Lib/idlelib/pyparse.py - platform/external/python/cpython3 - Gitiles

 from collections import Mapping
 import re
 import sys

 # Reason last stmt is continued (or C_NONE if it's not).
 (C_NONE, C_BACKSLASH, C_STRING_FIRST_LINE,
  C_STRING_NEXT_LINES, C_BRACKET) = range(5)

 if 0:   # for throwaway debugging output
     def dump(*stuff):
         sys.__stdout__.write(" ".join(map(str, stuff)) + "\n")

 # Find what looks like the start of a popular stmt.

 _synchre = re.compile(r"""
     ^
     [ \t]*
     (?: while
     |   else
     |   def
     |   return
     |   assert
     |   break
     |   class
     |   continue
     |   elif
     |   try
     |   except
     |   raise
     |   import
     |   yield
     )
     \b
 """, re.VERBOSE | re.MULTILINE).search

 # Match blank line or non-indenting comment line.

 _junkre = re.compile(r"""
     [ \t]*
     (?: \# \S .* )?
     \n
 """, re.VERBOSE).match

 # Match any flavor of string; the terminating quote is optional
 # so that we're robust in the face of incomplete program text.

 _match_stringre = re.compile(r"""
     \""" [^"\\]* (?:
                      (?: \\. | "(?!"") )
                      [^"\\]*
                  )*
     (?: \""" )?

 |   " [^"\\\n]* (?: \\. [^"\\\n]* )* "?

 |   ''' [^'\\]* (?:
                    (?: \\. | '(?!'') )
                    [^'\\]*
                 )*
     (?: ''' )?

 |   ' [^'\\\n]* (?: \\. [^'\\\n]* )* '?
 """, re.VERBOSE | re.DOTALL).match

 # Match a line that starts with something interesting;
 # used to find the first item of a bracket structure.

 _itemre = re.compile(r"""
     [ \t]*
     [^\s#\\]    # if we match, m.end()-1 is the interesting char
 """, re.VERBOSE).match

 # Match start of stmts that should be followed by a dedent.

 _closere = re.compile(r"""
     \s*
     (?: return
     |   break
     |   continue
     |   raise
     |   pass
     )
     \b
 """, re.VERBOSE).match

 # Chew up non-special chars as quickly as possible.  If match is
 # successful, m.end() less 1 is the index of the last boring char
 # matched.  If match is unsuccessful, the string starts with an
 # interesting char.

 _chew_ordinaryre = re.compile(r"""
     [^[\](){}#'"\\]+
 """, re.VERBOSE).match


 class StringTranslatePseudoMapping(Mapping):
     r"""Utility class to be used with str.translate()

     This Mapping class wraps a given dict. When a value for a key is
     requested via __getitem__() or get(), the key is looked up in the
     given dict. If found there, the value from the dict is returned.
     Otherwise, the default value given upon initialization is returned.

     This allows using str.translate() to make some replacements, and to
     replace all characters for which no replacement was specified with
     a given character instead of leaving them as-is.

     For example, to replace everything except whitespace with 'x':

     >>> whitespace_chars = ' \t\n\r'
     >>> preserve_dict = {ord(c): ord(c) for c in whitespace_chars}
     >>> mapping = StringTranslatePseudoMapping(preserve_dict, ord('x'))
     >>> text = "a + b\tc\nd"
     >>> text.translate(mapping)
     'x x x\tx\nx'
     """
     def __init__(self, non_defaults, default_value):
         self._non_defaults = non_defaults
         self._default_value = default_value

         def _get(key, _get=non_defaults.get, _default=default_value):
             return _get(key, _default)
         self._get = _get

     def __getitem__(self, item):
         return self._get(item)

     def __len__(self):
         return len(self._non_defaults)

     def __iter__(self):
         return iter(self._non_defaults)

     def get(self, key, default=None):
         return self._get(key)


 class Parser:

     def __init__(self, indentwidth, tabwidth):
         self.indentwidth = indentwidth
         self.tabwidth = tabwidth

     def set_str(self, s):
         assert len(s) == 0 or s[-1] == '\n'
         self.str = s
         self.study_level = 0

     # Return index of a good place to begin parsing, as close to the
     # end of the string as possible.  This will be the start of some
     # popular stmt like "if" or "def".  Return None if none found:
     # the caller should pass more prior context then, if possible, or
     # if not (the entire program text up until the point of interest
     # has already been tried) pass 0 to set_lo.
     #
     # This will be reliable iff given a reliable is_char_in_string
     # function, meaning that when it says "no", it's absolutely
     # guaranteed that the char is not in a string.

