"""Analysis of text input into executable blocks. The main class in this module, :class:`InputSplitter`, is designed to break input from either interactive, line-by-line environments or block-based ones, into standalone blocks that can be executed by Python as 'single' statements (thus triggering sys.displayhook). A companion, :class:`IPythonInputSplitter`, provides the same functionality but with full support for the extended IPython syntax (magics, system calls, etc). For more details, see the class docstring below. Syntax Transformations ---------------------- One of the main jobs of the code in this file is to apply all syntax transformations that make up 'the IPython language', i.e. magics, shell escapes, etc. All transformations should be implemented as *fully stateless* entities, that simply take one line as their input and return a line. Internally for implementation purposes they may be a normal function or a callable object, but the only input they receive will be a single line and they should only return a line, without holding any data-dependent state between calls. As an example, the EscapedTransformer is a class so we can more clearly group together the functionality of dispatching to individual functions based on the starting escape character, but the only method for public use is its call method. ToDo ---- - Should we make push() actually raise an exception once push_accepts_more() returns False? - Naming cleanups. The tr_* names aren't the most elegant, though now they are at least just attributes of a class so not really very exposed. - Think about the best way to support dynamic things: automagic, autocall, macros, etc. - Think of a better heuristic for the application of the transforms in IPythonInputSplitter.push() than looking at the buffer ending in ':'. Idea: track indentation change events (indent, dedent, nothing) and apply them only if the indentation went up, but not otherwise. - Think of the cleanest way for supporting user-specified transformations (the user prefilters we had before). Authors ------- * Fernando Perez * Brian Granger """ #----------------------------------------------------------------------------- # Copyright (C) 2010 The IPython Development Team # # Distributed under the terms of the BSD License. The full license is in # the file COPYING, distributed as part of this software. #----------------------------------------------------------------------------- from __future__ import print_function #----------------------------------------------------------------------------- # Imports #----------------------------------------------------------------------------- # stdlib import codeop import re import sys # IPython modules from IPython.utils.text import make_quoted_expr #----------------------------------------------------------------------------- # Globals #----------------------------------------------------------------------------- # The escape sequences that define the syntax transformations IPython will # apply to user input. These can NOT be just changed here: many regular # expressions and other parts of the code may use their hardcoded values, and # for all intents and purposes they constitute the 'IPython syntax', so they # should be considered fixed. ESC_SHELL = '!' # Send line to underlying system shell ESC_SH_CAP = '!!' # Send line to system shell and capture output ESC_HELP = '?' # Find information about object ESC_HELP2 = '??' # Find extra-detailed information about object ESC_MAGIC = '%' # Call magic function ESC_QUOTE = ',' # Split args on whitespace, quote each as string and call ESC_QUOTE2 = ';' # Quote all args as a single string, call ESC_PAREN = '/' # Call first argument with rest of line as arguments #----------------------------------------------------------------------------- # Utilities #----------------------------------------------------------------------------- # FIXME: These are general-purpose utilities that later can be moved to the # general ward. Kept here for now because we're being very strict about test # coverage with this code, and this lets us ensure that we keep 100% coverage # while developing. # compiled regexps for autoindent management dedent_re = re.compile(r'^\s+raise|^\s+return|^\s+pass') ini_spaces_re = re.compile(r'^([ \t\r\f\v]+)') # regexp to match pure comment lines so we don't accidentally insert 'if 1:' # before pure comments comment_line_re = re.compile('^\s*\#') def num_ini_spaces(s): """Return the number of initial spaces in a string. Note that tabs are counted as a single space. For now, we do *not* support mixing of tabs and spaces in the user's input. Parameters ---------- s : string Returns ------- n : int """ ini_spaces = ini_spaces_re.match(s) if ini_spaces: return ini_spaces.end() else: return 0 def remove_comments(src): """Remove all comments from input source. Note: comments are NOT recognized inside of strings! Parameters ---------- src : string A single or multiline input string. Returns ------- String with all Python comments removed. """ return re.sub('#.