# Licensed under the Apache License: http://www.apache.org/licenses/LICENSE-2.0 # For details: https://bitbucket.org/ned/coveragepy/src/default/NOTICE.txt """Better tokenizing for coverage.py.""" import codecs import keyword import re import sys import token import tokenize from coverage import env from coverage.backward import iternext from coverage.misc import contract def phys_tokens(toks): """Return all physical tokens, even line continuations. tokenize.generate_tokens() doesn't return a token for the backslash that continues lines. This wrapper provides those tokens so that we can re-create a faithful representation of the original source. Returns the same values as generate_tokens() """ last_line = None last_lineno = -1 last_ttype = None for ttype, ttext, (slineno, scol), (elineno, ecol), ltext in toks: if last_lineno != elineno: if last_line and last_line.endswith("\\\n"): # We are at the beginning of a new line, and the last line # ended with a backslash. We probably have to inject a # backslash token into the stream. Unfortunately, there's more # to figure out. This code:: # # usage = """\ # HEY THERE # """ # # triggers this condition, but the token text is:: # # '"""\\\nHEY THERE\n"""' # # so we need to figure out if the backslash is already in the # string token or not. inject_backslash = True if last_ttype == tokenize.COMMENT: # Comments like this \ # should never result in a new token. inject_backslash = False elif ttype == token.STRING: if "\n" in ttext and ttext.split('\n', 1)[0][-1] == '\\': # It's a multi-line string and the first line ends with # a backslash, so we don't need to inject another. inject_backslash = False if inject_backslash: # Figure out what column the backslash is in. ccol = len(last_line.split("\n")[-2]) - 1 # Yield the token, with a fake token type. yield ( 99999, "\\\n", (slineno, ccol), (slineno, ccol+2), last_line ) last_line = ltext last_ttype = ttype yield ttype, ttext, (slineno, scol), (elineno, ecol), ltext last_lineno = elineno @contract(source='unicode') def source_token_lines(source): """Generate a series of lines, one for each line in `source`. Each line is a list of pairs, each pair is a token:: [('key', 'def'), ('ws', ' '), ('nam', 'hello'), ('op', '('), ... ] Each pair has a token class, and the token text. If you concatenate all the token texts, and then join them with newlines, you should have your original `source` back, with two differences: trailing whitespace is not preserved, and a final line with no newline is indistinguishable from a final line with a newline. """ ws_tokens = set([token.INDENT, token.DEDENT, token.NEWLINE, tokenize.NL]) line = [] col = 0 # The \f is because of http://bugs.python.org/issue19035 source = source.expandtabs(8).replace('\r\n', '\n').replace('\f', ' ') tokgen = generate_tokens(source) for ttype, ttext, (_, scol), (_, ecol), _ in phys_tokens(tokgen): mark_start = True for part in re.split('(\n)', ttext): if part == '\n': yield line line = [] col = 0 mark_end = False elif part == '': mark_end = False elif ttype in ws_tokens: mark_end = False else: if mark_start and scol > col: line.append(("ws", u" " * (scol - col))) mark_start = False tok_class = tokenize.tok_name.get(ttype, 'xx').lower()[:3] if ttype == token.NAME and keyword.iskeyword(ttext): tok_class = "key" line.append((tok_class, part)) mark_end = True scol = 0 if mark_end: col = ecol if line: yield line class CachedTokenizer(object): """A one-element cache around tokenize.generate_tokens. When reporting, coverage.py tokenizes files twice, once to find the structure of the file, and once to syntax-color it. Tokenizing is expensive, and easily cached. This is a one-element cache so that our twice-in-a-row tokenizing doesn't actually tokenize twice. """ def __init__(self): self.last_text = None self.last_tokens = None @contract(text='unicode') def generate_tokens(self, text): """A stand-in for `tokenize.generate_tokens`.""" if text != self.last_text: self.last_text = text readline = iternext(text.splitlines(True)) self.last_tokens = list(tokenize.generate_tokens(readline)) return self.last_tokens # Create our generate_tokens cache as a callable replacement function. generate_tokens = CachedTokenizer().generate_tokens COOKIE_RE = re.compile(r"^[ \t]*#.