PEP: 280 Title: Optimizing access to globals Version: $Revision$ Last-Modified: $Date$ Author: guido@python.org (Guido van Rossum) Status: Deferred Type: Standards Track Content-Type: text/x-rst Created: 10-Feb-2002 Python-Version: 2.3 Post-History: Deferral ======== While this PEP is a nice idea, no-one has yet emerged to do the work of hashing out the differences between this PEP, PEP 266 and PEP 267. Hence, it is being deferred. Abstract ======== This PEP describes yet another approach to optimizing access to module globals, providing an alternative to PEP 266 (Optimizing Global Variable/Attribute Access by Skip Montanaro) and PEP 267 (Optimized Access to Module Namespaces by Jeremy Hylton). The expectation is that eventually one approach will be picked and implemented; possibly multiple approaches will be prototyped first. Description =========== (Note: Jason Orendorff writes: """I implemented this once, long ago, for Python 1.5-ish, I believe. I got it to the point where it was only 15% slower than ordinary Python, then abandoned it. ;) In my implementation, "cells" were real first-class objects, and "celldict" was a copy-and-hack version of dictionary. I forget how the rest worked.""" Reference: https://mail.python.org/pipermail/python-dev/2002-February/019876.html) Let a cell be a really simple Python object, containing a pointer to a Python object and a pointer to a cell. Both pointers may be ``NULL``. A Python implementation could be:: class cell(object): def __init__(self): self.objptr = NULL self.cellptr = NULL The cellptr attribute is used for chaining cells together for searching built-ins; this will be explained later. Let a celldict be a mapping from strings (the names of a module's globals) to objects (the values of those globals), implemented using a dict of cells. A Python implementation could be:: class celldict(object): def __init__(self): self.__dict = {} # dict of cells def getcell(self, key): c = self.__dict.get(key) if c is None: c = cell() self.__dict[key] = c return c def cellkeys(self): return self.__dict.keys() def __getitem__(self, key): c = self.__dict.get(key) if c is None: raise KeyError, key value = c.objptr if value is NULL: raise KeyError, key else: return value def __setitem__(self, key, value): c = self.__dict.get(key) if c is None: c = cell() self.__dict[key] = c c.objptr = value def __delitem__(self, key): c = self.__dict.get(key) if c is None or c.objptr is NULL: raise KeyError, key c.objptr = NULL def keys(self): return [k for k, c in self.__dict.iteritems() if c.objptr is not NULL] def items(self): return [k, c.objptr for k, c in self.__dict.iteritems() if c.objptr is not NULL] def values(self): preturn [c.objptr for c in self.__dict.itervalues() if c.objptr is not NULL] def clear(self): for c in self.__dict.values(): c.objptr = NULL # Etc. It is possible that a cell exists corresponding to a given key, but the cell's objptr is ``NULL``; let's call such a cell empty. When the celldict is used as a mapping, it is as if empty cells don't exist. However, once added, a cell is never deleted from a celldict, and it is possible to get at empty cells using the ``getcell()`` method. The celldict implementation never uses the cellptr attribute of cells. We change the module implementation to use a celldict for its ``__dict__``. The module's getattr, setattr and delattr operations now map to getitem, setitem and delitem on the celldict. The type of ``.__dict__`` and ``globals()`` is probably the only backwards incompatibility. When a module is initialized, its ``__builtins__`` is initialized from the ``__builtin__`` module's ``__dict__``, which is itself a celldict. For each cell in ``__builtins__``, the new module's ``__dict__`` adds a cell with a ``NULL`` objptr, whose cellptr points to the corresponding cell of ``__builtins__``. Python pseudo-code (ignoring rexec):: import __builtin__ class module(object): def __init__(self): self.__dict__ = d = celldict() d['__builtins__'] = bd = __builtin__.__dict__ for k in bd.cellkeys(): c = self.__dict__.getcell(k) c.cellptr = bd.getcell(k) def __getattr__(self, k): try: return self.__dict__[k] except KeyError: raise IndexError, k def __setattr__(self, k, v): self.__dict__[k] = v def __delattr__(self, k): del self.__dict__[k] The compiler generates ``LOAD_GLOBAL_CELL `` (and ``STORE_GLOBAL_CELL `` etc.) opcodes for references to globals, where ```` is a small index with meaning only within one code object like the const index in ``LOAD_CONST``. The code object has a new tuple, ``co_globals``, giving the names of the globals referenced by the code indexed by ````. No new analysis is required to be able to do this. When a function object is created from a code object and a celldict, the function object creates an array of cell pointers by asking the celldict for cells corresponding to the names in the code object's ``co_globals``. If the celldict doesn't already have a cell for a particular name, it creates and an empty one. This array of cell pointers is stored on the function object as ``func_cells``. When a function object is created from a regular dict instead of a celldict, ``func_cells`` is a ``NULL`` pointer. When the VM executes a ``LOAD_GLOBAL_CELL `` instruction, it gets cell number ```` from ``func_cells``. It then looks in the cell's ``PyObject`` pointer, and if not ``NULL``, that's the global value. If it is ``NULL``, it follows the cell's cell pointer to the next cell, if it is not ``NULL``, and looks in the ``PyObject`` pointer in that cell. If that's also ``NULL``, or if there is no second cell, ``NameError`` is raised. (It could follow the chain of cell pointers until a ``NULL`` cell pointer is found; but I have no use for this.) Similar for ``STORE_GLOBAL_CELL ``, except it doesn't follow the cell pointer chain -- it always stores in the first cell. There are fallbacks in the VM for the case where the function's globals aren't a celldict, and hence ``func_cells`` is ``NULL``. In that case, the code object's ``co_globals`` is indexed with ```` to find the name of the corresponding global and this name is used to index the function's globals dict. Additional Ideas ================ - Never make ``func_cell`` a ``NULL`` pointer; instead, make up an array of empty cells, so that ``LOAD_GLOBAL_CELL`` can index ``func_cells`` without a ``NULL`` check. - Make ``c.cellptr`` equal to c when a cell is created, so that ``LOAD_GLOBAL_CELL`` can always dereference ``c.cellptr`` without a ``NULL`` check. With these two additional ideas added, here's Python pseudo-code for ``LOAD_GLOBAL_CELL``:: def LOAD_GLOBAL_CELL(self, i): # self is the frame c = self.func_cells[i] obj = c.objptr if obj is not NULL: return obj # Existing global return c.cellptr.objptr # Built-in or NULL - Be more aggressive: put the actual values of builtins into module dicts, not just pointers to cells containing the actual values. There are two points to this: (1) Simplify and speed access, which is the most common operation. (2) Support faithful emulation of extreme existing corner cases. WRT #2, the set of builtins in the scheme above is captured at the time a module dict is first created. Mutations to the set of builtin names following that don't get reflected in the module dicts. Example: consider files ``main.py`` and ``cheater.py``:: [main.py] import cheater def f(): cheater.cheat() return pachinko() print f() [cheater.py] def cheat(): import __builtin__ __builtin__.pachinko = lambda: 666 If ``main.py`` is run under Python 2.2 (or before), 666 is printed. But under the proposal, ``__builtin__.pachinko`` doesn't exist at the time main's ``__dict__`` is initialized. When the function object for f is created, ``main.__dict__`` grows a pachinko cell mapping to two ``NULLs``. When ``cheat()`` is called, ``__builtin__.__dict__`` grows a pachinko cell too, but ``main.__dict__`` doesn't know-- and will never know --about that. When f's return stmt references pachinko, in will still find the double-NULLs in ``main.__dict__``'s ``pachinko`` cell, and so raise ``NameError``. A similar (in cause) break in compatibility can occur if a module global foo is del'ed, but a builtin foo was created prior to that but after the module dict was first created. Then the builtin foo becomes visible in the module under 2.2 and before, but remains invisible under the proposal. Mutating builtins is extremely rare (most programs never mutate the builtins, and it's hard to imagine a plausible use for frequent mutation of the builtins -- I've never seen or heard of one), so it doesn't matter how expensive mutating the builtins becomes. OTOH, referencing globals and builtins is very common. Combining those observations suggests a more aggressive caching of builtins in module globals, speeding access at the expense of making mutations of the builtins (potentially much) more expensive to keep the caches in synch. Much of the scheme above remains the same, and most of the rest is just a little different. A cell changes to:: class cell(object): def __init__(self, obj=NULL, builtin=0): self.objptr = obj self.builtinflag = builtin and a celldict maps strings to this version of cells. ``builtinflag`` is true when and only when objptr contains a value obtained from the builtins; in other words, it's true when and only when a cell is acting as a cached value. When ``builtinflag`` is false, objptr is the value of a module global (possibly ``NULL``). celldict changes to:: class celldict(object): def __init__(self, builtindict=()): self.basedict = builtindict self.__dict = d = {} for k, v in builtindict.items(): d[k] = cell(v, 1) def __getitem__(self, key): c = self.__dict.get(key) if c is None or c.objptr is NULL or c.builtinflag: raise KeyError, key return c.objptr def __setitem__(self, key, value): c = self.__dict.get(key) if c is None: c = cell() self.__dict[key] = c c.objptr = value c.builtinflag = 0 def __delitem__(self, key): c = self.__dict.get(key) if c is None or c.objptr is NULL or c.builtinflag: raise KeyError, key c.objptr = NULL # We may have unmasked a builtin. Note that because # we're checking the builtin dict for that *now*, this # still works if the builtin first came into existence # after we were constructed. Note too that del on # namespace dicts is rare, so the expensse of this check # shouldn't matter. if key in self.basedict: c.objptr = self.basedict[key] assert c.objptr is not NULL # else "in" lied c.builtinflag = 1 else: # There is no builtin with the same name. assert not c.builtinflag def keys(self): return [k for k, c in self.__dict.iteritems() if c.objptr is not NULL and not c.builtinflag] def items(self): return [k, c.objptr for k, c in self.__dict.iteritems() if c.objptr is not NULL and not c.builtinflag] def values(self): preturn [c.objptr for c in self.__dict.itervalues() if c.objptr is not NULL and not c.builtinflag] def clear(self): for c in self.