*', '', src) def get_input_encoding(): """Return the default standard input encoding. If sys.stdin has no encoding, 'ascii' is returned.""" # There are strange environments for which sys.stdin.encoding is None. We # ensure that a valid encoding is returned. encoding = getattr(sys.stdin, 'encoding', None) if encoding is None: encoding = 'ascii' return encoding #----------------------------------------------------------------------------- # Classes and functions for normal Python syntax handling #----------------------------------------------------------------------------- # HACK! This implementation, written by Robert K a while ago using the # compiler module, is more robust than the other one below, but it expects its # input to be pure python (no ipython syntax). For now we're using it as a # second-pass splitter after the first pass transforms the input to pure # python. def split_blocks(python): """ Split multiple lines of code into discrete commands that can be executed singly. Parameters ---------- python : str Pure, exec'able Python code. Returns ------- commands : list of str Separate commands that can be exec'ed independently. """ import compiler # compiler.parse treats trailing spaces after a newline as a # SyntaxError. This is different than codeop.CommandCompiler, which # will compile the trailng spaces just fine. We simply strip any # trailing whitespace off. Passing a string with trailing whitespace # to exec will fail however. There seems to be some inconsistency in # how trailing whitespace is handled, but this seems to work. python_ori = python # save original in case we bail on error python = python.strip() # The compiler module does not like unicode. We need to convert # it encode it: if isinstance(python, unicode): # Use the utf-8-sig BOM so the compiler detects this a UTF-8 # encode string. python = '\xef\xbb\xbf' + python.encode('utf-8') # The compiler module will parse the code into an abstract syntax tree. # This has a bug with str("a\nb"), but not str("""a\nb""")!!! try: ast = compiler.parse(python) except: return [python_ori] # Uncomment to help debug the ast tree # for n in ast.node: # print n.lineno,'->',n # Each separate command is available by iterating over ast.node. The # lineno attribute is the line number (1-indexed) beginning the commands # suite. # lines ending with ";" yield a Discard Node that doesn't have a lineno # attribute. These nodes can and should be discarded. But there are # other situations that cause Discard nodes that shouldn't be discarded. # We might eventually discover other cases where lineno is None and have # to put in a more sophisticated test. linenos = [x.lineno-1 for x in ast.node if x.lineno is not None] # When we finally get the slices, we will need to slice all the way to # the end even though we don't have a line number for it. Fortunately, # None does the job nicely. linenos.append(None) # Same problem at the other end: sometimes the ast tree has its # first complete statement not starting on line 0. In this case # we might miss part of it. This fixes ticket 266993. Thanks Gael! linenos[0] = 0 lines = python.splitlines() # Create a list of atomic commands. cmds = [] for i, j in zip(linenos[:-1], linenos[1:]): cmd = lines[i:j] if cmd: cmds.append('\n'.join(cmd)+'\n') return cmds class InputSplitter(object): """An object that can split Python source input in executable blocks. This object is designed to be used in one of two basic modes: 1. By feeding it python source line-by-line, using :meth:`push`. In this mode, it will return on each push whether the currently pushed code could be executed already. In addition, it provides a method called :meth:`push_accepts_more` that can be used to query whether more input can be pushed into a single interactive block. 