""" specialized local path implementation. This Path implementation offers some methods like chmod(), owner() and so on that may only make sense on unix. """ from __future__ import generators import sys, os, stat, re, atexit import py from py.__.path import common if sys.platform == 'win32': from py.__.path.local.win import WinMixin as PlatformMixin else: from py.__.path.local.posix import PosixMixin as PlatformMixin class LocalPath(common.FSPathBase, PlatformMixin): """ Local path implementation offering access/modification methods similar to os.path. """ _path_cache = {} sep = os.sep class Checkers(common.FSCheckers): def _stat(self): try: return self._statcache except AttributeError: try: self._statcache = self.path.stat() except py.error.ELOOP: self._statcache = self.path.lstat() return self._statcache def dir(self): return stat.S_ISDIR(self._stat().mode) def file(self): return stat.S_ISREG(self._stat().mode) def exists(self): return self._stat() def link(self): st = self.path.lstat() return stat.S_ISLNK(st.mode) def __new__(cls, path=None): """ Initialize and return a local Path instance. Path can be relative to the current directory. If it is None then the current working directory is taken. Note that Path instances always carry an absolute path. Note also that passing in a local path object will simply return the exact same path object. Use new() to get a new copy. """ if isinstance(path, common.FSPathBase): if path.__class__ == cls: return path path = path.strpath # initialize the path self = object.__new__(cls) if not path: self.strpath = os.getcwd() elif isinstance(path, str): self.strpath = os.path.abspath(os.path.normpath(str(path))) else: raise ValueError( "can only pass None, Path instances " "or non-empty strings to LocalPath") assert isinstance(self.strpath, str) return self def __hash__(self): return hash(self.strpath) def computehash(self, hashtype="md5", chunksize=524288): """ return hexdigest of hashvalue for this file. """ hash = self._gethashinstance(hashtype) f = self.open('rb') try: while 1: buf = f.read(chunksize) if not buf: return hash.hexdigest() hash.update(buf) finally: f.close() def new(self, **kw): """ create a modified version of this path. the following keyword arguments modify various path parts: a:/some/path/to/a/file.ext || drive |-------------| dirname |------| basename |--| purebasename |--| ext """ obj = object.__new__(self.__class__) drive, dirname, basename, purebasename,ext = self._getbyspec( "drive,dirname,basename,purebasename,ext") if 'basename' in kw: if 'purebasename' in kw or 'ext' in kw: raise ValueError("invalid specification %r" % kw) else: pb = kw.setdefault('purebasename', purebasename) try: ext = kw['ext'] except KeyError: pass else: if ext and not ext.startswith('.'): ext = '.' + ext kw['basename'] = pb + ext kw.setdefault('drive', drive) kw.setdefault('dirname', dirname) kw.setdefault('sep', self.sep) obj.strpath = os.path.normpath( "%(drive)s%(dirname)s%(sep)s%(basename)s" % kw) return obj def _getbyspec(self, spec): """ return a sequence of specified path parts. 'spec' is a comma separated string containing path part names. according to the following convention: a:/some/path/to/a/file.ext || drive |-------------| dirname |------| basename |--| purebasename |--| ext """ res = [] parts = self.strpath.split(self.sep) args = filter(None, spec.split(',') ) append = res.append for name in args: if name == 'drive': append(parts[0]) elif name == 'dirname': append(self.sep.join(['']+parts[1:-1])) else: basename = parts[-1] if name == 'basename': append(basename) else: i = basename.rfind('.') if i == -1: purebasename, ext = basename, '' else: purebasename, ext = basename[:i], basename[i:] if name == 'purebasename': append(purebasename) elif name == 'ext': append(ext) else: raise ValueError, "invalid part specification %r" % name return res def join(self, *args, **kwargs): """ return a new path by appending all 'args' as path components. if abs=1 is used restart from root if any of the args is an absolute path. """ if not args: return self strpath = self.strpath sep = self.sep strargs = [str(x) for x in args] if