ancestor: use absolute_import
A few months ago, import-checker.py was taught to enforce a more
well-defined import style for files with absolute_import. However,
we stopped short of actually converting source files to use
absolute_import because of problems with certain files.
Investigation revealed the following problems with switching to
absolute_import universally:
1) import cycles result in import failure on Python 2.6
2) undetermined way to import C/pure modules
While these problems need to be solved, they can be put off.
This patch starts a series of converting files to absolute_import
that won't exhibit any of the aforementioned problems.
import ast
import os
import sys
# Import a minimal set of stdlib modules needed for list_stdlib_modules()
# to work when run from a virtualenv. The modules were chosen empirically
# so that the return value matches the return value without virtualenv.
import BaseHTTPServer
import zlib
# Whitelist of modules that symbols can be directly imported from.
allowsymbolimports = (
'__future__',
'mercurial.i18n',
'mercurial.node',
)
# Modules that must be aliased because they are commonly confused with
# common variables and can create aliasing and readability issues.
requirealias = {
'ui': 'uimod',
}
def usingabsolute(root):
"""Whether absolute imports are being used."""
if sys.version_info[0] >= 3:
return True
for node in ast.walk(root):
if isinstance(node, ast.ImportFrom):
if node.module == '__future__':
for n in node.names:
if n.name == 'absolute_import':
return True
return False
def dotted_name_of_path(path, trimpure=False):
"""Given a relative path to a source file, return its dotted module name.
>>> dotted_name_of_path('mercurial/error.py')
'mercurial.error'
>>> dotted_name_of_path('mercurial/pure/parsers.py', trimpure=True)
'mercurial.parsers'
>>> dotted_name_of_path('zlibmodule.so')
'zlib'
"""
parts = path.split('/')
parts[-1] = parts[-1].split('.', 1)[0] # remove .py and .so and .ARCH.so
if parts[-1].endswith('module'):
parts[-1] = parts[-1][:-6]
if trimpure:
return '.'.join(p for p in parts if p != 'pure')
return '.'.join(parts)
def fromlocalfunc(modulename, localmods):
"""Get a function to examine which locally defined module the
target source imports via a specified name.
`modulename` is an `dotted_name_of_path()`-ed source file path,
which may have `.__init__` at the end of it, of the target source.
`localmods` is a dict (or set), of which key is an absolute
`dotted_name_of_path()`-ed source file path of locally defined (=
Mercurial specific) modules.
This function assumes that module names not existing in
`localmods` are ones of Python standard libarary.
This function returns the function, which takes `name` argument,
and returns `(absname, dottedpath, hassubmod)` tuple if `name`
matches against locally defined module. Otherwise, it returns
False.
It is assumed that `name` doesn't have `.__init__`.
`absname` is an absolute module name of specified `name`
(e.g. "hgext.convert"). This can be used to compose prefix for sub
modules or so.
`dottedpath` is a `dotted_name_of_path()`-ed source file path
(e.g. "hgext.convert.__init__") of `name`. This is used to look
module up in `localmods` again.
`hassubmod` is whether it may have sub modules under it (for
convenient, even though this is also equivalent to "absname !=
dottednpath")
>>> localmods = {'foo.__init__': True, 'foo.foo1': True,
... 'foo.bar.__init__': True, 'foo.bar.bar1': True,
... 'baz.__init__': True, 'baz.baz1': True }
>>> fromlocal = fromlocalfunc('foo.xxx', localmods)
>>> # relative
>>> fromlocal('foo1')
('foo.foo1', 'foo.foo1', False)
>>> fromlocal('bar')
('foo.bar', 'foo.bar.__init__', True)
>>> fromlocal('bar.bar1')
('foo.bar.bar1', 'foo.bar.bar1', False)
>>> # absolute
>>> fromlocal('baz')
('baz', 'baz.__init__', True)
>>> fromlocal('baz.baz1')
('baz.baz1', 'baz.baz1', False)
>>> # unknown = maybe standard library
>>> fromlocal('os')
False
>>> fromlocal(None, 1)
('foo', 'foo.__init__', True)
>>> fromlocal2 = fromlocalfunc('foo.xxx.yyy', localmods)
>>> fromlocal2(None, 2)
('foo', 'foo.__init__', True)
"""
prefix = '.'.join(modulename.split('.')[:-1])
if prefix:
prefix += '.'
def fromlocal(name, level=0):
# name is None when relative imports are used.
if name is None:
# If relative imports are used, level must not be absolute.
assert level > 0
candidates = ['.'.join(modulename.split('.')[:-level])]
else:
# Check relative name first.
candidates = [prefix + name, name]
for n in candidates:
if n in localmods:
return (n, n, False)
dottedpath = n + '.__init__'
if dottedpath in localmods:
return (n, dottedpath, True)
return False
return fromlocal
def list_stdlib_modules():
"""List the modules present in the stdlib.