2. By calling :meth:`split_blocks` with a single, multiline Python string, that is then split into blocks each of which can be executed interactively as a single statement. This is a simple example of how an interactive terminal-based client can use this tool:: isp = InputSplitter() while isp.push_accepts_more(): indent = ' '*isp.indent_spaces prompt = '>>> ' + indent line = indent + raw_input(prompt) isp.push(line) print 'Input source was:\n', isp.source_reset(), """ # Number of spaces of indentation computed from input that has been pushed # so far. This is the attributes callers should query to get the current # indentation level, in order to provide auto-indent facilities. indent_spaces = 0 # String, indicating the default input encoding. It is computed by default # at initialization time via get_input_encoding(), but it can be reset by a # client with specific knowledge of the encoding. encoding = '' # String where the current full source input is stored, properly encoded. # Reading this attribute is the normal way of querying the currently pushed # source code, that has been properly encoded. source = '' # Code object corresponding to the current source. It is automatically # synced to the source, so it can be queried at any time to obtain the code # object; it will be None if the source doesn't compile to valid Python. code = None # Input mode input_mode = 'line' # Private attributes # List with lines of input accumulated so far _buffer = None # Command compiler _compile = None # Mark when input has changed indentation all the way back to flush-left _full_dedent = False # Boolean indicating whether the current block is complete _is_complete = None def __init__(self, input_mode=None): """Create a new InputSplitter instance. Parameters ---------- input_mode : str One of ['line', 'cell']; default is 'line'. The input_mode parameter controls how new inputs are used when fed via the :meth:`push` method: - 'line': meant for line-oriented clients, inputs are appended one at a time to the internal buffer and the whole buffer is compiled. - 'cell': meant for clients that can edit multi-line 'cells' of text at a time. A cell can contain one or more blocks that can be compile in 'single' mode by Python. In this mode, each new input new input completely replaces all prior inputs. Cell mode is thus equivalent to prepending a full reset() to every push() call. """ self._buffer = [] self._compile = codeop.CommandCompiler() self.encoding = get_input_encoding() self.input_mode = InputSplitter.input_mode if input_mode is None \ else input_mode def reset(self): """Reset the input buffer and associated state.""" self.indent_spaces = 0 self._buffer[:] = [] self.source = '' self.code = None self._is_complete = False self._full_dedent = False def source_reset(self): """Return the input source and perform a full reset. """ out = self.source self.reset() return out def push(self, lines): """Push one ore more lines of input. This stores the given lines and returns a status code indicating whether the code forms a complete Python block or not. Any exceptions generated in compilation are swallowed, but if an exception was produced, the method returns True. Parameters ---------- lines : string One or more lines of Python input. Returns ------- is_complete : boolean True if the current input source (the result of the current input plus prior inputs) forms a complete Python execution block. Note that this value is also stored as a private attribute (_is_complete), so it can be queried at any time. """ if self.input_mode == 'cell': self.reset() self._store(lines) source = self.source # Before calling _compile(), reset the code object to None so that if an # exception is raised in compilation, we don't mislead by having # inconsistent code/source attributes. self.code, self._is_complete = None, None # Honor termination lines properly if source.rstrip().endswith('\\'): return False self._update_indent(lines) try: self.code = self._compile(source) # Invalid syntax can produce any of a number of different errors from # inside the compiler, so we have to catch them all. Syntax errors # immediately produce a 'ready' block, so the invalid Python can be # sent to the kernel for evaluation with possible ipython # special-syntax conversion. except (SyntaxError, OverflowError, ValueError, TypeError, MemoryError): self._is_complete = True else: # Compilation didn't produce any exceptions (though it may not have # given a complete code object) self._is_complete = self.code is not None return self._is_complete def push_accepts_more(self): """Return whether a block of interactive input can accept more input. This method is meant to be used by line-oriented frontends, who need to guess whether a block is complete or not based solely on prior and current input lines. The InputSplitter considers it has a complete interactive block and will not accept more input only when either a SyntaxError is raised, or *all* of the following are true: 1. The input compiles to a complete statement. 