     def find_good_parse_start(self, is_char_in_string=None,
                               _synchre=_synchre):
         str, pos = self.str, None

         if not is_char_in_string:
             # no clue -- make the caller pass everything
             return None

         # Peek back from the end for a good place to start,
         # but don't try too often; pos will be left None, or
         # bumped to a legitimate synch point.
         limit = len(str)
         for tries in range(5):
             i = str.rfind(":\n", 0, limit)
             if i < 0:
                 break
             i = str.rfind('\n', 0, i) + 1  # start of colon line
             m = _synchre(str, i, limit)
             if m and not is_char_in_string(m.start()):
                 pos = m.start()
                 break
             limit = i
         if pos is None:
             # Nothing looks like a block-opener, or stuff does
             # but is_char_in_string keeps returning true; most likely
             # we're in or near a giant string, the colorizer hasn't
             # caught up enough to be helpful, or there simply *aren't*
             # any interesting stmts.  In any of these cases we're
             # going to have to parse the whole thing to be sure, so
             # give it one last try from the start, but stop wasting
             # time here regardless of the outcome.
             m = _synchre(str)
             if m and not is_char_in_string(m.start()):
                 pos = m.start()
             return pos

         # Peeking back worked; look forward until _synchre no longer
         # matches.
         i = pos + 1
         while 1:
             m = _synchre(str, i)
             if m:
                 s, i = m.span()
                 if not is_char_in_string(s):
                     pos = s
             else:
                 break
         return pos

     # Throw away the start of the string.  Intended to be called with
     # find_good_parse_start's result.

     def set_lo(self, lo):
         assert lo == 0 or self.str[lo-1] == '\n'
         if lo > 0:
             self.str = self.str[lo:]

     # Build a translation table to map uninteresting chars to 'x', open
     # brackets to '(', close brackets to ')' while preserving quotes,
     # backslashes, newlines and hashes. This is to be passed to
     # str.translate() in _study1().
     _tran = {}
     _tran.update((ord(c), ord('(')) for c in "({[")
     _tran.update((ord(c), ord(')')) for c in ")}]")
     _tran.update((ord(c), ord(c)) for c in "\"'\\\n#")
     _tran = StringTranslatePseudoMapping(_tran, default_value=ord('x'))

     # As quickly as humanly possible <wink>, find the line numbers (0-
     # based) of the non-continuation lines.
     # Creates self.{goodlines, continuation}.

     def _study1(self):
         if self.study_level >= 1:
             return
         self.study_level = 1

         # Map all uninteresting characters to "x", all open brackets
         # to "(", all close brackets to ")", then collapse runs of
         # uninteresting characters.  This can cut the number of chars
         # by a factor of 10-40, and so greatly speed the following loop.
         str = self.str
         str = str.translate(self._tran)
         str = str.replace('xxxxxxxx', 'x')
         str = str.replace('xxxx', 'x')
         str = str.replace('xx', 'x')
         str = str.replace('xx', 'x')
         str = str.replace('\nx', '\n')
         # note that replacing x\n with \n would be incorrect, because
         # x may be preceded by a backslash

         # March over the squashed version of the program, accumulating
         # the line numbers of non-continued stmts, and determining
         # whether & why the last stmt is a continuation.
         continuation = C_NONE
         level = lno = 0     # level is nesting level; lno is line number
         self.goodlines = goodlines = [0]
         push_good = goodlines.append
         i, n = 0, len(str)
         while i < n:
             ch = str[i]
             i = i+1

             # cases are checked in decreasing order of frequency
             if ch == 'x':
                 continue

             if ch == '\n':
                 lno = lno + 1
                 if level == 0:
                     push_good(lno)
                     # else we're in an unclosed bracket structure
                 continue

             if ch == '(':
                 level = level + 1
                 continue

             if ch == ')':
                 if level:
                     level = level - 1
                     # else the program is invalid, but we can't complain
                 continue

             if ch == '"' or ch == "'":
                 # consume the string
                 quote = ch
                 if str[i-1:i+2] == quote * 3:
                     quote = quote * 3
                 firstlno = lno
                 w = len(quote) - 1
                 i = i+w
                 while i < n:
                     ch = str[i]
                     i = i+1

                     if ch == 'x':
                         continue

                     if str[i-1:i+w] == quote:
                         i = i+w
                         break

                     if ch == '\n':
                         lno = lno + 1
                         if w == 0:
                             # unterminated single-quoted string
                             if level == 0:
                                 push_good(lno)
                             break
                         continue

                     if ch == '\\':
                         assert i < n
                         if str[i] == '\n':
                             lno = lno + 1
                         i = i+1
                         continue