>>> mods = set(list_stdlib_modules())
>>> 'BaseHTTPServer' in mods
True
os.path isn't really a module, so it's missing:
>>> 'os.path' in mods
False
sys requires special treatment, because it's baked into the
interpreter, but it should still appear:
>>> 'sys' in mods
True
>>> 'collections' in mods
True
>>> 'cStringIO' in mods
True
"""
for m in sys.builtin_module_names:
yield m
# These modules only exist on windows, but we should always
# consider them stdlib.
for m in ['msvcrt', '_winreg']:
yield m
# These get missed too
for m in 'ctypes', 'email':
yield m
yield 'builtins' # python3 only
for m in 'fcntl', 'grp', 'pwd', 'termios': # Unix only
yield m
stdlib_prefixes = set([sys.prefix, sys.exec_prefix])
# We need to supplement the list of prefixes for the search to work
# when run from within a virtualenv.
for mod in (BaseHTTPServer, zlib):
try:
# Not all module objects have a __file__ attribute.
filename = mod.__file__
except AttributeError:
continue
dirname = os.path.dirname(filename)
for prefix in stdlib_prefixes:
if dirname.startswith(prefix):
# Then this directory is redundant.
break
else:
stdlib_prefixes.add(dirname)
for libpath in sys.path:
# We want to walk everything in sys.path that starts with
# something in stdlib_prefixes. check-code suppressed because
# the ast module used by this script implies the availability
# of any().
if not any(libpath.startswith(p) for p in stdlib_prefixes): # no-py24
continue
for top, dirs, files in os.walk(libpath):
for i, d in reversed(list(enumerate(dirs))):
if (not os.path.exists(os.path.join(top, d, '__init__.py'))
or top == libpath and d in ('hgext', 'mercurial')):
del dirs[i]
for name in files:
if name == '__init__.py':
continue
if not (name.endswith('.py') or name.endswith('.so')
or name.endswith('.pyd')):
continue
full_path = os.path.join(top, name)
rel_path = full_path[len(libpath) + 1:]
mod = dotted_name_of_path(rel_path)
yield mod
stdlib_modules = set(list_stdlib_modules())
def imported_modules(source, modulename, localmods, ignore_nested=False):
"""Given the source of a file as a string, yield the names
imported by that file.
Args:
source: The python source to examine as a string.
modulename: of specified python source (may have `__init__`)
localmods: dict of locally defined module names (may have `__init__`)
ignore_nested: If true, import statements that do not start in
column zero will be ignored.
Returns:
A list of absolute module names imported by the given source.
>>> modulename = 'foo.xxx'
>>> localmods = {'foo.__init__': True,
... 'foo.foo1': True, 'foo.foo2': True,
... 'foo.bar.__init__': True, 'foo.bar.bar1': True,
... 'baz.__init__': True, 'baz.baz1': True }
>>> # standard library (= not locally defined ones)
>>> sorted(imported_modules(
... 'from stdlib1 import foo, bar; import stdlib2',
... modulename, localmods))
[]
>>> # relative importing
>>> sorted(imported_modules(
... 'import foo1; from bar import bar1',
... modulename, localmods))
['foo.bar.__init__', 'foo.bar.bar1', 'foo.foo1']
>>> sorted(imported_modules(
... 'from bar.bar1 import name1, name2, name3',
... modulename, localmods))
['foo.bar.bar1']
>>> # absolute importing
>>> sorted(imported_modules(
... 'from baz import baz1, name1',
... modulename, localmods))
['baz.__init__', 'baz.baz1']
>>> # mixed importing, even though it shouldn't be recommended
>>> sorted(imported_modules(
... 'import stdlib, foo1, baz',
... modulename, localmods))
['baz.__init__', 'foo.foo1']
>>> # ignore_nested
>>> sorted(imported_modules(
... '''import foo
... def wat():
... import bar
... ''', modulename, localmods))
['foo.__init__', 'foo.bar.__init__']
>>> sorted(imported_modules(
... '''import foo
... def wat():
... import bar
... ''', modulename, localmods, ignore_nested=True))
['foo.__init__']
"""
fromlocal = fromlocalfunc(modulename, localmods)
for node in ast.walk(ast.parse(source)):
if ignore_nested and getattr(node, 'col_offset', 0) > 0:
continue
if isinstance(node, ast.Import):
for n in node.names:
found = fromlocal(n.name)
if not found:
# this should import standard library
continue
yield found[1]
elif isinstance(node, ast.ImportFrom):
found = fromlocal(node.module, node.level)
if not found:
# this should import standard library
continue
absname, dottedpath, hassubmod = found
yield dottedpath
if not hassubmod:
# examination of "node.names" should be redundant
# e.g.: from mercurial.node import nullid, nullrev
continue
prefix = absname + '.'