kwargs.get('abs', 0): for i in range(len(strargs)-1, -1, -1): if os.path.isabs(strargs[i]): strpath = strargs[i] strargs = strargs[i+1:] break for arg in strargs: arg = arg.strip(sep) if py.std.sys.platform == 'win32': # allow unix style paths even on windows. arg = arg.strip('/') arg = arg.replace('/', sep) if arg: if not strpath.endswith(sep): strpath += sep strpath += arg obj = self.new() obj.strpath = os.path.normpath(strpath) return obj def __eq__(self, other): return str(self) == str(other) def open(self, mode='r'): """ return an opened file with the given mode. """ return self._callex(open, self.strpath, mode) def listdir(self, fil=None, sort=None): """ list directory contents, possibly filter by the given fil func and possibly sorted. """ if isinstance(fil, str): fil = common.fnmatch(fil) res = [] for name in self._callex(os.listdir, self.strpath): childurl = self.join(name) if fil is None or fil(childurl): res.append(childurl) if callable(sort): res.sort(sort) elif sort: res.sort() return res def size(self): """ return size of the underlying file object """ return self.stat().size def mtime(self): """ return last modification time of the path. """ return self.stat().mtime def copy(self, target, archive=False): """ copy path to target.""" assert not archive, "XXX archive-mode not supported" if self.check(file=1): if target.check(dir=1): target = target.join(self.basename) assert self!=target copychunked(self, target) else: target.ensure(dir=1) def rec(p): return p.check(link=0) for x in self.visit(rec=rec): relpath = x.relto(self) newx = target.join(relpath) if x.check(link=1): newx.mksymlinkto(x.readlink()) elif x.check(file=1): copychunked(x, newx) elif x.check(dir=1): newx.ensure(dir=1) def rename(self, target): """ rename this path to target. """ return self._callex(os.rename, str(self), str(target)) def dump(self, obj, bin=1): """ pickle object into path location""" f = self.open('wb') try: self._callex(py.std.cPickle.dump, obj, f, bin) finally: f.close() def mkdir(self, *args): """ create & return the directory joined with args. """ p = self.join(*args) self._callex(os.mkdir, str(p)) return p def write(self, content, mode='wb'): """ write string content into path. """ s = str(content) f = self.open(mode) try: f.write(s) finally: f.close() def _ensuredirs(self): parent = self.dirpath() if parent == self: return self if parent.check(dir=0): parent._ensuredirs() if self.check(dir=0): try: self.mkdir() except py.error.EEXIST: # race condition: file/dir created by another thread/process. # complain if it is not a dir if self.check(dir=0): raise return self def ensure(self, *args, **kwargs): """ ensure that an args-joined path exists (by default as a file). if you specify a keyword argument 'dir=True' then the path is forced to be a directory path. """ p = self.join(*args) if kwargs.get('dir', 0): return p._ensuredirs() else: p.dirpath()._ensuredirs() if not p.check(file=1): p.write("") return p def stat(self): """ Return an os.stat() tuple. """ stat = self._callex(os.stat, self.strpath) return self._makestat(stat) def lstat(self): """ Return an os.lstat() tuple. """ return self._makestat(self._callex(os.lstat, self.strpath)) # xlocal implementation def setmtime(self, mtime=None): """ set modification time for the given path. if 'mtime' is None (the default) then the file's mtime is set to current time. Note that the resolution for 'mtime' is platform dependent. """ if mtime is None: return self._callex(os.utime, self.strpath, mtime) try: return self._callex(os.utime, self.strpath, (-1, mtime)) except py.error.EINVAL: return self._callex(os.utime, self.strpath, (self.atime(), mtime)) def chdir(self): """ change directory to self and return old current directory """ old = self.__class__() self._callex(os.chdir, self.strpath) return old def realpath(self): """ return a new path which contains no symbolic links.""" return self.