*coding[:=][ \t]*([-\w.]+)", flags=re.MULTILINE) @contract(source='bytes') def _source_encoding_py2(source): """Determine the encoding for `source`, according to PEP 263. `source` is a byte string, the text of the program. Returns a string, the name of the encoding. """ assert isinstance(source, bytes) # Do this so the detect_encode code we copied will work. readline = iternext(source.splitlines(True)) # This is mostly code adapted from Py3.2's tokenize module. def _get_normal_name(orig_enc): """Imitates get_normal_name in tokenizer.c.""" # Only care about the first 12 characters. enc = orig_enc[:12].lower().replace("_", "-") if re.match(r"^utf-8($|-)", enc): return "utf-8" if re.match(r"^(latin-1|iso-8859-1|iso-latin-1)($|-)", enc): return "iso-8859-1" return orig_enc # From detect_encode(): # It detects the encoding from the presence of a UTF-8 BOM or an encoding # cookie as specified in PEP-0263. If both a BOM and a cookie are present, # but disagree, a SyntaxError will be raised. If the encoding cookie is an # invalid charset, raise a SyntaxError. Note that if a UTF-8 BOM is found, # 'utf-8-sig' is returned. # If no encoding is specified, then the default will be returned. default = 'ascii' bom_found = False encoding = None def read_or_stop(): """Get the next source line, or ''.""" try: return readline() except StopIteration: return '' def find_cookie(line): """Find an encoding cookie in `line`.""" try: line_string = line.decode('ascii') except UnicodeDecodeError: return None matches = COOKIE_RE.findall(line_string) if not matches: return None encoding = _get_normal_name(matches[0]) try: codec = codecs.lookup(encoding) except LookupError: # This behavior mimics the Python interpreter raise SyntaxError("unknown encoding: " + encoding) if bom_found: # codecs in 2.3 were raw tuples of functions, assume the best. codec_name = getattr(codec, 'name', encoding) if codec_name != 'utf-8': # This behavior mimics the Python interpreter raise SyntaxError('encoding problem: utf-8') encoding += '-sig' return encoding first = read_or_stop() if first.startswith(codecs.BOM_UTF8): bom_found = True first = first[3:] default = 'utf-8-sig' if not first: return default encoding = find_cookie(first) if encoding: return encoding second = read_or_stop() if not second: return default encoding = find_cookie(second) if encoding: return encoding return default @contract(source='bytes') def _source_encoding_py3(source): """Determine the encoding for `source`, according to PEP 263. `source` is a byte string: the text of the program. Returns a string, the name of the encoding. """ readline = iternext(source.splitlines(True)) return tokenize.detect_encoding(readline)[0] if env.PY3: source_encoding = _source_encoding_py3 else: source_encoding = _source_encoding_py2 @contract(source='unicode') def compile_unicode(source, filename, mode): """Just like the `compile` builtin, but works on any Unicode string. Python 2's compile() builtin has a stupid restriction: if the source string is Unicode, then it may not have a encoding declaration in it. Why not? Who knows! It also decodes to utf8, and then tries to interpret those utf8 bytes according to the encoding declaration. Why? Who knows! This function neuters the coding declaration, and compiles it. """ source = neuter_encoding_declaration(source) if env.PY2 and isinstance(filename, unicode): filename = filename.encode(sys.getfilesystemencoding(), "replace") code = compile(source, filename, mode) return code @contract(source='unicode', returns='unicode') def neuter_encoding_declaration(source): """Return `source`, with any encoding declaration neutered.""" source = COOKIE_RE.sub("# (deleted declaration)", source, count=1) return source