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Is there a way to create an NTFS junction point in Python? I know I can call the junction utility, but it would be better not to rely on external tools.

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5 Answers 5

up vote 3 down vote accepted

I answered this in a similar question, so I'll copy my answer to that below. Since writing that answer, I ended up writing a python-only (if you can call a module that uses ctypes python-only) module to creating, reading, and checking junctions which can be found in this folder. Hope that helps.

Also, unlike the answer that utilizes uses the CreateSymbolicLinkA API, the linked implementation should work on any Windows version that supports junctions. CreateSymbolicLinkA is only supported in Vista+.

Answer:

python ntfslink extension

Or if you want to use pywin32, you can use the previously stated method, and to read, use:

from win32file import *
from winioctlcon import FSCTL_GET_REPARSE_POINT

__all__ = ['islink', 'readlink']

# Win32file doesn't seem to have this attribute.
FILE_ATTRIBUTE_REPARSE_POINT = 1024
# To make things easier.
REPARSE_FOLDER = (FILE_ATTRIBUTE_DIRECTORY | FILE_ATTRIBUTE_REPARSE_POINT)

# For the parse_reparse_buffer function
SYMBOLIC_LINK = 'symbolic'
MOUNTPOINT = 'mountpoint'
GENERIC = 'generic'

def islink(fpath):
    """ Windows islink implementation. """
    if GetFileAttributes(fpath) & REPARSE_FOLDER:
        return True
    return False


def parse_reparse_buffer(original, reparse_type=SYMBOLIC_LINK):
    """ Implementing the below in Python:

    typedef struct _REPARSE_DATA_BUFFER {
        ULONG  ReparseTag;
        USHORT ReparseDataLength;
        USHORT Reserved;
        union {
            struct {
                USHORT SubstituteNameOffset;
                USHORT SubstituteNameLength;
                USHORT PrintNameOffset;
                USHORT PrintNameLength;
                ULONG Flags;
                WCHAR PathBuffer[1];
            } SymbolicLinkReparseBuffer;
            struct {
                USHORT SubstituteNameOffset;
                USHORT SubstituteNameLength;
                USHORT PrintNameOffset;
                USHORT PrintNameLength;
                WCHAR PathBuffer[1];
            } MountPointReparseBuffer;
            struct {
                UCHAR  DataBuffer[1];
            } GenericReparseBuffer;
        } DUMMYUNIONNAME;
    } REPARSE_DATA_BUFFER, *PREPARSE_DATA_BUFFER;

    """
    # Size of our data types
    SZULONG = 4 # sizeof(ULONG)
    SZUSHORT = 2 # sizeof(USHORT)

    # Our structure.
    # Probably a better way to iterate a dictionary in a particular order,
    # but I was in a hurry, unfortunately, so I used pkeys.
    buffer = {
        'tag' : SZULONG,
        'data_length' : SZUSHORT,
        'reserved' : SZUSHORT,
        SYMBOLIC_LINK : {
            'substitute_name_offset' : SZUSHORT,
            'substitute_name_length' : SZUSHORT,
            'print_name_offset' : SZUSHORT,
            'print_name_length' : SZUSHORT,
            'flags' : SZULONG,
            'buffer' : u'',
            'pkeys' : [
                'substitute_name_offset',
                'substitute_name_length',
                'print_name_offset',
                'print_name_length',
                'flags',
            ]
        },
        MOUNTPOINT : {
            'substitute_name_offset' : SZUSHORT,
            'substitute_name_length' : SZUSHORT,
            'print_name_offset' : SZUSHORT,
            'print_name_length' : SZUSHORT,
            'buffer' : u'',
            'pkeys' : [
                'substitute_name_offset',
                'substitute_name_length',
                'print_name_offset',
                'print_name_length',
            ]
        },
        GENERIC : {
            'pkeys' : [],
            'buffer': ''
        }
    }

    # Header stuff
    buffer['tag'] = original[:SZULONG]
    buffer['data_length'] = original[SZULONG:SZUSHORT]
    buffer['reserved'] = original[SZULONG+SZUSHORT:SZUSHORT]
    original = original[8:]

    # Parsing
    k = reparse_type
    for c in buffer[k]['pkeys']:
        if type(buffer[k][c]) == int:
            sz = buffer[k][c]
            bytes = original[:sz]
            buffer[k][c] = 0
            for b in bytes:
                n = ord(b)
                if n:
                    buffer[k][c] += n
            original = original[sz:]

    # Using the offset and length's grabbed, we'll set the buffer.
    buffer[k]['buffer'] = original
    return buffer

def readlink(fpath):
    """ Windows readlink implementation. """
    # This wouldn't return true if the file didn't exist, as far as I know.
    if not islink(fpath):
        return None

    # Open the file correctly depending on the string type.
    handle = CreateFileW(fpath, GENERIC_READ, 0, None, OPEN_EXISTING, FILE_FLAG_OPEN_REPARSE_POINT, 0) \
                if type(fpath) == unicode else \
            CreateFile(fpath, GENERIC_READ, 0, None, OPEN_EXISTING, FILE_FLAG_OPEN_REPARSE_POINT, 0)

    # MAXIMUM_REPARSE_DATA_BUFFER_SIZE = 16384 = (16*1024)
    buffer = DeviceIoControl(handle, FSCTL_GET_REPARSE_POINT, None, 16*1024)
    # Above will return an ugly string (byte array), so we'll need to parse it.