__class__(os.path.realpath(self.strpath)) def atime(self): """ return last access time of the path. """ return self.stat().atime def __repr__(self): return 'local(%r)' % self.strpath def __str__(self): """ return string representation of the Path. """ return self.strpath def pypkgpath(self, pkgname=None): """ return the path's package path by looking for the given pkgname. If pkgname is None then look for the last directory upwards which still contains an __init__.py. Return None if a pkgpath can not be determined. """ pkgpath = None for parent in self.parts(reverse=True): if pkgname is None: if parent.check(file=1): continue if parent.join('__init__.py').check(): pkgpath = parent continue return pkgpath else: if parent.basename == pkgname: return parent return pkgpath def _prependsyspath(self, path): s = str(path) if s != sys.path[0]: #print "prepending to sys.path", s sys.path.insert(0, s) def pyimport(self, modname=None, ensuresyspath=True): """ return path as an imported python module. if modname is None, look for the containing package and construct an according module name. The module will be put/looked up in sys.modules. """ if not self.check(): raise py.error.ENOENT(self) #print "trying to import", self pkgpath = None if modname is None: #try: # return self._module #except AttributeError: # pass pkgpath = self.pypkgpath() if pkgpath is not None: if ensuresyspath: self._prependsyspath(pkgpath.dirpath()) pkg = __import__(pkgpath.basename, None, None, []) if hasattr(pkg, '__package__'): modname = pkg.__package__.getimportname(self) assert modname is not None, "package %s doesn't know %s" % ( pkg.__name__, self) else: names = self.new(ext='').relto(pkgpath.dirpath()) names = names.split(self.sep) modname = ".".join(names) else: # no package scope, still make it possible if ensuresyspath: self._prependsyspath(self.dirpath()) modname = self.purebasename mod = __import__(modname, None, None, ['__doc__']) #self._module = mod return mod else: try: return sys.modules[modname] except KeyError: # we have a custom modname, do a pseudo-import mod = py.std.new.module(modname) mod.__file__ = str(self) sys.modules[modname] = mod try: execfile(str(self), mod.__dict__) except: del sys.modules[modname] raise return mod def getpymodule(self): """resolve this path to a module python object. """ if self.ext != '.c': return super(LocalPath, self).getpymodule() from py.__.misc.buildcmodule import make_module_from_c mod = make_module_from_c(self) return mod def getpycodeobj(self): """ read the path and compile it to a code object. """ dotpy = self.check(ext='.py') if dotpy: my_magic = py.std.imp.get_magic() my_timestamp = int(self.mtime()) if __debug__: pycfile = self + 'c' else: pycfile = self + 'o' try: f = pycfile.open('rb') try: header = f.read(8) if len(header) == 8: magic, timestamp = py.std.struct.unpack('<4si', header) if magic == my_magic and timestamp == my_timestamp: co = py.std.marshal.load(f) path1 = co.co_filename path2 = str(self) if path1 == path2: return co try: if os.path.samefile(path1, path2): return co except (OSError, # probably path1 not found AttributeError): # samefile() not available pass finally: f.close() except py.error.Error: pass s = self.read(mode='rU') + '\n' codeobj = compile(s, str(self), 'exec', generators.compiler_flag) if dotpy: try: f = pycfile.open('wb') f.write(py.std.struct.pack('<4si', 'TEMP', -1)) # fixed below py.std.marshal.dump(codeobj, f) f.flush() f.seek(0) f.write(py.std.struct.pack('<4si', my_magic, my_timestamp)) f.close() except py.error.Error: pass return codeobj def sysexec(self, *argv): """ return stdout-put from executing a system child process, where the self path points to the binary (XXX or script) to be executed. Note that this process is directly invoked and not through a system shell. """ from py.compat.subprocess import Popen, PIPE argv = map(str, argv) proc = Popen([str(self)] + list(argv), stdout=PIPE, stderr=PIPE) stdout, stderr = proc.communicate() ret = proc.wait() if ret != 0: raise py.process.cmdexec.Error(ret, ret, str(self), stdout, stderr,) return stdout def sysfind(cls, name, checker=None): """ return a path object found by looking at the systems underlying PATH specification. If the checker is not None it will be invoked to filter matching paths. If a binary cannot be found, None is returned Note: This is probably not working on plain win32 