                     # else comment char or paren inside string

                 else:
                     # didn't break out of the loop, so we're still
                     # inside a string
                     if (lno - 1) == firstlno:
                         # before the previous \n in str, we were in the first
                         # line of the string
                         continuation = C_STRING_FIRST_LINE
                     else:
                         continuation = C_STRING_NEXT_LINES
                 continue    # with outer loop

             if ch == '#':
                 # consume the comment
                 i = str.find('\n', i)
                 assert i >= 0
                 continue

             assert ch == '\\'
             assert i < n
             if str[i] == '\n':
                 lno = lno + 1
                 if i+1 == n:
                     continuation = C_BACKSLASH
             i = i+1

         # The last stmt may be continued for all 3 reasons.
         # String continuation takes precedence over bracket
         # continuation, which beats backslash continuation.
         if (continuation != C_STRING_FIRST_LINE
             and continuation != C_STRING_NEXT_LINES and level > 0):
             continuation = C_BRACKET
         self.continuation = continuation

         # Push the final line number as a sentinel value, regardless of
         # whether it's continued.
         assert (continuation == C_NONE) == (goodlines[-1] == lno)
         if goodlines[-1] != lno:
             push_good(lno)

     def get_continuation_type(self):
         self._study1()
         return self.continuation

     # study1 was sufficient to determine the continuation status,
     # but doing more requires looking at every character.  study2
     # does this for the last interesting statement in the block.
     # Creates:
     #     self.stmt_start, stmt_end
     #         slice indices of last interesting stmt
     #     self.stmt_bracketing
     #         the bracketing structure of the last interesting stmt;
     #         for example, for the statement "say(boo) or die", stmt_bracketing
     #         will be [(0, 0), (3, 1), (8, 0)]. Strings and comments are
     #         treated as brackets, for the matter.
     #     self.lastch
     #         last non-whitespace character before optional trailing
     #         comment
     #     self.lastopenbracketpos
     #         if continuation is C_BRACKET, index of last open bracket

     def _study2(self):
         if self.study_level >= 2:
             return
         self._study1()
         self.study_level = 2

         # Set p and q to slice indices of last interesting stmt.
         str, goodlines = self.str, self.goodlines
         i = len(goodlines) - 1
         p = len(str)    # index of newest line
         while i:
             assert p
             # p is the index of the stmt at line number goodlines[i].
             # Move p back to the stmt at line number goodlines[i-1].
             q = p
             for nothing in range(goodlines[i-1], goodlines[i]):
                 # tricky: sets p to 0 if no preceding newline
                 p = str.rfind('\n', 0, p-1) + 1
             # The stmt str[p:q] isn't a continuation, but may be blank
             # or a non-indenting comment line.
             if  _junkre(str, p):
                 i = i-1
             else:
                 break
         if i == 0:
             # nothing but junk!
             assert p == 0
             q = p
         self.stmt_start, self.stmt_end = p, q

         # Analyze this stmt, to find the last open bracket (if any)
         # and last interesting character (if any).
         lastch = ""
         stack = []  # stack of open bracket indices
         push_stack = stack.append
         bracketing = [(p, 0)]
         while p < q:
             # suck up all except ()[]{}'"#\\
             m = _chew_ordinaryre(str, p, q)
             if m:
                 # we skipped at least one boring char
                 newp = m.end()
                 # back up over totally boring whitespace
                 i = newp - 1    # index of last boring char
                 while i >= p and str[i] in " \t\n":
                     i = i-1
                 if i >= p:
                     lastch = str[i]
                 p = newp
                 if p >= q:
                     break

             ch = str[p]

             if ch in "([{":
                 push_stack(p)
                 bracketing.append((p, len(stack)))
                 lastch = ch
                 p = p+1
                 continue

             if ch in ")]}":
                 if stack:
                     del stack[-1]
                 lastch = ch
                 p = p+1
                 bracketing.append((p, len(stack)))
                 continue

             if ch == '"' or ch == "'":
                 # consume string
                 # Note that study1 did this with a Python loop, but
                 # we use a regexp here; the reason is speed in both
                 # cases; the string may be huge, but study1 pre-squashed
                 # strings to a couple of characters per line.  study1
                 # also needed to keep track of newlines, and we don't
                 # have to.
                 bracketing.append((p, len(stack)+1))
                 lastch = ch
                 p = _match_stringre(str, p, q).end()
                 bracketing.append((p, len(stack)))
                 continue

             if ch == '#':
                 # consume comment and trailing newline
                 bracketing.append((p, len(stack)+1))
                 p = str.find('\n', p, q) + 1
                 assert p > 0
                 bracketing.append((p, len(stack)))
                 continue

             assert ch == '\\'
             p = p+1     # beyond backslash
             assert p < q
             if str[p] != '\n':
                 # the program is invalid, but can't complain
                 lastch = ch + str[p]
             p = p+1     # beyond escaped char

         # end while p < q:

         self.lastch = lastch
         if stack:
             self.lastopenbracketpos = stack[-1]
         self.stmt_bracketing = tuple(bracketing)

     # Assuming continuation is C_BRACKET, return the number
     # of spaces the next line should be indented.

     def compute_bracket_indent(self):
         self._study2()
         assert self.continuation == C_BRACKET
         j = self.lastopenbracketpos
         str = self.str
         n = len(str)
         origi = i = str.rfind('\n', 0, j) + 1
         j = j+1     # one beyond open bracket
         # find first list item; set i to start of its line
         while j < n:
             m = _itemre(str, j)
             if m:
                 j = m.end() - 1     # index of first interesting char
                 extra = 0
                 break
             else:
                 # this line is junk; advance to next line
                 i = j = str.find('\n', j) + 1
         else:
             # nothing interesting follows the bracket;
             # reproduce the bracket line's indentation + a level
             j = i = origi
             while str[j] in " \t":
                 j = j+1
             extra = self.indentwidth
         return len(str[i:j].expandtabs(self.tabwidth)) + extra

     # Return number of physical lines in last stmt (whether or not
     # it's an interesting stmt!  this is intended to be called when
     # continuation is C_BACKSLASH).

     def get_num_lines_in_stmt(self):
         self._study1()
         goodlines = self.goodlines
         return goodlines[-1] - goodlines[-2]

     # Assuming continuation is C_BACKSLASH, return the number of spaces
     # the next line should be indented.  Also assuming the new line is
     # the first one following the initial line of the stmt.

     def compute_backslash_indent(self):
         self._study2()
         assert self.continuation == C_BACKSLASH
         str = self.str
         i = self.stmt_start
         while str[i] in " \t":
             i = i+1
         startpos = i

         # See whether the initial line starts an assignment stmt; i.e.,
         # look for an = operator
         endpos = str.find('\n', startpos) + 1
         found = level = 0
         while i < endpos:
             ch = str[i]
             if ch in "([{":
                 level = level + 1
                 i = i+1
             elif ch in ")]}":
                 if level:
                     level = level - 1
                 i = i+1
             elif ch == '"' or ch == "'":
                 i = _match_stringre(str, i, endpos).end()
             elif ch == '#':
                 break
             elif level == 0 and ch == '=' and \
                    (i == 0 or str[i-1] not in "=<>!") and \
                    str[i+1] != '=':
                 found = 1
                 break
             else:
                 i = i+1

         if found:
             # found a legit =, but it may be the last interesting
             # thing on the line
             i = i+1     # move beyond the =
             found = re.match(r"\s*\\", str[i:endpos]) is None

         if not found:
             # oh well ... settle for moving beyond the first chunk
             # of non-whitespace chars
             i = startpos
             while str[i] not in " \t\n":
                 i = i+1

         return len(str[self.stmt_start:i].expandtabs(\
                                      self.tabwidth)) + 1

     # Return the leading whitespace on the initial line of the last
     # interesting stmt.

     def get_base_indent_string(self):
         self._study2()
         i, n = self.stmt_start, self.stmt_end
         j = i
         str = self.str
         while j < n and str[j] in " \t":
             j = j + 1
         return str[i:j]

     # Did the last interesting stmt open a block?

     def is_block_opener(self):
         self._study2()
         return self.lastch == ':'

     # Did the last interesting stmt close a block?

     def is_block_closer(self):
         self._study2()
         return _closere(self.str, self.stmt_start) is not None

     # index of last open bracket ({[, or None if none
     lastopenbracketpos = None

     def get_last_open_bracket_pos(self):
         self._study2()
         return self.lastopenbracketpos

     # the structure of the bracketing of the last interesting statement,
     # in the format defined in _study2, or None if the text didn't contain
     # anything
     stmt_bracketing = None

     def get_last_stmt_bracketing(self):
         self._study2()
         return self.stmt_bracketing
	from collections import Mapping
	import re
	import sys

	# Reason last stmt is continued (or C_NONE if it's not).
	(C_NONE, C_BACKSLASH, C_STRING_FIRST_LINE,
	C_STRING_NEXT_LINES, C_BRACKET) = range(5)

	if 0: # for throwaway debugging output
	def dump(*stuff):
	sys.__stdout__.write(" ".join(map(str, stuff)) + "\n")

	# Find what looks like the start of a popular stmt.

	_synchre = re.compile(r"""
	^
	[ \t]*
	(?: while
	\| else
	\| def
	\| return
	\| assert
	\| break
	\| class
	\| continue
	\| elif
	\| try
	\| except
	\| raise
	\| import
	\| yield
	)
	\b
	""", re.VERBOSE \| re.MULTILINE).search

	# Match blank line or non-indenting comment line.

	_junkre = re.compile(r"""
	[ \t]*
	(?: \# \S .* )?
	\n
	""", re.VERBOSE).match

	# Match any flavor of string; the terminating quote is optional
	# so that we're robust in the face of incomplete program text.

	_match_stringre = re.compile(r"""
	\""" [^"\\]* (?:
	(?: \\. \| "(?!"") )
	[^"\\]*
	)*
	(?: \""" )?

	\| " [^"\\\n]* (?: \\. [^"\\\n]* )* "?

	\| ''' [^'\\]* (?:
	(?: \\. \| '(?!'') )
	[^'\\]*
	)*
	(?: ''' )?

	\| ' [^'\\\n]* (?: \\. [^'\\\n]* )* '?
	""", re.VERBOSE \| re.DOTALL).match

	# Match a line that starts with something interesting;
	# used to find the first item of a bracket structure.

	_itemre = re.compile(r"""
	[ \t]*
	[^\s#\\] # if we match, m.end()-1 is the interesting char
	""", re.VERBOSE).match

	# Match start of stmts that should be followed by a dedent.

	_closere = re.compile(r"""
	\s*
	(?: return
	\| break
	\| continue
	\| raise
	\| pass
	)
	\b
	""", re.VERBOSE).match

	# Chew up non-special chars as quickly as possible. If match is
	# successful, m.end() less 1 is the index of the last boring char
	# matched. If match is unsuccessful, the string starts with an
	# interesting char.

	_chew_ordinaryre = re.compile(r"""
	[^[\](){}#'"\\]+
	""", re.VERBOSE).match


	class StringTranslatePseudoMapping(Mapping):
	r"""Utility class to be used with str.translate()

	This Mapping class wraps a given dict. When a value for a key is
	requested via __getitem__() or get(), the key is looked up in the
	given dict. If found there, the value from the dict is returned.
	Otherwise, the default value given upon initialization is returned.

	This allows using str.translate() to make some replacements, and to
	replace all characters for which no replacement was specified with
	a given character instead of leaving them as-is.

	For example, to replace everything except whitespace with 'x':

	>>> whitespace_chars = ' \t\n\r'
	>>> preserve_dict = {ord(c): ord(c) for c in whitespace_chars}
	>>> mapping = StringTranslatePseudoMapping(preserve_dict, ord('x'))
	>>> text = "a + b\tc\nd"
	>>> text.translate(mapping)
	'x x x\tx\nx'
	"""
	def __init__(self, non_defaults, default_value):
	self._non_defaults = non_defaults
	self._default_value = default_value

	def _get(key, _get=non_defaults.get, _default=default_value):
	return _get(key, _default)
	self._get = _get

	def __getitem__(self, item):
	return self._get(item)

	def __len__(self):
	return len(self._non_defaults)

	def __iter__(self):
	return iter(self._non_defaults)

	def get(self, key, default=None):
	return self._get(key)


	class Parser:

	def __init__(self, indentwidth, tabwidth):
	self.indentwidth = indentwidth
	self.tabwidth = tabwidth

	def set_str(self, s):
	assert len(s) == 0 or s[-1] == '\n'
	self.str = s
	self.study_level = 0

