.strsym.values():
if sys.version_info[0] < 3:
s.sort(lambda x, y: (len(x[1]) < len(y[1])) - (len(x[1]) > len(y[1])))
else:
# Python 3.0
s.sort(key=lambda x: len(x[1]), reverse=True)
# Validate all of the t_rules collected
def validate_rules(self):
for state in self.stateinfo:
# Validate all rules defined by functions
for fname, f in self.funcsym[state]:
line = func_code(f).co_firstlineno
file = func_code(f).co_filename
self.files[file] = 1
tokname = self.toknames[fname]
reqargs = 2 if isinstance(f, types.MethodType) else 1
nargs = func_code(f).co_argcount
if nargs > reqargs:
self.log.error("%s:%d: Rule '%s' has too many arguments", file, line, f.__name__)
self.error = 1
continue
if nargs < reqargs:
self.log.error("%s:%d: Rule '%s' requires an argument", file, line, f.__name__)
self.error = 1
continue
if not f.__doc__:
self.log.error("%s:%d: No regular expression defined for rule '%s'", file, line, f.__name__)
self.error = 1
continue
try:
c = re.compile(f"(?P<{fname}>{f.__doc__})", re.VERBOSE | self.reflags)
if c.match(""):
self.log.error(
"%s:%d: Regular expression for rule '%s' matches empty string",
file,
line,
f.__name__,
)
self.error = 1
except re.error:
_etype, e, _etrace = sys.exc_info()
self.log.exception("%s:%d: Invalid regular expression for rule '%s'. %s", file, line, f.__name__, e)
if "#" in f.__doc__:
self.log.exception(
"%s:%d. Make sure '#' in rule '%s' is escaped with '\\#'",
file,
line,
f.__name__,
)
self.error = 1
# Validate all rules defined by strings
for name, r in self.strsym[state]:
tokname = self.toknames[name]
if tokname == "error":
self.log.error("Rule '%s' must be defined as a function", name)
self.error = 1
continue
if tokname not in self.tokens and tokname.find("ignore_") < 0:
self.log.error("Rule '%s' defined for an unspecified token %s", name, tokname)
self.error = 1
continue
try:
c = re.compile(f"(?P<{name}>{r})", re.VERBOSE | self.reflags)
if c.match(""):
self.log.error("Regular expression for rule '%s' matches empty string", name)
self.error = 1
except re.error:
_etype, e, _etrace = sys.exc_info()
self.log.exception("Invalid regular expression for rule '%s'. %s", name, e)
if "#" in r:
self.log.exception("Make sure '#' in rule '%s' is escaped with '\\#'", name)
self.error = 1
if not self.funcsym[state] and not self.strsym[state]:
self.log.error("No rules defined for state '%s'", state)
self.error = 1
# Validate the error function
efunc = self.errorf.get(state, None)
if efunc:
f = efunc
line = func_code(f).co_firstlineno
file = func_code(f).co_filename
self.files[file] = 1
reqargs = 2 if isinstance(f, types.MethodType) else 1
nargs = func_code(f).co_argcount
if nargs > reqargs:
self.log.error("%s:%d: Rule '%s' has too many arguments", file, line, f.__name__)
self.error = 1
if nargs < reqargs:
self.log.error("%s:%d: Rule '%s' requires an argument", file, line, f.__name__)
self.error = 1
for f in self.files:
self.validate_file(f)
# -----------------------------------------------------------------------------
# validate_file()
#
# This checks to see if there are duplicated t_rulename() functions or strings
# in the parser input file. This is done using a simple regular expression
# match on each line in the given file.
# -----------------------------------------------------------------------------
def validate_file(self, filename):
import os.path # @Reimport
base, ext = os.path.splitext(filename) # @UnusedVariable
if ext != ".py":
return # No idea what the file is. Return OK
try:
with open(filename) as f:
lines = f.readlines()
except UnicodeDecodeError as ex:
console.Out.Ci("[ERROR] UnicodeDecodeError in validate_file: " + str(ex))
console.Out.Ci(f"[ERROR] Exception occurred reading file '{filename}', convert from UTF16LE to UTF8")
raise
except OSError:
return # Couldn't find the file. Don't worry about it
fre = re.compile(r"\s*def\s+(t_[a-zA-Z_0-9]*)\(")
sre = re.compile(r"\s*(t_[a-zA-Z_0-9]*)\s*=")
counthash = {}
linen = 1
for l in lines:
m = fre.match(l)
if not m:
m = sre.match(l)
if m:
name = m.group(1)
prev = counthash.get(name)
if not prev:
counthash[name] = linen
else:
self.log.error(
"%s:%d: Rule %s redefined. Previously defined on line %d",
filename,
linen,
name,
prev,
)
self.error = 1
linen += 1
# -----------------------------------------------------------------------------
# lex(module)
#
# Build all of the regular expression rules from definitions in the supplied module
# -----------------------------------------------------------------------------
def lex(
module=None,
object=None,
debug=0,
optimize=0,
lextab="lextab",
reflags=0,
nowarn=0,
outputdir="",
debuglog=None,
errorlog=None,
):
global lexer
ldict = None
stateinfo = {"INITIAL": "inclusive"} # @UnusedVariable
lexobj = Lexer()
lexobj.lexoptimize = optimize
global token, input
if errorlog is None:
errorlog = PlyLogger(sys.stderr)
if debug and debuglog is None:
debuglog = PlyLogger(sys.stderr)
# Get the module dictionary used for the lexer
if object:
module = object
if module:
_items = [(k, getattr(module, k)) for k in dir(module)]
ldict = dict(_items)
else:
ldict = get_caller_module_dict(2)
# Collect parser information from the dictionary
linfo = LexerReflect(ldict, log=errorlog, reflags=reflags)
linfo.get_all()
if not optimize and linfo.validate_all():
msg = "Can't build lexer"
raise SyntaxError(msg)
if optimize and lextab:
try:
lexobj.readtab(lextab, ldict)
token = lexobj.token
input = lexobj.input
lexer = lexobj
return lexobj
except ImportError:
pass
# Dump some basic debugging information
if debug:
debuglog.info("lex: tokens = %r", linfo.tokens)
debuglog.info("lex: literals = %r", linfo.literals)
debuglog.info("lex: states = %r", linfo.stateinfo)
# Build a dictionary of valid token names
lexobj.lextokens = {}
for n in linfo.tokens:
lexobj.lextokens[n] = 1
# Get literals specification
if isinstance(linfo.literals, (list, tuple)):
lexobj.lexliterals = type(linfo.literals[0])().join(linfo.literals)
else:
lexobj.lexliterals = linfo.literals
# Get the stateinfo dictionary
stateinfo = linfo.stateinfo
regexs = {}
# Build the master regular expressions
for state in stateinfo: