*if_pyth.txt* For Vim version 9.1. Last change: 2024 Nov 09 VIM REFERENCE MANUAL by Paul Moore The Python Interface to Vim *python* *Python* 1. Commands |python-commands| 2. The vim module |python-vim| 3. Buffer objects |python-buffer| 4. Range objects |python-range| 5. Window objects |python-window| 6. Tab page objects |python-tabpage| 7. vim.bindeval objects |python-bindeval-objects| 8. pyeval(), py3eval() Vim functions |python-pyeval| 9. Dynamic loading |python-dynamic| 10. Python 3 |python3| 11. Python X |python_x| 12. Building with Python support |python-building| The Python 2.x interface is available only when Vim was compiled with the |+python| feature. The Python 3 interface is available only when Vim was compiled with the |+python3| feature. Both can be available at the same time, but read |python-2-and-3|. NOTE: Python 2 is old and no longer being developed. Using Python 3 is highly recommended. Python 2 support will be dropped when it does not work properly anymore. ============================================================================== 1. Commands *python-commands* *:python* *:py* *E263* *E264* *E887* :[range]py[thon] {stmt} Execute Python statement {stmt}. A simple check if the `:python` command is working: > :python print "Hello" :[range]py[thon] << [trim] [{endmarker}] {script} {endmarker} Execute Python script {script}. Note: This command doesn't work when the Python feature wasn't compiled in. To avoid errors, see |script-here|. If [endmarker] is omitted from after the "<<", a dot '.' must be used after {script}, like for the |:append| and |:insert| commands. Refer to |:let-heredoc| for more information. This form of the |:python| command is mainly useful for including python code in Vim scripts. Example: > function! IcecreamInitialize() python << EOF class StrawberryIcecream: def __call__(self): print 'EAT ME' EOF endfunction To see what version of Python you have: > :python print(sys.version) There is no need to import sys, it's done by default. *python-environment* Environment variables set in Vim are not always available in Python. This depends on how Vim and Python were built. Also see https://docs.python.org/3/library/os.html#os.environ Note: Python is very sensitive to the indenting. Make sure the "class" line and "EOF" do not have any indent. *:pydo* :[range]pydo {body} Execute Python function "def _vim_pydo(line, linenr): {body}" for each line in the [range], with the function arguments being set to the text of each line in turn, without a trailing , and the current line number. The function should return a string or None. If a string is returned, it becomes the text of the line in the current turn. The default for [range] is the whole file: "1,$". Examples: > :pydo return "%s\t%d" % (line[::-1], len(line)) :pydo if line: return "%4d: %s" % (linenr, line) < One can use `:pydo` in possible conjunction with `:py` to filter a range using python. For example: > :py3 << EOF needle = vim.eval('@a') replacement = vim.eval('@b') def py_vim_string_replace(str): return str.replace(needle, replacement) EOF :'<,'>py3do return py_vim_string_replace(line) < *:pyfile* *:pyf* :[range]pyf[ile] {file} Execute the Python script in {file}. The whole argument is used as a single file name. Both of these commands do essentially the same thing - they execute a piece of Python code, with the "current range" |python-range| set to the given line range. In the case of :python, the code to execute is in the command-line. In the case of :pyfile, the code to execute is the contents of the given file. Python commands cannot be used in the |sandbox|. To pass arguments you need to set sys.argv[] explicitly. Example: > :python sys.argv = ["foo", "bar"] :pyfile myscript.py Here are some examples *python-examples* > :python from vim import * :python from string import upper :python current.line = upper(current.line) :python print "Hello" :python str = current.buffer[42] (Note that changes - like the imports - persist from one command to the next, just like in the Python interpreter.) ============================================================================== 2. The vim module *python-vim* Python code gets all of its access to vim (with one exception - see |python-output| below) via the "vim" module. The vim module implements two methods, three constants, and one error object. You need to import the vim module before using it: > :python import vim Overview > :py print "Hello" # displays a message :py vim.command(cmd) # execute an Ex command :py w = vim.windows[n] # gets window "n" :py cw = vim.current.window # gets the current window :py b = vim.buffers[n] # gets buffer "n" :py cb = vim.current.buffer # gets the current buffer :py w.height = lines # sets the window height :py w.cursor = (row, col) # sets the window cursor position :py pos = w.cursor # gets a tuple (row, col) :py name = b.name # gets the buffer file name :py line = b[n] # gets a line from the buffer :py lines = b[n:m] # gets a list of lines :py num = len(b) # gets the number of lines :py b[n] = str # sets a line in the buffer :py b[n:m] = [str1, str2, str3] # sets a number of lines at once :py del b[n] # deletes a line :py del b[n:m] # deletes a number of lines Methods of the "vim" module vim.command(str) *python-command* Executes the vim (ex-mode) command str. Returns None. Examples: > :py vim.command("set tw=72") :py vim.command("%s/aaa/bbb/g") < The following definition executes Normal mode commands: > def normal(str): vim.command("normal "+str) # Note the use of single quotes to delimit a string containing # double quotes normal('"a2dd"aP') < *E659* The ":python" command cannot be used recursively with Python 2.2 and older. This only works with Python 2.3 and later: > :py vim.command("python print 'Hello again Python'") vim.eval(str) *python-eval* Evaluates the expression str using the vim internal expression evaluator (see |expression|). Returns the expression result as: - a string if the Vim expression evaluates to a string or number - a list if the Vim expression evaluates to a Vim list - a dictionary if the Vim expression evaluates to a Vim dictionary Dictionaries and lists are recursively expanded. Examples: > :" value of the 'textwidth' option :py text_width = vim.eval("&tw") : :" contents of the 'a' register :py a_reg = vim.eval("@a") : :" Result is a string! Use string.atoi() to convert to a number. :py str = vim.eval("12+12") : :py tagList = vim.eval('taglist("eval_expr")') < The latter will return a python list of python dicts, for instance: [{'cmd': '/^eval_expr(arg, nextcmd)$/', 'static': 0, 'name': ~ 'eval_expr', 'kind': 'f', 'filename': './src/eval.c'}] ~ NOTE: In Vim9 script, local variables in def functions are not visible to python evaluations. To pass local variables to python evaluations, use the {locals} dict when calling |py3eval()| and friends. vim.bindeval(str) *python-bindeval* Like |python-eval|, but returns special objects described in |python-bindeval-objects|. These python objects let you modify (|List| or |Dictionary|) or call (|Funcref|) vim objects. vim.strwidth(str) *python-strwidth* Like |strwidth()|: returns number of display cells str occupies, tab is counted as one cell. vim.foreach_rtp(callable) *python-foreach_rtp* Call the given callable for each path in 'runtimepath' until either callable returns something but None, the exception is raised or there are no longer paths. If stopped in case callable returned non-None, vim.foreach_rtp function returns the value returned by callable. vim.chdir(*args, **kwargs) *python-chdir* vim.fchdir(*args, **kwargs) *python-fchdir* Run os.chdir or os.fchdir, then all appropriate vim stuff. Note: you should not use these functions directly, use os.chdir and os.fchdir instead. Behavior of vim.fchdir is undefined in case os.fchdir does not exist. Error object of the "vim" module vim.error *python-error* Upon encountering a Vim error, Python raises an exception of type vim.error. Example: > try: vim.command("put a") except vim.error: # nothing in register a Constants of the "vim" module Note that these are not actually constants - you could reassign them. But this is silly, as you would then lose access to the vim objects to which the variables referred. vim.buffers *python-buffers* A mapping object providing access to the list of vim buffers. The object supports the following operations: > :py b = vim.buffers[i] # Indexing (read-only) :py b in vim.buffers # Membership test :py n = len(vim.buffers) # Number of elements :py for b in vim.buffers: # Iterating over buffer list < vim.windows *python-windows* A sequence object providing access to the list of vim windows. The object supports the following operations: > :py w = vim.windows[i] # Indexing (read-only) :py w in vim.windows # Membership test :py n = len(vim.windows) # Number of elements :py for w in vim.windows: # Sequential access < Note: vim.windows object always accesses current tab page. |python-tabpage|.windows objects are bound to parent |python-tabpage| object and always use windows from that tab page (or throw vim.error in case tab page was deleted). You can keep a reference to both without keeping a reference to vim module object or |python-tabpage|, they will not lose their properties in this case. vim.tabpages *python-tabpages* A sequence object providing access to the list of vim tab pages. The object supports the following operations: > :py t = vim.tabpages[i] # Indexing (read-only) :py t in vim.tabpages # Membership test :py n = len(vim.tabpages) # Number of elements :py for t in vim.tabpages: # Sequential access < vim.current *python-current* An object providing access (via specific attributes) to various "current" objects available in vim: vim.current.line The current line (RW) String vim.current.buffer The current buffer (RW) Buffer vim.current.window The current window (RW) Window vim.current.tabpage The current tab page (RW) TabPage vim.current.range The current line range (RO) Range The last case deserves a little explanation. When the :python or :pyfile command specifies a range, this range of lines becomes the "current range". A range is a bit like a buffer, but with all access restricted to a subset of lines. See |python-range| for more details. Note: When assigning to vim.current.{buffer,window,tabpage} it expects valid |python-buffer|, |python-window| or |python-tabpage| objects respectively. Assigning triggers normal (with |autocommand|s) switching to given buffer, window or tab page. It is the only way to switch UI objects in python: you can't assign to |python-tabpage|.window attribute. To switch without triggering autocommands use > py << EOF saved_eventignore = vim.options['eventignore'] vim.options['eventignore'] = 'all' try: vim.current.buffer = vim.buffers[2] # Switch to buffer 2 finally: vim.options['eventignore'] = saved_eventignore EOF < vim.vars *python-vars* vim.vvars *python-vvars* Dictionary-like objects holding dictionaries with global (|g:|) and vim (|v:|) variables respectively. Identical to `vim.bindeval("g:")`, but faster. vim.options *python-options* Object partly supporting mapping protocol (supports setting and getting items) providing a read-write access to global options. Note: unlike |:set| this provides access only to global options. You cannot use this object to obtain or set local options' values or access local-only options in any fashion. Raises KeyError if no global option with such name exists (i.e. does not raise KeyError for |global-local| options and global only options, but does for window- and buffer-local ones). Use |python-buffer| objects to access to buffer-local options and |python-window| objects to access to window-local options. Type of this object is available via "Options" attribute of vim module. Output from Python *python-output* Vim displays all Python code output in the Vim message area. Normal output appears as information messages, and error output appears as error messages. In implementation terms, this means that all output to sys.stdout (including the output from print statements) appears as information messages, and all output to sys.stderr (including error tracebacks) appears as error messages. *python-input* Input (via sys.stdin, including input() and raw_input()) is not supported, and may cause the program to crash. This should probably be fixed. *python2-directory* *python3-directory* *pythonx-directory* Python 'runtimepath' handling *python-special-path* In python vim.VIM_SPECIAL_PATH special directory is used as a replacement for the list of paths found in 'runtimepath': with this directory in sys.path and vim.path_hooks in sys.path_hooks python will try to load module from {rtp}/python2 (or python3) and {rtp}/pythonx (for both python versions) for each {rtp} found in 'runtimepath' (Note: find_module() has been removed from imp module around Python 3.12.0a7). Implementation is similar to the following, but written in C: > from imp import find_module, load_module import vim import sys class VimModuleLoader(object): def __init__(self, module): self.module = module def load_module(self, fullname, path=None): return self.module def _find_module(fullname, oldtail, path): idx = oldtail.find('.') if idx > 0: name = oldtail[:idx] tail = oldtail[idx+1:] fmr = find_module(name, path) module = load_module(fullname[:-len(oldtail)] + name, *fmr) return _find_module(fullname, tail, module.__path__) else: fmr = find_module(fullname, path) return load_module(fullname, *fmr) # It uses vim module itself in place of VimPathFinder class: it does not # matter for python which object has find_module function attached to as # an attribute. class VimPathFinder(object): @classmethod def find_module(cls, fullname, path=None): try: return VimModuleLoader(_find_module(fullname, fullname, path or vim._get_paths())) except ImportError: return None @classmethod def load_module(cls, fullname, path=None): return _find_module(fullname, fullname, path or vim._get_paths()) def hook(path): if path == vim.VIM_SPECIAL_PATH: return VimPathFinder else: raise ImportError sys.path_hooks.append(hook) vim.VIM_SPECIAL_PATH *python-VIM_SPECIAL_PATH* String constant used in conjunction with vim path hook. If path hook installed by vim is requested to handle anything but