    # But first, we'll close the handle to our file so we're not locking it anymore.
    CloseHandle(handle)

    # Minimum possible length (assuming that the length of the target is bigger than 0)
    if len(buffer) < 9:
        return None
    # Parse and return our result.
    result = parse_reparse_buffer(buffer)
    offset = result[SYMBOLIC_LINK]['substitute_name_offset']
    ending = offset + result[SYMBOLIC_LINK]['substitute_name_length']
    rpath = result[SYMBOLIC_LINK]['buffer'][offset:ending].replace('\x00','')
    if len(rpath) > 4 and rpath[0:4] == '\\??\\':
        rpath = rpath[4:]
    return rpath

def realpath(fpath):
    from os import path
    while islink(fpath):
        rpath = readlink(fpath)
        if not path.isabs(rpath):
            rpath = path.abspath(path.join(path.dirname(fpath), rpath))
        fpath = rpath
    return fpath


def example():
    from os import system, unlink
    system('cmd.exe /c echo Hello World > test.txt')
    system('mklink test-link.txt test.txt')
    print 'IsLink: %s' % islink('test-link.txt')
    print 'ReadLink: %s' % readlink('test-link.txt')
    print 'RealPath: %s' % realpath('test-link.txt')
    unlink('test-link.txt')
    unlink('test.txt')

if __name__=='__main__':
    example()

Adjust the attributes in the CreateFile to your needs, but for a normal situation, it should work. Feel free to improve on it.

It should also work for folder junctions if you use MOUNTPOINT instead of SYMBOLIC_LINK.

You may way to check that

sys.getwindowsversion()[0] >= 6

if you put this into something you're releasing, since this form of symbolic link is only supported on Vista+.

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you can use python win32 API modules e.g.

import win32file

win32file.CreateSymbolicLink(srcDir, targetDir, 1)

see http://docs.activestate.com/activepython/2.5/pywin32/win32file__CreateSymbolicLink_meth.html for more details

if you do not want to rely on that too, you can always use ctypes and directly call CreateSymbolicLinl win32 API, which is anyway a simple call

here is example call using ctypes

import ctypes

kdll = ctypes.windll.LoadLibrary("kernel32.dll")

kdll.CreateSymbolicLinkA("d:\testdir", "d:\testdir_link", 1)

MSDN says Minimum supported client Windows Vista

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2  
I think junctions were from Win2K onwards but not officially (or well) supported by MS, given the scarcity of docs on how to do it. The new symbolic links look a lot better, especially since you can do them to files and (I think) they can now cross networks. –  paxdiablo Jul 17 '09 at 13:57
1  
yes junctions are subset of symbolic links –  Anurag Uniyal Jul 17 '09 at 15:05
4  
Junctions are not a subset of symbolic links. Junctions only apply to directories. This answer is incorrect and creates a symbolic link for files (which only works on Vista and above) rather than a junction for directories (which works on NTFS in Windows 2000) and above. Unfortunately, there's no real easy way of doing this in Python. –  Mike McQuaid Oct 25 '10 at 11:08
1  
Downvoted with reference to Mike McQuaid's comment. I was looking for junction points, i.e. hardlinks to directories. –  Kim Gräsman May 27 '11 at 11:58
    
@Mike McQuaid, according to MSDN CreateSymboliLink takes flag SYMBOLIC_LINK_FLAG_DIRECTORY, wouldn't that be like junction for directory ? –  Anurag Uniyal May 30 '11 at 0:16

You don't want to rely on external tools but you don't mind relying on the specific environment? I think you could safely assume that, if it's NTFS you're running on, the junction utility will probably be there.

But, if you mean you'd rather not call out to an external program, I've found the ctypes stuff to be invaluable. It allows you to call Windows DLLs directly from Python. And I'm pretty sure it's in the standard Python releases nowadays.

You'd just have to figure out which Windows DLL the CreateJunction() (or whatever Windows calls it) API call is in and set up the parameters and call. Best of luck with that, Microsoft don't seem to support it very well. You could disassemble the SysInternals junction program or linkd or one of the other tools to find out how they do it.

Me, I'm pretty lazy, I'd just call junction as an external process :-)

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ctypes is included in Python from 2.5 onwards. –  Torsten Marek Jul 17 '09 at 13:38
2  
The junction command doesn't exist on Vista and Win7. It's been replaced by mklink. –  Dustin Wyatt Sep 22 '09 at 16:19
    
It exists as a Sysinternals tool Junction. –  Nux Apr 13 '13 at 18:53

The answer you seek is already on StackOverflow in this question: In .NET, how do I Create a Junction in NTFS, as opposed to a Symlink?

Actually, the junction utility would be useful to identify the DLL since the .exe will have this information in it. Get something like Dependency Walker and use that to examine the .EXE's dependencies.

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I downloaded juntalis' python ntfslink extension and the module winioctl.py seems to contain a bug that caused some error about PrintNameOffset not found. I looked at the code and it seems that this is wrong:

class MountPointBuffer(Structure): fields = [

            # See SymbolicLinkBuffer.PathBuffer for our reasoning.
            ('PathBuffer', WCHAR * MAX_REPARSE_PATH_BUFFER)
    ]

By changing it to

    _fields_ = [
            ('SubstituteNameOffset', USHORT),
            ('SubstituteNameLength', USHORT),
            ('PrintNameOffset', USHORT),
            ('PrintNameLength', USHORT),
            ('PathBuffer', WCHAR * MAX_REPARSE_PATH_BUFFER)
    ]

I was able to get the code to work.

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