	# Return index of a good place to begin parsing, as close to the
	# end of the string as possible. This will be the start of some
	# popular stmt like "if" or "def". Return None if none found:
	# the caller should pass more prior context then, if possible, or
	# if not (the entire program text up until the point of interest
	# has already been tried) pass 0 to set_lo.
	#
	# This will be reliable iff given a reliable is_char_in_string
	# function, meaning that when it says "no", it's absolutely
	# guaranteed that the char is not in a string.

	def find_good_parse_start(self, is_char_in_string=None,
	_synchre=_synchre):
	str, pos = self.str, None

	if not is_char_in_string:
	# no clue -- make the caller pass everything
	return None

	# Peek back from the end for a good place to start,
	# but don't try too often; pos will be left None, or
	# bumped to a legitimate synch point.
	limit = len(str)
	for tries in range(5):
	i = str.rfind(":\n", 0, limit)
	if i < 0:
	break
	i = str.rfind('\n', 0, i) + 1 # start of colon line
	m = _synchre(str, i, limit)
	if m and not is_char_in_string(m.start()):
	pos = m.start()
	break
	limit = i
	if pos is None:
	# Nothing looks like a block-opener, or stuff does
	# but is_char_in_string keeps returning true; most likely
	# we're in or near a giant string, the colorizer hasn't
	# caught up enough to be helpful, or there simply aren't
	# any interesting stmts. In any of these cases we're
	# going to have to parse the whole thing to be sure, so
	# give it one last try from the start, but stop wasting
	# time here regardless of the outcome.
	m = _synchre(str)
	if m and not is_char_in_string(m.start()):
	pos = m.start()
	return pos

	# Peeking back worked; look forward until _synchre no longer
	# matches.
	i = pos + 1
	while 1:
	m = _synchre(str, i)
	if m:
	s, i = m.span()
	if not is_char_in_string(s):
	pos = s
	else:
	break
	return pos

	# Throw away the start of the string. Intended to be called with
	# find_good_parse_start's result.

	def set_lo(self, lo):
	assert lo == 0 or self.str[lo-1] == '\n'
	if lo > 0:
	self.str = self.str[lo:]

	# Build a translation table to map uninteresting chars to 'x', open
	# brackets to '(', close brackets to ')' while preserving quotes,
	# backslashes, newlines and hashes. This is to be passed to
	# str.translate() in _study1().
	_tran = {}
	_tran.update((ord(c), ord('(')) for c in "({[")
	_tran.update((ord(c), ord(')')) for c in ")}]")
	_tran.update((ord(c), ord(c)) for c in "\"'\\\n#")
	_tran = StringTranslatePseudoMapping(_tran, default_value=ord('x'))

	# As quickly as humanly possible <wink>, find the line numbers (0-
	# based) of the non-continuation lines.
	# Creates self.{goodlines, continuation}.

	def _study1(self):
	if self.study_level >= 1:
	return
	self.study_level = 1

	# Map all uninteresting characters to "x", all open brackets
	# to "(", all close brackets to ")", then collapse runs of
	# uninteresting characters. This can cut the number of chars
	# by a factor of 10-40, and so greatly speed the following loop.
	str = self.str
	str = str.translate(self._tran)
	str = str.replace('xxxxxxxx', 'x')
	str = str.replace('xxxx', 'x')
	str = str.replace('xx', 'x')
	str = str.replace('xx', 'x')
	str = str.replace('\nx', '\n')
	# note that replacing x\n with \n would be incorrect, because
	# x may be preceded by a backslash

	# March over the squashed version of the program, accumulating
	# the line numbers of non-continued stmts, and determining
	# whether & why the last stmt is a continuation.
	continuation = C_NONE
	level = lno = 0 # level is nesting level; lno is line number
	self.goodlines = goodlines = [0]
	push_good = goodlines.append
	i, n = 0, len(str)
	while i < n:
	ch = str[i]
	i = i+1

	# cases are checked in decreasing order of frequency
	if ch == 'x':
	continue

	if ch == '\n':
	lno = lno + 1
	if level == 0:
	push_good(lno)
	# else we're in an unclosed bracket structure
	continue

	if ch == '(':
	level = level + 1
	continue

	if ch == ')':
	if level:
	level = level - 1
	# else the program is invalid, but we can't complain
	continue

	if ch == '"' or ch == "'":
	# consume the string
	quote = ch
	if str[i-1:i+2] == quote * 3:
	quote = quote * 3
	firstlno = lno
	w = len(quote) - 1
	i = i+w
	while i < n:
	ch = str[i]
	i = i+1

	if ch == 'x':
	continue

	if str[i-1:i+w] == quote:
	i = i+w
	break

	if ch == '\n':
	lno = lno + 1
	if w == 0:
	# unterminated single-quoted string
	if level == 0:
	push_good(lno)
	break
	continue

	if ch == '\\':
	assert i < n
	if str[i] == '\n':
	lno = lno + 1
	i = i+1
	continue

	# else comment char or paren inside string

	else:
	# didn't break out of the loop, so we're still
	# inside a string
	if (lno - 1) == firstlno:
	# before the previous \n in str, we were in the first
	# line of the string
	continuation = C_STRING_FIRST_LINE
	else:
	continuation = C_STRING_NEXT_LINES
	continue # with outer loop

	if ch == '#':
	# consume the comment
	i = str.find('\n', i)
	assert i >= 0
	continue

	assert ch == '\\'
	assert i < n
	if str[i] == '\n':
	lno = lno + 1
	if i+1 == n:
	continuation = C_BACKSLASH
	i = i+1

	# The last stmt may be continued for all 3 reasons.
	# String continuation takes precedence over bracket
	# continuation, which beats backslash continuation.
	if (continuation != C_STRING_FIRST_LINE
	and continuation != C_STRING_NEXT_LINES and level > 0):
	continuation = C_BRACKET
	self.continuation = continuation

	# Push the final line number as a sentinel value, regardless of
	# whether it's continued.
	assert (continuation == C_NONE) == (goodlines[-1] == lno)
	if goodlines[-1] != lno:
	push_good(lno)

	def get_continuation_type(self):
	self._study1()
	return self.continuation

	# study1 was sufficient to determine the continuation status,
	# but doing more requires looking at every character. study2
	# does this for the last interesting statement in the block.
	# Creates:
	# self.stmt_start, stmt_end
	# slice indices of last interesting stmt
	# self.stmt_bracketing
	# the bracketing structure of the last interesting stmt;
	# for example, for the statement "say(boo) or die", stmt_bracketing
	# will be [(0, 0), (3, 1), (8, 0)]. Strings and comments are
	# treated as brackets, for the matter.
	# self.lastch
	# last non-whitespace character before optional trailing
	# comment
	# self.lastopenbracketpos
	# if continuation is C_BRACKET, index of last open bracket

	def _study2(self):
	if self.study_level >= 2:
	return
	self._study1()
	self.study_level = 2

	# Set p and q to slice indices of last interesting stmt.
	str, goodlines = self.str, self.goodlines
	i = len(goodlines) - 1
	p = len(str) # index of newest line
	while i:
	assert p
	# p is the index of the stmt at line number goodlines[i].
	# Move p back to the stmt at line number goodlines[i-1].
	q = p
	for nothing in range(goodlines[i-1], goodlines[i]):
	# tricky: sets p to 0 if no preceding newline
	p = str.rfind('\n', 0, p-1) + 1
	# The stmt str[p:q] isn't a continuation, but may be blank
	# or a non-indenting comment line.
	if _junkre(str, p):
	i = i-1
	else:
	break
	if i == 0:
	# nothing but junk!
	assert p == 0
	q = p
	self.stmt_start, self.stmt_end = p, q

	# Analyze this stmt, to find the last open bracket (if any)
	# and last interesting character (if any).
	lastch = ""
	stack = [] # stack of open bracket indices
	push_stack = stack.append
	bracketing = [(p, 0)]
	while p < q:
	# suck up all except ()[]{}'"#\\
	m = _chew_ordinaryre(str, p, q)
	if m:
	# we skipped at least one boring char
	newp = m.end()
	# back up over totally boring whitespace
	i = newp - 1 # index of last boring char
	while i >= p and str[i] in " \t\n":
	i = i-1
	if i >= p:
	lastch = str[i]
	p = newp
	if p >= q:
	break

	ch = str[p]

	if ch in "([{":
	push_stack(p)
	bracketing.append((p, len(stack)))
	lastch = ch
	p = p+1
	continue

	if ch in ")]}":
	if stack:
	del stack[-1]
	lastch = ch
	p = p+1
	bracketing.append((p, len(stack)))
	continue

	if ch == '"' or ch == "'":
	# consume string
	# Note that study1 did this with a Python loop, but
	# we use a regexp here; the reason is speed in both
	# cases; the string may be huge, but study1 pre-squashed
	# strings to a couple of characters per line. study1
	# also needed to keep track of newlines, and we don't
	# have to.
	bracketing.append((p, len(stack)+1))
	lastch = ch
	p = _match_stringre(str, p, q).end()
	bracketing.append((p, len(stack)))
	continue

	if ch == '#':
	# consume comment and trailing newline
	bracketing.append((p, len(stack)+1))
	p = str.find('\n', p, q) + 1
	assert p > 0
	bracketing.append((p, len(stack)))
	continue

	assert ch == '\\'
	p = p+1 # beyond backslash
	assert p < q
	if str[p] != '\n':
	# the program is invalid, but can't complain
	lastch = ch + str[p]
	p = p+1 # beyond escaped char