__dict.values(): if not c.builtinflag: c.objptr = NULL # Etc. The speed benefit comes from simplifying ``LOAD_GLOBAL_CELL``, which I expect is executed more frequently than all other namespace operations combined:: def LOAD_GLOBAL_CELL(self, i): # self is the frame c = self.func_cells[i] return c.objptr # may be NULL (also true before) That is, accessing builtins and accessing module globals are equally fast. For module globals, a NULL-pointer test+branch is saved. For builtins, an additional pointer chase is also saved. The other part needed to make this fly is expensive, propagating mutations of builtins into the module dicts that were initialized from the builtins. This is much like, in 2.2, propagating changes in new-style base classes to their descendants: the builtins need to maintain a list of weakrefs to the modules (or module dicts) initialized from the builtin's dict. Given a mutation to the builtin dict (adding a new key, changing the value associated with an existing key, or deleting a key), traverse the list of module dicts and make corresponding mutations to them. This is straightforward; for example, if a key is deleted from builtins, execute ``reflect_bltin_del`` in each module:: def reflect_bltin_del(self, key): c = self.__dict.get(key) assert c is not None # else we were already out of synch if c.builtinflag: # Put us back in synch. c.objptr = NULL c.builtinflag = 0 # Else we're shadowing the builtin, so don't care that # the builtin went away. Note that ``c.builtinflag`` protects from us erroneously deleting a module global of the same name. Adding a new (key, value) builtin pair is similar:: def reflect_bltin_new(self, key, value): c = self.__dict.get(key) if c is None: # Never heard of it before: cache the builtin value. self.__dict[key] = cell(value, 1) elif c.objptr is NULL: # This used to exist in the module or the builtins, # but doesn't anymore; rehabilitate it. assert not c.builtinflag c.objptr = value c.builtinflag = 1 else: # We're shadowing it already. assert not c.builtinflag Changing the value of an existing builtin:: def reflect_bltin_change(self, key, newvalue): c = self.__dict.get(key) assert c is not None # else we were already out of synch if c.builtinflag: # Put us back in synch. c.objptr = newvalue # Else we're shadowing the builtin, so don't care that # the builtin changed. FAQs ==== * Q: Will it still be possible to: a) install new builtins in the ``__builtin__`` namespace and have them available in all already loaded modules right away ? b) override builtins (e.g. ``open()``) with my own copies (e.g. to increase security) in a way that makes these new copies override the previous ones in all modules ? A: Yes, this is the whole point of this design. In the original approach, when ``LOAD_GLOBAL_CELL`` finds a ``NULL`` in the second cell, it should go back to see if the ``__builtins__`` dict has been modified (the pseudo code doesn't have this yet). Tim's "more aggressive" alternative also takes care of this. * Q: How does the new scheme get along with the restricted execution model? A: It is intended to support that fully. * Q: What happens when a global is deleted? A: The module's celldict would have a cell with a ``NULL`` objptr for that key. This is true in both variations, but the "aggressive" variation goes on to see whether this unmasks a builtin of the same name, and if so copies its value (just a pointer-copy of the ultimate ``PyObject*``) into the cell's objptr and sets the cell's ``builtinflag`` to true. * Q: What would the C code for ``LOAD_GLOBAL_CELL`` look like? A: The first version, with the first two bullets under "Additional ideas" incorporated, could look like this:: case LOAD_GLOBAL_CELL: cell = func_cells[oparg]; x = cell->objptr; if (x == NULL) { x = cell->cellptr->objptr; if (x == NULL) { ... error recovery ... break; } } Py_INCREF(x); PUSH(x); continue; We could even write it like this (idea courtesy of Ka-Ping Yee):: case LOAD_GLOBAL_CELL: cell = func_cells[oparg]; x = cell->cellptr->objptr; if (x != NULL) { Py_INCREF(x); PUSH(x); continue; } ... error recovery ... break; In modern CPU architectures, this reduces the number of branches taken for built-ins, which might be a really good thing, while any decent memory cache should realize that ``cell->cellptr`` is the same as cell for regular globals and hence this should be very fast in that case too. For the aggressive variant:: case LOAD_GLOBAL_CELL: cell = func_cells[oparg]; x = cell->objptr; if (x != NULL) { Py_INCREF(x); PUSH(x); continue; } ... error recovery ... break; * Q: What happens in the module's top-level code where there is presumably no ``func_cells`` array? A: We could do some code analysis and create a ``func_cells`` array, or we could use ``LOAD_NAME`` which should use ``PyMapping_GetItem`` on the globals dict. Graphics ======== Ka-Ping Yee supplied a drawing of the state of things after "import spam", where ``spam.py`` contains:: import eggs i = -2 max = 3 def foo(n): y = abs(i) + max return eggs.ham(y + n) The drawing is at http://web.lfw.org/repo/cells.gif; a larger version is at http://lfw.org/repo/cells-big.gif; the source is at http://lfw.org/repo/cells.ai. Comparison ========== XXX Here, a comparison of the three approaches could be added. Copyright ========= This document has been placed in the public domain. .. 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