2. The indentation level is flush-left (because if we are indented, like inside a function definition or for loop, we need to keep reading new input). 3. There is one extra line consisting only of whitespace. Because of condition #3, this method should be used only by *line-oriented* frontends, since it means that intermediate blank lines are not allowed in function definitions (or any other indented block). Block-oriented frontends that have a separate keyboard event to indicate execution should use the :meth:`split_blocks` method instead. If the current input produces a syntax error, this method immediately returns False but does *not* raise the syntax error exception, as typically clients will want to send invalid syntax to an execution backend which might convert the invalid syntax into valid Python via one of the dynamic IPython mechanisms. """ # With incomplete input, unconditionally accept more if not self._is_complete: return True # If we already have complete input and we're flush left, the answer # depends. In line mode, we're done. But in cell mode, we need to # check how many blocks the input so far compiles into, because if # there's already more than one full independent block of input, then # the client has entered full 'cell' mode and is feeding lines that # each is complete. In this case we should then keep accepting. # The Qt terminal-like console does precisely this, to provide the # convenience of terminal-like input of single expressions, but # allowing the user (with a separate keystroke) to switch to 'cell' # mode and type multiple expressions in one shot. if self.indent_spaces==0: if self.input_mode=='line': return False else: nblocks = len(split_blocks(''.join(self._buffer))) if nblocks==1: return False # When input is complete, then termination is marked by an extra blank # line at the end. last_line = self.source.splitlines()[-1] return bool(last_line and not last_line.isspace()) def split_blocks(self, lines): """Split a multiline string into multiple input blocks. Note: this method starts by performing a full reset(). Parameters ---------- lines : str A possibly multiline string. Returns ------- blocks : list A list of strings, each possibly multiline. Each string corresponds to a single block that can be compiled in 'single' mode (unless it has a syntax error).""" # This code is fairly delicate. If you make any changes here, make # absolutely sure that you do run the full test suite and ALL tests # pass. self.reset() blocks = [] # Reversed copy so we can use pop() efficiently and consume the input # as a stack lines = lines.splitlines()[::-1] # Outer loop over all input while lines: #print 'Current lines:', lines # dbg # Inner loop to build each block while True: # Safety exit from inner loop if not lines: break # Grab next line but don't push it yet next_line = lines.pop() # Blank/empty lines are pushed as-is if not next_line or next_line.isspace(): self.push(next_line) continue # Check indentation changes caused by the *next* line indent_spaces, _full_dedent = self._find_indent(next_line) # If the next line causes a dedent, it can be for two differnt # reasons: either an explicit de-dent by the user or a # return/raise/pass statement. These MUST be handled # separately: # # 1. the first case is only detected when the actual explicit # dedent happens, and that would be the *first* line of a *new* # block. Thus, we must put the line back into the input buffer # so that it starts a new block on the next pass. # # 2. the second case is detected in the line before the actual # dedent happens, so , we consume the line and we can break out # to start a new block. # Case 1, explicit dedent causes a break. # Note: check that we weren't on the very last line, else we'll # enter an infinite loop adding/removing the last line. if _full_dedent and lines and not next_line.startswith(' '): lines.append(next_line) break # Otherwise any line is pushed self.push(next_line) # Case 2, full dedent with full block ready: if _full_dedent or \ self.indent_spaces==0 and not self.push_accepts_more(): break # Form the new block with the current source input blocks.append(self.source_reset()) #return blocks # HACK!!! Now that our input is in blocks but guaranteed to be pure # python syntax, feed it back a second time through the AST-based # splitter, which is more accurate than ours. return split_blocks(''.join(blocks)) #------------------------------------------------------------------------ # Private interface #------------------------------------------------------------------------ def _find_indent(self, line): """Compute the new indentation level for a single line. Parameters ---------- line : str A single new line of non-whitespace, non-comment Python input. Returns ------- indent_spaces : int New value for the indent level (it may be equal to self.indent_spaces if indentation doesn't change. full_dedent : boolean Whether the new line causes a full flush-left dedent. """ indent_spaces = self.indent_spaces full_dedent = self._full_dedent inisp = num_ini_spaces(line) if inisp < indent_spaces: indent_spaces = inisp if indent_spaces <= 0: #print 'Full dedent in text',self.source # dbg full_dedent = True if line[-1] == ':': indent_spaces += 4 elif dedent_re.match(line): indent_spaces -= 4 if indent_spaces <= 0: full_dedent = True # Safety if indent_spaces < 0: indent_spaces = 0 #print 'safety' # dbg return indent_spaces, full_dedent def _update_indent(self, lines): for line in remove_comments(lines).splitlines(): if line and not line.isspace(): self.indent_spaces, self._full_dedent = self._find_indent(line) def _store(self, lines, buffer=None, store='source'): """Store one or more lines of input. If input lines are not newline-terminated, a newline is automatically appended.""" if buffer is None: buffer = self._buffer if lines.endswith('\n'): buffer.append(lines) else: buffer.append(lines+'\n') setattr(self, store, self._set_source(buffer)) def _set_source(self, buffer): return ''.join(buffer).encode(self.encoding) #----------------------------------------------------------------------------- # Functions and classes for IPython-specific syntactic support #----------------------------------------------------------------------------- # RegExp for splitting line contents into pre-char//first word-method//rest. # For clarity, each group in on one line. line_split = re.compile(""" ^(\s*) # any leading space ([,;/%]|!!?|\?\??) # escape character or characters \s*(%?[\w\.\*]*) # function/method, possibly with leading % # to correctly treat things like '?%magic' (\s+.*$|$) # rest of line """, re.VERBOSE) def split_user_input(line): """Split user input into early whitespace, esc-char, function part and rest. This is currently handles lines with '=' in them in a very inconsistent manner. Examples ======== >>> split_user_input('x=1') ('', '', 'x=1', '') >>> split_user_input('?') ('', '?', '', '') >>> split_user_input('??') ('', '??', '', '') >>> split_user_input(' ?') (' ', '?', '', '') >>> split_user_input(' ??') (' ', '??', '', '') >>> split_user_input('??x') ('', '??', 'x', '') >>> split_user_input('?x=1') ('', '', '?x=1', '') >>> split_user_input('!ls') ('', '!', 'ls', '') >>> split_user_input(' !ls') (' ', '!', 'ls', '') >>> split_user_input('!!ls') ('', '!!', 'ls', '') >>> split_user_input(' !!ls') (' ', '!!', 'ls', '') >>> split_user_input(',ls') ('', ',', 'ls', '') >>> split_user_input(';ls') ('', ';', 'ls', '') >>> split_user_input(' ;ls') (' ', ';', 'ls', '') >>> split_user_input('f.g(x)') ('', '', 'f.g(x)', '') >>> split_user_input('f.g (x)') ('', '', 'f.g', '(x)') >>> split_user_input('?%hist') ('', '?', '%hist', '') >>> split_user_input('?x*') ('', '?', 'x*', '') """ match = line_split.match(line) if match: lspace, esc, fpart, rest = match.groups() else: # print "match failed for line '%s'" % line try: fpart, rest = line.split(None, 1) except ValueError: # print "split failed for line '%s'" % line fpart, rest = line,'' lspace = re.match('^(\s*)(.