for n in node.names:
found = fromlocal(prefix + n.name)
if not found:
# this should be a function or a property of "node.module"
continue
yield found[1]
def verify_import_convention(module, source):
"""Verify imports match our established coding convention.
We have 2 conventions: legacy and modern. The modern convention is in
effect when using absolute imports.
The legacy convention only looks for mixed imports. The modern convention
is much more thorough.
"""
root = ast.parse(source)
absolute = usingabsolute(root)
if absolute:
return verify_modern_convention(module, root)
else:
return verify_stdlib_on_own_line(root)
def verify_modern_convention(module, root):
"""Verify a file conforms to the modern import convention rules.
The rules of the modern convention are:
* Ordering is stdlib followed by local imports. Each group is lexically
sorted.
* Importing multiple modules via "import X, Y" is not allowed: use
separate import statements.
* Importing multiple modules via "from X import ..." is allowed if using
parenthesis and one entry per line.
* Only 1 relative import statement per import level ("from .", "from ..")
is allowed.
* Relative imports from higher levels must occur before lower levels. e.g.
"from .." must be before "from .".
* Imports from peer packages should use relative import (e.g. do not
"import mercurial.foo" from a "mercurial.*" module).
* Symbols can only be imported from specific modules (see
`allowsymbolimports`). For other modules, first import the module then
assign the symbol to a module-level variable. In addition, these imports
must be performed before other relative imports. This rule only
applies to import statements outside of any blocks.
* Relative imports from the standard library are not allowed.
* Certain modules must be aliased to alternate names to avoid aliasing
and readability problems. See `requirealias`.
"""
topmodule = module.split('.')[0]
# Whether a local/non-stdlib import has been performed.
seenlocal = False
# Whether a relative, non-symbol import has been seen.
seennonsymbolrelative = False
# The last name to be imported (for sorting).
lastname = None
# Relative import levels encountered so far.
seenlevels = set()
for node in ast.walk(root):
if isinstance(node, ast.Import):
# Disallow "import foo, bar" and require separate imports
# for each module.
if len(node.names) > 1:
yield 'multiple imported names: %s' % ', '.join(
n.name for n in node.names)
name = node.names[0].name
asname = node.names[0].asname
# Ignore sorting rules on imports inside blocks.
if node.col_offset == 0:
if lastname and name < lastname:
yield 'imports not lexically sorted: %s < %s' % (
name, lastname)
lastname = name
# stdlib imports should be before local imports.
stdlib = name in stdlib_modules
if stdlib and seenlocal and node.col_offset == 0:
yield 'stdlib import follows local import: %s' % name
if not stdlib:
seenlocal = True
# Import of sibling modules should use relative imports.
topname = name.split('.')[0]
if topname == topmodule:
yield 'import should be relative: %s' % name
if name in requirealias and asname != requirealias[name]:
yield '%s module must be "as" aliased to %s' % (
name, requirealias[name])
elif isinstance(node, ast.ImportFrom):
# Resolve the full imported module name.
if node.level > 0:
fullname = '.'.join(module.split('.')[:-node.level])
if node.module:
fullname += '.%s' % node.module
else:
assert node.module
fullname = node.module
topname = fullname.split('.')[0]
if topname == topmodule:
yield 'import should be relative: %s' % fullname
# __future__ is special since it needs to come first and use
# symbol import.
if fullname != '__future__':
if not fullname or fullname in stdlib_modules:
yield 'relative import of stdlib module'
else:
seenlocal = True
# Direct symbol import is only allowed from certain modules and
# must occur before non-symbol imports.
if node.module and node.col_offset == 0:
if fullname not in allowsymbolimports:
yield 'direct symbol import from %s' % fullname
if seennonsymbolrelative:
yield ('symbol import follows non-symbol import: %s' %
fullname)
if not node.module:
assert node.level
seennonsymbolrelative = True
# Only allow 1 group per level.
if node.level in seenlevels and node.col_offset == 0:
yield 'multiple "from %s import" statements' % (
'.' * node.level)
# Higher-level groups come before lower-level groups.
if any(node.level > l for l in seenlevels):
yield 'higher-level import should come first: %s' % (
fullname)
seenlevels.add(node.level)
# Entries in "from .X import ( ... )" lists must be lexically
# sorted.
lastentryname = None
for n in node.names:
if lastentryname and n.name < lastentryname:
yield 'imports from %s not lexically sorted: %s < %s' % (
fullname, n.name, lastentryname)
lastentryname = n.name
if n.name in requirealias and n.asname != requirealias[n.name]:
yield '%s from %s must be "as" aliased to %s' % (
n.name, fullname, requirealias[n.name])
def verify_stdlib_on_own_line(root):
"""Given some python source, verify that stdlib imports are done
in separate statements from relative local module imports.
Observing this limitation is important as it works around an
annoying lib2to3 bug in relative import rewrites:
http://bugs.python.org/issue19510.
>>> list(verify_stdlib_on_own_line(ast.parse('import sys, foo')))
['mixed imports\\n stdlib: sys\\n relative: foo']
>>> list(verify_stdlib_on_own_line(ast.parse('import sys, os')))
[]
>>> list(verify_stdlib_on_own_line(ast.parse('import foo, bar')))
[]
"""
for node in ast.walk(root):
if isinstance(node, ast.Import):
from_stdlib = {False: [], True: []}
for n in node.names:
from_stdlib[n.name in stdlib_modules].append(n.name)
if from_stdlib[True] and from_stdlib[False]:
yield ('mixed imports\n stdlib: %s\n relative: %s' %
(', '.join(sorted(from_stdlib[True])),
', '.join(sorted(from_stdlib[False]))))
class CircularImport(Exception):
pass
def checkmod(mod, imports):
shortest = {}
visit = [[mod]]
while visit:
path = visit.pop(0)
for i in sorted(imports.get(path[-1], [])):
if len(path) < shortest.get(i, 1000):
shortest[i] = len(path)
if i in path:
if i == path[0]:
raise CircularImport(path)
continue
visit.append(path + [i])
def rotatecycle(cycle):
"""arrange a cycle so that the lexicographically first module listed first
>>> rotatecycle(['foo', 'bar'])
['bar', 'foo', 'bar']
"""
lowest = min(cycle)
idx = cycle.index(lowest)
return cycle[idx:] + cycle[:idx] + [lowest]
def find_cycles(imports):
"""Find cycles in an already-loaded import graph.
All module names recorded in `imports` should be absolute one.
>>> imports = {'top.foo': ['top.bar', 'os.path', 'top.qux'],
... 'top.bar': ['top.baz', 'sys'],
... 'top.baz': ['top.foo'],
... 'top.qux': ['top.foo']}
>>> print '\\n'.join(sorted(find_cycles(imports)))
top.bar -> top.baz -> top.foo -> top.bar
top.foo -> top.qux -> top.foo
"""
cycles = set()
for mod in sorted(imports.iterkeys()):
try:
checkmod(mod, imports)
except CircularImport as e:
cycle = e.args[0]
cycles.add(" -> ".join(rotatecycle(cycle)))
return cycles
def _cycle_sortkey(c):
return len(c), c
def main(argv):
if len(argv) < 2 or (argv[1] == '-' and len(argv) > 2):
print 'Usage: %s {-|file [file] [file] ...}'
return 1
if argv[1] == '-':
argv = argv[:1]
argv.extend(l.rstrip() for l in sys.stdin.readlines())
localmods = {}
used_imports = {}
any_errors = False
for source_path in argv[1:]:
modname = dotted_name_of_path(source_path, trimpure=True)
localmods[modname] = source_path
for modname, source_path in sorted(localmods.iteritems()):
f = open(source_path)
src = f.read()
used_imports[modname] = sorted(
imported_modules(src, modname, localmods, ignore_nested=True))
for error in verify_import_convention(modname, src):
any_errors = True
print source_path, error
f.close()
cycles = find_cycles(used_imports)
if cycles:
firstmods = set()
for c in sorted(cycles, key=_cycle_sortkey):
first = c.split()[0]
# As a rough cut, ignore any cycle that starts with the
# same module as some other cycle. Otherwise we see lots
# of cycles that are effectively duplicates.
if first in firstmods:
continue
print 'Import cycle:', c
firstmods.add(first)
any_errors = True
return any_errors != 0
if __name__ == '__main__':
sys.exit(int(main(sys.argv)))