	# end while p < q:

	self.lastch = lastch
	if stack:
	self.lastopenbracketpos = stack[-1]
	self.stmt_bracketing = tuple(bracketing)

	# Assuming continuation is C_BRACKET, return the number
	# of spaces the next line should be indented.

	def compute_bracket_indent(self):
	self._study2()
	assert self.continuation == C_BRACKET
	j = self.lastopenbracketpos
	str = self.str
	n = len(str)
	origi = i = str.rfind('\n', 0, j) + 1
	j = j+1 # one beyond open bracket
	# find first list item; set i to start of its line
	while j < n:
	m = _itemre(str, j)
	if m:
	j = m.end() - 1 # index of first interesting char
	extra = 0
	break
	else:
	# this line is junk; advance to next line
	i = j = str.find('\n', j) + 1
	else:
	# nothing interesting follows the bracket;
	# reproduce the bracket line's indentation + a level
	j = i = origi
	while str[j] in " \t":
	j = j+1
	extra = self.indentwidth
	return len(str[i:j].expandtabs(self.tabwidth)) + extra

	# Return number of physical lines in last stmt (whether or not
	# it's an interesting stmt! this is intended to be called when
	# continuation is C_BACKSLASH).

	def get_num_lines_in_stmt(self):
	self._study1()
	goodlines = self.goodlines
	return goodlines[-1] - goodlines[-2]

	# Assuming continuation is C_BACKSLASH, return the number of spaces
	# the next line should be indented. Also assuming the new line is
	# the first one following the initial line of the stmt.

	def compute_backslash_indent(self):
	self._study2()
	assert self.continuation == C_BACKSLASH
	str = self.str
	i = self.stmt_start
	while str[i] in " \t":
	i = i+1
	startpos = i

	# See whether the initial line starts an assignment stmt; i.e.,
	# look for an = operator
	endpos = str.find('\n', startpos) + 1
	found = level = 0
	while i < endpos:
	ch = str[i]
	if ch in "([{":
	level = level + 1
	i = i+1
	elif ch in ")]}":
	if level:
	level = level - 1
	i = i+1
	elif ch == '"' or ch == "'":
	i = _match_stringre(str, i, endpos).end()
	elif ch == '#':
	break
	elif level == 0 and ch == '=' and \
	(i == 0 or str[i-1] not in "=<>!") and \
	str[i+1] != '=':
	found = 1
	break
	else:
	i = i+1

	if found:
	# found a legit =, but it may be the last interesting
	# thing on the line
	i = i+1 # move beyond the =
	found = re.match(r"\s*\\", str[i:endpos]) is None

	if not found:
	# oh well ... settle for moving beyond the first chunk
	# of non-whitespace chars
	i = startpos
	while str[i] not in " \t\n":
	i = i+1

	return len(str[self.stmt_start:i].expandtabs(\
	self.tabwidth)) + 1

	# Return the leading whitespace on the initial line of the last
	# interesting stmt.

	def get_base_indent_string(self):
	self._study2()
	i, n = self.stmt_start, self.stmt_end
	j = i
	str = self.str
	while j < n and str[j] in " \t":
	j = j + 1
	return str[i:j]

	# Did the last interesting stmt open a block?

	def is_block_opener(self):
	self._study2()
	return self.lastch == ':'

	# Did the last interesting stmt close a block?

	def is_block_closer(self):
	self._study2()
	return _closere(self.str, self.stmt_start) is not None

	# index of last open bracket ({[, or None if none
	lastopenbracketpos = None

	def get_last_open_bracket_pos(self):
	self._study2()
	return self.lastopenbracketpos

	# the structure of the bracketing of the last interesting statement,
	# in the format defined in _study2, or None if the text didn't contain
	# anything
	stmt_bracketing = None

	def get_last_stmt_bracketing(self):
	self._study2()
	return self.stmt_bracketing