systems but may work on cygwin. """ if os.path.isabs(name): p = py.path.local(name) if p.check(file=1): return p else: if py.std.sys.platform == 'win32': paths = py.std.os.environ['Path'].split(';') try: systemroot = os.environ['SYSTEMROOT'] except KeyError: pass else: paths = [re.sub('%SystemRoot%', systemroot, path) for path in paths] tryadd = '', '.exe', '.com', '.bat' # XXX add more? else: paths = py.std.os.environ['PATH'].split(':') tryadd = ('',) for x in paths: for addext in tryadd: p = py.path.local(x).join(name, abs=True) + addext try: if p.check(file=1): if checker: if not checker(p): continue return p except py.error.EACCES: pass return None sysfind = classmethod(sysfind) #""" #special class constructors for local filesystem paths #""" def get_temproot(cls): """ return the system's temporary directory (where tempfiles are usually created in) """ return py.path.local(py.std.tempfile.gettempdir()) get_temproot = classmethod(get_temproot) def mkdtemp(cls): """ return a Path object pointing to a fresh new temporary directory (which we created ourself). """ import tempfile tries = 10 for i in range(tries): dname = tempfile.mktemp() dpath = cls(tempfile.mktemp()) try: dpath.mkdir() except (py.error.EEXIST, py.error.EPERM, py.error.EACCES): continue return dpath raise py.error.ENOENT(dpath, "could not create tempdir, %d tries" % tries) mkdtemp = classmethod(mkdtemp) def make_numbered_dir(cls, prefix='session-', rootdir=None, keep=3, lock_timeout = 172800): # two days """ return unique directory with a number greater than the current maximum one. The number is assumed to start directly after prefix. if keep is true directories with a number less than (maxnum-keep) will be removed. """ if rootdir is None: rootdir = cls.get_temproot() def parse_num(path): """ parse the number out of a path (if it matches the prefix) """ bn = path.basename if bn.startswith(prefix): try: return int(bn[len(prefix):]) except ValueError: pass # compute the maximum number currently in use with the # prefix lastmax = None while True: maxnum = -1 for path in rootdir.listdir(): num = parse_num(path) if num is not None: maxnum = max(maxnum, num) # make the new directory try: udir = rootdir.mkdir(prefix + str(maxnum+1)) except py.error.EEXIST: # race condition: another thread/process created the dir # in the meantime. Try counting again if lastmax == maxnum: raise lastmax = maxnum continue break # put a .lock file in the new directory that will be removed at # process exit lockfile = udir.join('.lock') mypid = os.getpid() if hasattr(lockfile, 'mksymlinkto'): lockfile.mksymlinkto(str(mypid)) else: lockfile.write(str(mypid)) def try_remove_lockfile(): # in a fork() situation, only the last process should # remove the .lock, otherwise the other processes run the # risk of seeing their temporary dir disappear. For now # we remove the .lock in the parent only (i.e. we assume # that the children finish before the parent). if os.getpid() != mypid: return try: lockfile.remove() except py.error.Error: pass atexit.register(try_remove_lockfile) # prune old directories if keep: for path in rootdir.listdir(): num = parse_num(path) if num is not None and num <= (maxnum - keep): lf = path.join('.lock') try: t1 = lf.lstat().mtime t2 = lockfile.lstat().mtime if abs(t2-t1) < lock_timeout: continue # skip directories still locked except py.error.Error: pass # assume that it means that there is no 'lf' try: path.remove(rec=1) except py.error.Error: pass # make link... try: username = os.environ['USER'] #linux, et al except KeyError: try: username = os.environ['USERNAME'] #windows except KeyError: username = 'current' src = str(udir) dest = src[:src.rfind('-')] + '-' + username try: os.unlink(dest) except OSError: pass try: os.symlink(src, dest) except (OSError, AttributeError): # AttributeError on win32 pass return udir make_numbered_dir = classmethod(make_numbered_dir) def copychunked(src, dest): chunksize = 524288 # half a meg of bytes fsrc = src.open('rb') try: fdest = dest.open('wb') try: while 1: buf = fsrc.read(chunksize) if not buf: break fdest.write(buf) finally: fdest.close() finally: fsrc.close()