*)', line).groups()[0] esc = '' # fpart has to be a valid python identifier, so it better be only pure # ascii, no unicode: try: fpart = fpart.encode('ascii') except UnicodeEncodeError: lspace = unicode(lspace) rest = fpart + u' ' + rest fpart = u'' #print 'line:<%s>' % line # dbg #print 'esc <%s> fpart <%s> rest <%s>' % (esc,fpart.strip(),rest) # dbg return lspace, esc, fpart.strip(), rest.lstrip() # The escaped translators ALL receive a line where their own escape has been # stripped. Only '?' is valid at the end of the line, all others can only be # placed at the start. class LineInfo(object): """A single line of input and associated info. This is a utility class that mostly wraps the output of :func:`split_user_input` into a convenient object to be passed around during input transformations. Includes the following as properties: line The original, raw line lspace Any early whitespace before actual text starts. esc The initial esc character (or characters, for double-char escapes like '??' or '!!'). fpart The 'function part', which is basically the maximal initial sequence of valid python identifiers and the '.' character. This is what is checked for alias and magic transformations, used for auto-calling, etc. rest Everything else on the line. """ def __init__(self, line): self.line = line self.lspace, self.esc, self.fpart, self.rest = \ split_user_input(line) def __str__(self): return "LineInfo [%s|%s|%s|%s]" % (self.lspace, self.esc, self.fpart, self.rest) # Transformations of the special syntaxes that don't rely on an explicit escape # character but instead on patterns on the input line # The core transformations are implemented as standalone functions that can be # tested and validated in isolation. Each of these uses a regexp, we # pre-compile these and keep them close to each function definition for clarity _assign_system_re = re.compile(r'(?P(\s*)([\w\.]+)((\s*,\s*[\w\.]+)*))' r'\s*=\s*!\s*(?P.*)') def transform_assign_system(line): """Handle the `files = !ls` syntax.""" m = _assign_system_re.match(line) if m is not None: cmd = m.group('cmd') lhs = m.group('lhs') expr = make_quoted_expr(cmd) new_line = '%s = get_ipython().getoutput(%s)' % (lhs, expr) return new_line return line _assign_magic_re = re.compile(r'(?P(\s*)([\w\.]+)((\s*,\s*[\w\.]+)*))' r'\s*=\s*%\s*(?P.*)') def transform_assign_magic(line): """Handle the `a = %who` syntax.""" m = _assign_magic_re.match(line) if m is not None: cmd = m.group('cmd') lhs = m.group('lhs') expr = make_quoted_expr(cmd) new_line = '%s = get_ipython().magic(%s)' % (lhs, expr) return new_line return line _classic_prompt_re = re.compile(r'^([ \t]*>>> |^[ \t]*\.\.\. )') def transform_classic_prompt(line): """Handle inputs that start with '>>> ' syntax.""" if not line or line.isspace(): return line m = _classic_prompt_re.match(line) if m: return line[len(m.group(0)):] else: return line _ipy_prompt_re = re.compile(r'^([ \t]*In \[\d+\]: |^[ \t]*\ \ \ \.\.\.+: )') def transform_ipy_prompt(line): """Handle inputs that start classic IPython prompt syntax.""" if not line or line.isspace(): return line #print 'LINE: %r' % line # dbg m = _ipy_prompt_re.match(line) if m: #print 'MATCH! %r -> %r' % (line, line[len(m.group(0)):]) # dbg return line[len(m.group(0)):] else: return line class EscapedTransformer(object): """Class to transform lines that are explicitly escaped out.""" def __init__(self): tr = { ESC_SHELL : self._tr_system, ESC_SH_CAP : self._tr_system2, ESC_HELP : self._tr_help, ESC_HELP2 : self._tr_help, ESC_MAGIC : self._tr_magic, ESC_QUOTE : self._tr_quote, ESC_QUOTE2 : self._tr_quote2, ESC_PAREN : self._tr_paren } self.tr = tr # Support for syntax transformations that use explicit escapes typed by the # user at the beginning of a line @staticmethod def _tr_system(line_info): "Translate lines escaped with: !" cmd = line_info.line.lstrip().lstrip(ESC_SHELL) return '%sget_ipython().system(%s)' % (line_info.lspace, make_quoted_expr(cmd)) @staticmethod def _tr_system2(line_info): "Translate lines escaped with: !!" cmd = line_info.line.lstrip()[2:] return '%sget_ipython().getoutput(%s)' % (line_info.lspace, make_quoted_expr(cmd)) @staticmethod def _tr_help(line_info): "Translate lines escaped with: ?/??" # A naked help line should just fire the intro help screen if not line_info.line[1:]: return 'get_ipython().show_usage()' # There may be one or two '?' at the end, move them to the front so that # the rest of the logic can assume escapes are at the start l_ori = line_info line = line_info.line if line.endswith('?'): line = line[-1] + line[:-1] if line.endswith('?'): line = line[-1] + line[:-1] line_info = LineInfo(line) # From here on, simply choose which level of detail to get, and # special-case the psearch syntax pinfo = 'pinfo' # default if '*' in line_info.line: pinfo = 'psearch' elif line_info.esc == '??': pinfo = 'pinfo2' tpl = '%sget_ipython().magic("%s %s")' return tpl % (line_info.lspace, pinfo, ' '.join([line_info.fpart, line_info.rest]).strip()) @staticmethod def _tr_magic(line_info): "Translate lines escaped with: %" tpl = '%sget_ipython().magic(%s)' cmd = make_quoted_expr(' '.join([line_info.fpart, line_info.rest]).strip()) return tpl % (line_info.lspace, cmd) @staticmethod def _tr_quote(line_info): "Translate lines escaped with: ," return '%s%s("%s")' % (line_info.lspace, line_info.fpart, '", "'.join(line_info.rest.split()) ) @staticmethod def _tr_quote2(line_info): "Translate lines escaped with: ;" return '%s%s("%s")' % (line_info.lspace, line_info.fpart, line_info.rest) @staticmethod def _tr_paren(line_info): "Translate lines escaped with: /" return '%s%s(%s)' % (line_info.lspace, line_info.fpart, ", ".join(line_info.rest.split())) def __call__(self, line): """Class to transform lines that are explicitly escaped out. This calls the above _tr_* static methods for the actual line translations.""" # Empty lines just get returned unmodified if not line or line.isspace(): return line # Get line endpoints, where the escapes can be line_info = LineInfo(line) # If the escape is not at the start, only '?' needs to be special-cased. # All other escapes are only valid at the start if not line_info.esc in self.tr: if line.endswith(ESC_HELP): return self._tr_help(line_info) else: # If we don't recognize the escape, don't modify the line return line return self.tr[line_info.esc](line_info) # A function-looking object to be used by the rest of the code. The purpose of # the class in this case is to organize related functionality, more than to # manage state. transform_escaped = EscapedTransformer() class IPythonInputSplitter(InputSplitter): """An input splitter that recognizes all of IPython's special syntax.""" # String with raw, untransformed input. source_raw = '' # Private attributes # List with lines of raw input accumulated so far. _buffer_raw = None def __init__(self, input_mode=None): InputSplitter.__init__(self, input_mode) self._buffer_raw = [] def reset(self): """Reset the input buffer and associated state.""" InputSplitter.reset(self) self._buffer_raw[:] = [] self.source_raw = '' def source_raw_reset(self): """Return input and raw source and perform a full reset. """ out = self.source out_r = self.source_raw self.reset() return out, out_r def push(self, lines): """Push one or more lines of IPython input. """ if not lines: return super(IPythonInputSplitter, self).push(lines) # We must ensure all input is pure unicode if type(lines)==str: lines = lines.decode(self.encoding) lines_list = lines.splitlines() transforms = [transform_escaped, transform_assign_system, transform_assign_magic, transform_ipy_prompt, transform_classic_prompt] # Transform logic # # We only apply the line transformers to the input if we have either no # input yet, or complete input, or if the last line of the buffer ends # with ':' (opening an indented block). This prevents the accidental # transformation of escapes inside multiline expressions like # triple-quoted strings or parenthesized expressions. # # The last heuristic, while ugly, ensures that the first line of an # indented block is correctly transformed. # # FIXME: try to find a cleaner approach for this last bit. # If we were in 'block' mode, since we're going to pump the parent # class by hand line by line, we need to temporarily switch out to # 'line' mode, do a single manual reset and then feed the lines one # by one. Note that this only matters if the input has more than one # line. changed_input_mode = False if self.input_mode == 'cell': self.reset() changed_input_mode = True saved_input_mode = 'cell' self.input_mode = 'line' # Store raw source before applying any transformations to it. Note # that this must be done *after* the reset() call that would otherwise # flush the buffer. self._store(lines, self._buffer_raw, 'source_raw') try: push = super(IPythonInputSplitter, self).push for line in lines_list: if self._is_complete or not self._buffer or \ (self._buffer and self._buffer[-1].rstrip().endswith(':')): for f in transforms: line = f(line) out = push(line) finally: if changed_input_mode: self.input_mode = saved_input_mode return out