path equal to vim.VIM_SPECIAL_PATH constant it raises ImportError. In the only other case it uses special loader. Note: you must not use value of this constant directly, always use vim.VIM_SPECIAL_PATH object. vim.find_module(...) *python-find_module* vim.path_hook(path) *python-path_hook* vim.find_spec(...) *python-find_spec* Methods or objects used to implement path loading as described above. You should not be using any of these directly except for vim.path_hook in case you need to do something with sys.meta_path, vim.find_spec() is available starting with Python 3.7. It is not guaranteed that any of the objects will exist in future vim versions. vim._get_paths *python-_get_paths* Methods returning a list of paths which will be searched for by path hook. You should not rely on this method being present in future versions, but can use it for debugging. It returns a list of {rtp}/python2 (or {rtp}/python3) and {rtp}/pythonx directories for each {rtp} in 'runtimepath'. ============================================================================== 3. Buffer objects *python-buffer* Buffer objects represent vim buffers. You can obtain them in a number of ways: - via vim.current.buffer (|python-current|) - from indexing vim.buffers (|python-buffers|) - from the "buffer" attribute of a window (|python-window|) Buffer objects have two read-only attributes - name - the full file name for the buffer, and number - the buffer number. They also have three methods (append, mark, and range; see below). You can also treat buffer objects as sequence objects. In this context, they act as if they were lists (yes, they are mutable) of strings, with each element being a line of the buffer. All of the usual sequence operations, including indexing, index assignment, slicing and slice assignment, work as you would expect. Note that the result of indexing (slicing) a buffer is a string (list of strings). This has one unusual consequence - b[:] is different from b. In particular, "b[:] = None" deletes the whole of the buffer, whereas "b = None" merely updates the variable b, with no effect on the buffer. Buffer indexes start at zero, as is normal in Python. This differs from vim line numbers, which start from 1. This is particularly relevant when dealing with marks (see below) which use vim line numbers. The buffer object attributes are: b.vars Dictionary-like object used to access |buffer-variable|s. b.options Mapping object (supports item getting, setting and deleting) that provides access to buffer-local options and buffer-local values of |global-local| options. Use |python-window|.options if option is window-local, this object will raise KeyError. If option is |global-local| and local value is missing getting it will return None. b.name String, RW. Contains buffer name (full path). Note: when assigning to b.name |BufFilePre| and |BufFilePost| autocommands are launched. b.number Buffer number. Can be used as |python-buffers| key. Read-only. b.valid True or False. Buffer object becomes invalid when corresponding buffer is wiped out. The buffer object methods are: b.append(str) Append a line to the buffer b.append(str, nr) Idem, below line "nr" b.append(list) Append a list of lines to the buffer Note that the option of supplying a list of strings to the append method differs from the equivalent method for Python's built-in list objects. b.append(list, nr) Idem, below line "nr" b.mark(name) Return a tuple (row,col) representing the position of the named mark (can also get the []"<> marks) b.range(s,e) Return a range object (see |python-range|) which represents the part of the given buffer between line numbers s and e |inclusive|. Note that when adding a line it must not contain a line break character '\n'. A trailing '\n' is allowed and ignored, so that you can do: > :py b.append(f.readlines()) Buffer object type is available using "Buffer" attribute of vim module. Examples (assume b is the current buffer) > :py print b.name # write the buffer file name :py b[0] = "hello!!!" # replace the top line :py b[:] = None # delete the whole buffer :py del b[:] # delete the whole buffer :py b[0:0] = [ "a line" ] # add a line at the top :py del b[2] # delete a line (the third) :py b.append("bottom") # add a line at the bottom :py n = len(b) # number of lines :py (row,col) = b.mark('a') # named mark :py r = b.range(1,5) # a sub-range of the buffer :py b.vars["foo"] = "bar" # assign b:foo variable :py b.options["ff"] = "dos" # set fileformat :py del b.options["ar"] # same as :set autoread< ============================================================================== 4. Range objects *python-range* Range objects represent a part of a vim buffer. You can obtain them in a number of ways: - via vim.current.range (|python-current|) - from a buffer's range() method (|python-buffer|) A range object is almost identical in operation to a buffer object. However, all operations are restricted to the lines within the range (this line range can, of course, change as a result of slice assignments, line deletions, or the range.append() method). The range object attributes are: r.start Index of first line into the buffer r.end Index of last line into the buffer The range object methods are: r.append(str) Append a line to the range r.append(str, nr) Idem, after line "nr" r.append(list) Append a list of lines to the range Note that the option of supplying a list of strings to the append method differs from the equivalent method for Python's built-in list objects. r.append(list, nr) Idem, after line "nr" Range object type is available using "Range" attribute of vim module. Example (assume r is the current range): > # Send all lines in a range to the default printer vim.command("%d,%dhardcopy!" % (r.start+1,r.end+1)) ============================================================================== 5. Window objects *python-window* Window objects represent vim windows. You can obtain them in a number of ways: - via vim.current.window (|python-current|) - from indexing vim.windows (|python-windows|) - from indexing "windows" attribute of a tab page (|python-tabpage|) - from the "window" attribute of a tab page (|python-tabpage|) You can manipulate window objects only through their attributes. They have no methods, and no sequence or other interface. Window attributes are: buffer (read-only) The buffer displayed in this window cursor (read-write) The current cursor position in the window This is a tuple, (row,col). height (read-write) The window height, in rows width (read-write) The window width, in columns vars (read-only) The window |w:| variables. Attribute is unassignable, but you can change window variables this way options (read-only) The window-local options. Attribute is unassignable, but you can change window options this way. Provides access only to window-local options, for buffer-local use |python-buffer| and for global ones use |python-options|. If option is |global-local| and local value is missing getting it will return None. number (read-only) Window number. The first window has number 1. This is zero in case it cannot be determined (e.g. when the window object belongs to other tab page). row, col (read-only) On-screen window position in display cells. First position is zero. tabpage (read-only) Window tab page. valid (read-write) True or False. Window object becomes invalid when corresponding window is closed. The height attribute is writable only if the screen is split horizontally. The width attribute is writable only if the screen is split vertically. Window object type is available using "Window" attribute of vim module. ============================================================================== 6. Tab page objects *python-tabpage* Tab page objects represent vim tab pages. You can obtain them in a number of ways: - via vim.current.tabpage (|python-current|) - from indexing vim.tabpages (|python-tabpages|) You can use this object to access tab page windows. They have no methods and no sequence or other interfaces. Tab page attributes are: number The tab page number like the one returned by |tabpagenr()|. windows Like |python-windows|, but for current tab page. vars The tab page |t:| variables. window Current tabpage window. valid True or False. Tab page object becomes invalid when corresponding tab page is closed. TabPage object type is available using "TabPage" attribute of vim module. ============================================================================== 7. vim.bindeval objects *python-bindeval-objects* vim.Dictionary object *python-Dictionary* Dictionary-like object providing access to vim |Dictionary| type. Attributes: Attribute Description ~ locked One of *python-.locked* Value Description ~ zero Variable is not locked vim.VAR_LOCKED Variable is locked, but can be unlocked vim.VAR_FIXED Variable is locked and can't be unlocked Read-write. You can unlock locked variable by assigning `True` or `False` to this attribute. No recursive locking is supported. scope One of Value Description ~ zero Dictionary is not a scope one vim.VAR_DEF_SCOPE |g:| or |l:| dictionary vim.VAR_SCOPE Other scope dictionary, see |internal-variables| Methods (note: methods do not support keyword arguments): Method Description ~ keys() Returns a list with dictionary keys. values() Returns a list with dictionary values. items() Returns a list of 2-tuples with dictionary contents. update(iterable), update(dictionary), update(**kwargs) Adds keys to dictionary. get(key[, default=None]) Obtain key from dictionary, returning the default if it is not present. pop(key[, default]) Remove specified key from dictionary and return corresponding value. If key is not found and default is given returns the default, otherwise raises KeyError. popitem() Remove random key from dictionary and return (key, value) pair. has_key(key) Check whether dictionary contains specified key, similar to `key in dict`. __new__(), __new__(iterable), __new__(dictionary), __new__(update) You can use `vim.Dictionary()` to create new vim dictionaries. `d=vim.Dictionary(arg)` is the same as `d=vim.bindeval('{}');d.update(arg)`. Without arguments constructs empty dictionary. Examples: > d = vim.Dictionary(food="bar") # Constructor d['a'] = 'b' # Item assignment print d['a'] # getting item d.update({'c': 'd'}) # .update(dictionary) d.update(e='f') # .update(**kwargs) d.update((('g', 'h'), ('i', 'j'))) # .update(iterable) for key in d.keys(): # .keys() for val in d.values(): # .values() for key, val in d.items(): # .items() print isinstance(d, vim.Dictionary) # True for key in d: # Iteration over keys class Dict(vim.Dictionary): # Subclassing < Note: when iterating over keys you should not modify dictionary. vim.List object *python-List* Sequence-like object providing access to vim |List| type. Supports `.locked` attribute, see |python-.locked|. Also supports the following methods: Method Description ~ extend(item) Add items to the list. __new__(), __new__(iterable) You can use `vim.List()` to create new vim lists. `l=vim.List(iterable)` is the same as `l=vim.bindeval('[]');l.extend(iterable)`. Without arguments constructs empty list. Examples: > l = vim.List("abc") # Constructor, result: ['a', 'b', 'c'] l.extend(['abc', 'def']) # .extend() method print l[1:] # slicing l[:0] = ['ghi', 'jkl'] # slice assignment print l[0] # getting item l[0] = 'mno' # assignment for i in l: # iteration print isinstance(l, vim.List) # True class List(vim.List): # Subclassing vim.Function object *python-Function* Function-like object, acting like vim |Funcref| object. Accepts special keyword argument `self`, see |Dictionary-function|. You can also use `vim.Function(name)` constructor, it is the same as `vim.bindeval('function(%s)'%json.dumps(name))`. Attributes (read-only): Attribute Description ~ name Function name. args `None` or a |python-List| object with arguments. Note that this is a copy of the arguments list, constructed each time you request this attribute. Modifications made to the list will be ignored (but not to the containers inside argument list: this is like |copy()| and not |deepcopy()|). self `None` or a |python-Dictionary| object with self dictionary. Note that explicit `self` keyword used when calling resulting object overrides this attribute. auto_rebind Boolean. True if partial created from this Python object and stored in the Vim script dictionary should be automatically rebound to the dictionary it is stored in when this dictionary is indexed. Exposes Vim internal difference between `dict.func` (auto_rebind=True) and `function(dict.func,dict)` (auto_rebind=False). This attribute makes no sense if `self` attribute is `None`. Constructor additionally accepts `args`, `self` and `auto_rebind` keywords. If `args` and/or `self` argument is given then it constructs a partial, see |function()|. `auto_rebind` is only used when `self` argument is given, otherwise it is assumed to be `True` regardless of whether it was given or not. If `self` is given then it defaults to `False`. Examples: > f = vim.Function('tr') # Constructor print f('abc', 'a', 'b') # Calls tr('abc', 'a', 'b') vim.command(''' function DictFun() dict return self endfunction ''') f = vim.bindeval('function("DictFun")') print f(self={}) # Like call('DictFun', [], {}) print isinstance(f, vim.Function) # True p = vim.Function('DictFun', self={}) print f() p = vim.Function('tr', args=['abc', 'a']) print f('b') ============================================================================== 8. pyeval() and py3eval() Vim functions *python-pyeval* To facilitate bi-directional interface, you can use |pyeval()| and |py3eval()| functions to evaluate Python expressions and pass their values to Vim script. |pyxeval()| is also available. You can inject local variables into the evaluation using the optional {locals} dict. This can be particularly useful in vim9script where vim.eval |python-eval| will not find locals in a def func. The Python value "None" is converted to v:none. ============================================================================== 9. Dynamic loading *python-dynamic* On MS-Windows and Unix the Python library can be loaded dynamically. The |:version| output then includes |+python/dyn| or |+python3/dyn|. This means that Vim will search for the Python DLL or shared library file only when needed. When you don't use the Python interface you don't need it, thus you can use Vim without this file. MS-Windows ~ To use the Python interface the Python DLL must be in your search path. In a console window type "path" to see what directories are used. If the DLL is not found in your search path, Vim will check the registry to find the path where Python is installed. The 'pythondll' or 'pythonthreedll' option can be also used to specify the Python DLL. The name of the DLL should match the Python version Vim was compiled with. Currently the name for Python 2 is "python27.dll", that is for Python 2.7. That is the default value for 'pythondll'. For Python 3 it is python36.dll (Python 3.6). To know for sure edit "gvim.exe" and search for "python\d*.dll\c". Unix ~ The 'pythondll' or 'pythonthreedll' option can be used to specify the Python shared library file instead of DYNAMIC_PYTHON_DLL or DYNAMIC_PYTHON3_DLL file what were specified at compile time. The version of the shared library must match the Python 2.x or Python 3 version (|v:python3_version|) Vim was compiled with unless using |python3-stable-abi|. Stable ABI and mixing Python versions ~ *python-stable* *python-stable-abi* *python3-stable-abi* If Vim was not compiled with Stable ABI (only available for Python 3), the version of the Python shared library must match the version that Vim was compiled with. Otherwise, mixing versions could result in unexpected crashes and failures. With Stable ABI, this restriction is relaxed, and any Python 3 library with version of at least |v:python3_version| will work. See |has-python| for how to check if Stable ABI is supported, or see if version output includes |+python3/dyn-stable|. On MS-Windows, 'pythonthreedll' will be set to "python3.dll". When searching the DLL from the registry, Vim will search the latest version of Python. ============================================================================== 10. Python 3 *python3* *:py3* *:python3* :[range]py3 {stmt} :[range]py3 << [trim] [{endmarker}] {script} {endmarker} :[range]python3 {stmt} :[range]python3 << [trim] [{endmarker}] {script} {endmarker} The `:py3` and `:python3` commands work similar to `:python`. A simple check if the `:py3` command is working: > :py3 print("Hello") < To see what version of Python you have: > :py3 import sys :py3 print(sys.version) < *:py3file* :[range]py3f[ile] {file} The `:py3file` command works similar to `:pyfile`. *:py3do* :[range]py3do {body} The `:py3do` command works similar to `:pydo`. Vim can be built in four ways (:version output): 1. No Python support (-python, -python3) 2. Python 2 support only (+python or +python/dyn, -python3) 3. Python 3 support only (-python, +python3 or +python3/dyn) 4. Python 2 and 3 support (+python/dyn, +python3/dyn) Some more details on the special case 4: *python-2-and-3* When Python 2 and Python 3 are both supported they must be loaded dynamically. When doing this on Linux/Unix systems and importing global symbols, this leads to a crash when the second Python version is used. So either global symbols are loaded but only one Python version is activated, or no global symbols are loaded. The latter makes Python's "import" fail on libraries that expect the symbols to be provided by Vim. *E836* *E837* Vim's configuration script makes a guess for all libraries based on one standard Python library (termios). If importing this library succeeds for both Python versions, then both will be made available in Vim at the same time. If not, only the version first used in a session will be enabled. When trying to use the other one you will get the E836 or E837 error message. Here Vim's behavior depends on the system in which it was configured. In a system where both versions of Python were configured with --enable-shared, both versions of Python will be activated at the same time. There will still be problems with other third party libraries that were not linked to libPython. To work around such problems there are these options: 1. The problematic library is recompiled to link to the according libpython.so. 2. Vim is recompiled for only one Python version. 3. You undefine PY_NO_RTLD_GLOBAL in auto/config.h after configuration. This may crash Vim though. *E880* Raising SystemExit exception in python isn't endorsed way to quit vim, use: > :py vim.command("qall!") < *E1266* This error can occur when Python 3 cannot load the required modules. This means that your Python 3 is not correctly installed or there are some mistakes in your settings. Please check the following items: 1. Make sure that Python 3 is correctly installed. Also check the version of python. 2. Check the 'pythonthreedll' option. 3. Check the 'pythonthreehome' option. 4. Check the PATH environment variable if you don't set 'pythonthreedll'. On MS-Windows, you can use where.exe to check which dll will be loaded. E.g. > where.exe python310.dll 5. Check the PYTHONPATH and PYTHONHOME environment variables. *has-python* You can test what Python version is available with: > if has('python') echo 'there is Python 2.x' endif if has('python3') echo 'there is Python 3.x' endif Note however, that when Python 2 and 3 are both available and loaded dynamically, these has() calls will try to load them. If only one can be loaded at a time, just checking if Python 2 or 3 are available will prevent the other one from being available. To avoid loading the dynamic library, only check if Vim was compiled with python support: > if has('python_compiled') echo 'compiled with Python 2.x support' if has('python_dynamic') echo 'Python 2.x dynamically loaded' endif endif if has('python3_compiled') echo 'compiled with Python 3.x support' if has('python3_dynamic') echo 'Python 3.x dynamically loaded' endif endif When loading the library dynamically, Vim can be compiled to support Python 3 Stable ABI (|python3-stable-abi|) which allows you to load a different version of Python 3 library than the one Vim was compiled with. To check it: > if has('python3_dynamic') if has('python3_stable') echo 'support Python 3 Stable ABI.' else echo 'does not support Python 3 Stable ABI.' echo 'only use Python 3 version ' .. v:python3_version endif endif This also tells you whether Python is dynamically loaded, which will fail if the runtime library cannot be found. ============================================================================== 11. Python X *python_x* *pythonx* Because most python code can be written so that it works with Python 2.6+ and Python 3 the pyx* functions and commands have been written. They work exactly the same as the Python 2 and 3 variants, but select the Python version using the 'pyxversion' setting. You should set 'pyxversion' in your |.vimrc| to prefer Python 2 or Python 3 for Python commands. If you change this setting at runtime you may risk that state of plugins (such as initialization) may be lost. If you want to use a module, you can put it in the {rtp}/pythonx directory. See |pythonx-directory|. *:pyx* *:pythonx* The `:pyx` and `:pythonx` commands work similar to `:python`. A simple check if the `:pyx` command is working: > :pyx print("Hello") To see what version of Python is being used: > :pyx import sys :pyx print(sys.version) < *:pyxfile* *python_x-special-comments* The `:pyxfile` command works similar to `:pyfile`. However you can add one of these comments to force Vim using `:pyfile` or `:py3file`: > #!/any string/python2 " Shebang. Must be the first line of the file. #!/any string/python3 " Shebang. Must be the first line of the file. # requires python 2.x " Maximum lines depend on 'modelines'. # requires python 3.x " Maximum lines depend on 'modelines'. Unlike normal modelines, the bottom of the file is not checked. If none of them are found, the 'pyxversion' setting is used. *W20* *W21* If Vim does not support the selected Python version a silent message will be printed. Use `:messages` to read them. *:pyxdo* The `:pyxdo` command works similar to `:pydo`. *has-pythonx* You can test if pyx* commands are available with: > if has('pythonx') echo 'pyx* commands are available. (Python ' .. &pyx .. ')' endif When compiled with only one of |+python| or |+python3|, the has() returns 1. When compiled with both |+python| and |+python3|, the test depends on the 'pyxversion' setting. If 'pyxversion' is 0, it tests Python 3 first, and if it is not available then Python 2. If 'pyxversion' is 2 or 3, it tests only Python 2 or 3 respectively. Note that for `has('pythonx')` to work it may try to dynamically load Python 3 or 2. This may have side effects, especially when Vim can only load one of the two. If a user prefers Python 2 and want to fallback to Python 3, he needs to set 'pyxversion' explicitly in his |.vimrc|. E.g.: > if has('python') set pyx=2 elseif has('python3') set pyx=3 endif ============================================================================== 12. Building with Python support *python-building* A few hints for building with Python 2 or 3 support. UNIX See src/Makefile for how to enable including the Python interface. On Ubuntu you will want to install these packages for Python 2: python python-dev For Python 3: python3 python3-dev For Python 3.6: python3.6 python3.6-dev If you have more than one version of Python 3, you need to link python3 to the one you prefer, before running configure. ============================================================================== vim:tw=78:ts=8:noet:ft=help:norl: