[Zope-Checkins] CVS: ZODB3/BTrees - check.py:1.1.2.1
Tim Peters
tim.one@comcast.net
Tue, 14 Jan 2003 17:25:15 -0500
Update of /cvs-repository/ZODB3/BTrees
In directory cvs.zope.org:/tmp/cvs-serv11036/BTrees
Added Files:
Tag: ZODB3-3_1-branch
check.py
Log Message:
New btrees module check.py (and test program). The primary new function
is check.check(btree), which performs value-based sanity checks on a BTree
(or TreeSet) that the btree._check() method doesn't do. The new checks
include that all the bucket keys are in sorted order, and that all the
keys within each bucket, and within each internal BTree node, lie within
the range necessary for that node. That last is a subtle invariant that
can't be checked locally: it requires propagating range info down the
tree, and modifying it for each child and each level. This *should* catch
any BTree B for which iterating over the keys yields a key K for which
B.has_key(K) returns false.
Another function check.display(btree) prints the internal structure of
a BTree (or TreeSet, Bucket, or Set) to stdout. If check.check(B)
ever complains, a clearer picture of the damage can be gotten by
staring at check.display(B)'s output.
Also beefed up the regular BTree tests by calling check.check() in key
places. No surprises (the tests still pass).
=== Added File ZODB3/BTrees/check.py ===
##############################################################################
#
# Copyright (c) 2003 Zope Corporation and Contributors.
# All Rights Reserved.
#
# This software is subject to the provisions of the Zope Public License,
# Version 2.0 (ZPL). A copy of the ZPL should accompany this distribution.
# THIS SOFTWARE IS PROVIDED "AS IS" AND ANY AND ALL EXPRESS OR IMPLIED
# WARRANTIES ARE DISCLAIMED, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED
# WARRANTIES OF TITLE, MERCHANTABILITY, AGAINST INFRINGEMENT, AND FITNESS
# FOR A PARTICULAR PURPOSE
#
##############################################################################
"""
Utilities for working with BTrees (TreeSets, Buckets, and Sets) at a low
level.
The primary function is check(btree), which performs value-based consistency
checks of a kind btree._check() does not perform. See the function docstring
for details.
display(btree) displays the internal structure of a BTree (TreeSet, etc) to
stdout.
CAUTION: When a BTree node has only a single bucket child, it can be
impossible to get at the bucket from Python code (__getstate__() may squash
the bucket object out of existence, as a pickling storage optimization). In
such a case, the code here synthesizes a temporary bucket with the same keys
(and values, if the bucket is of a mapping type). This has no first-order
consequences, but can mislead if you pay close attention to reported object
addresses and/or object identity (the synthesized bucket has an address
that doesn't exist in the actual BTree).
"""
try:
from zodb.btrees.OOBTree import OOBTree, OOBucket, OOSet, OOTreeSet
from zodb.btrees.OIBTree import OIBTree, OIBucket, OISet, OITreeSet
from zodb.btrees.IOBTree import IOBTree, IOBucket, IOSet, IOTreeSet
from zodb.btrees.IIBTree import IIBTree, IIBucket, IISet, IITreeSet
except ImportError:
from BTrees.OOBTree import OOBTree, OOBucket, OOSet, OOTreeSet
from BTrees.OIBTree import OIBTree, OIBucket, OISet, OITreeSet
from BTrees.IOBTree import IOBTree, IOBucket, IOSet, IOTreeSet
from BTrees.IIBTree import IIBTree, IIBucket, IISet, IITreeSet
TYPE_UNKNOWN, TYPE_BTREE, TYPE_BUCKET = range(3)
_type2kind = {IOBTree: (TYPE_BTREE, True),
IIBTree: (TYPE_BTREE, True),
OIBTree: (TYPE_BTREE, True),
OOBTree: (TYPE_BTREE, True),
IOBucket: (TYPE_BUCKET, True),
IIBucket: (TYPE_BUCKET, True),
OIBucket: (TYPE_BUCKET, True),
OOBucket: (TYPE_BUCKET, True),
IOTreeSet: (TYPE_BTREE, False),
IITreeSet: (TYPE_BTREE, False),
OITreeSet: (TYPE_BTREE, False),
OOTreeSet: (TYPE_BTREE, False),
IOSet: (TYPE_BUCKET, False),
IISet: (TYPE_BUCKET, False),
OISet: (TYPE_BUCKET, False),
OOSet: (TYPE_BUCKET, False),
}
# Return pair
#
# TYPE_BTREE or TYPE_BUCKET, is_mapping
def classify(obj):
return _type2kind[type(obj)]
BTREE_EMPTY, BTREE_ONE, BTREE_NORMAL = range(3)
# If the BTree is empty, returns
#
# BTREE_EMPTY, [], []
#
# If the BTree has only one bucket, sometimes returns
#
# BTREE_ONE, bucket_state, None
#
# Else returns
#
# BTREE_NORMAL, list of keys, list of kids
#
# and the list of kids has one more entry than the list of keys.
#
# BTree.__getstate__() docs:
#
# For an empty BTree (self->len == 0), None.
#
# For a BTree with one child (self->len == 1), and that child is a bucket,
# and that bucket has a NULL oid, a one-tuple containing a one-tuple
# containing the bucket's state:
#
# (
# (
# child[0].__getstate__(),
# ),
# )
#
# Else a two-tuple. The first element is a tuple interleaving the BTree's
# keys and direct children, of size 2*self->len - 1 (key[0] is unused and
# is not saved). The second element is the firstbucket:
#
# (
# (child[0], key[1], child[1], key[2], child[2], ...,
# key[len-1], child[len-1]),
# self->firstbucket
# )
_btree2bucket = {IOBTree: IOBucket,
IOTreeSet: IOSet,
IIBTree: IIBucket,
IITreeSet: IISet,
OIBTree: OIBucket,
OITreeSet: OISet,
OOBTree: OOBucket,
OOTreeSet: OOSet}
def crack_btree(t, is_mapping):
state = t.__getstate__()
if state is None:
return BTREE_EMPTY, [], []
assert isinstance(state, tuple)
if len(state) == 1:
state = state[0]
assert isinstance(state, tuple) and len(state) == 1
state = state[0]
return BTREE_ONE, state, None
assert len(state) == 2
data, firstbucket = state
n = len(data)
assert n & 1
kids = []
keys = []
i = 0
for x in data:
if i & 1:
keys.append(x)
else:
kids.append(x)
i += 1
return BTREE_NORMAL, keys, kids
# Returns
#
# keys, values # for a mapping; len(keys) == len(values) in this case
# or
# keys, [] # for a set
#
# bucket.__getstate__() docs:
#
# For a set bucket (self->values is NULL), a one-tuple or two-tuple. The
# first element is a tuple of keys, of length self->len. The second element
# is the next bucket, present if and only if next is non-NULL:
#
# (
# (keys[0], keys[1], ..., keys[len-1]),
# <self->next iff non-NULL>
# )
#
# For a mapping bucket (self->values is not NULL), a one-tuple or two-tuple.
# The first element is a tuple interleaving keys and values, of length
# 2 * self->len. The second element is the next bucket, present iff next is
# non-NULL:
#
# (
# (keys[0], values[0], keys[1], values[1], ...,
# keys[len-1], values[len-1]),
# <self->next iff non-NULL>
# )
def crack_bucket(b, is_mapping):
state = b.__getstate__()
assert isinstance(state, tuple)
assert 1 <= len(state) <= 2
data = state[0]
if not is_mapping:
return data, []
keys = []
values = []
n = len(data)
assert n & 1 == 0
i = 0
for x in data:
if i & 1:
values.append(x)
else:
keys.append(x)
i += 1
return keys, values
def type_and_adr(obj):
return "%s (0x%x)" % (type(obj).__name__, id(obj))
# Walker implements a depth-first search of a BTree (or TreeSet or Set or
# Bucket). Subclasses must implement the visit_btree() and visit_bucket()
# methods, and arrange to call the walk() method. walk() calls the
# visit_XYZ() methods once for each node in the tree, in depth-first
# left-to-right order.
class Walker(object):
def __init__(self, obj):
self.obj = obj
# obj is the BTree (BTree or TreeSet).
# path is a list of indices, from the root. For example, if a BTree node
# is child[5] of child[3] of the root BTree, [3, 5].
# parent is the parent BTree object, or None if this is the root BTree.
# is_mapping is True for a BTree and False for a TreeSet.
# keys is a list of the BTree's internal keys.
# kids is a list of the BTree's children.
# If the BTree is an empty root node, keys == kids == [].
# Else len(kids) == len(keys) + 1.
# lo and hi are slice bounds on the values the elements of keys *should*
# lie in (lo inclusive, hi exclusive). lo is None if there is no lower
# bound known, and hi is None if no upper bound is known.
def visit_btree(self, obj, path, parent, is_mapping,
keys, kids, lo, hi):
raise NotImplementedError
# obj is the bucket (Bucket or Set).
# path is a list of indices, from the root. For example, if a bucket
# node is child[5] of child[3] of the root BTree, [3, 5].
# parent is the parent BTree object.
# is_mapping is True for a Bucket and False for a Set.
# keys is a list of the bucket's keys.
# values is a list of the bucket's values.
# If is_mapping is false, values == []. Else len(keys) == len(values).
# lo and hi are slice bounds on the values the elements of keys *should*
# lie in (lo inclusive, hi exclusive). lo is None if there is no lower
# bound known, and hi is None if no upper bound is known.
def visit_bucket(self, obj, path, parent, is_mapping,
keys, values, lo, hi):
raise NotImplementedError
def walk(self):
obj = self.obj
path = []
stack = [(obj, path, None, None, None)]
while stack:
obj, path, parent, lo, hi = stack.pop()
kind, is_mapping = classify(obj)
if kind is TYPE_BTREE:
bkind, keys, kids = crack_btree(obj, is_mapping)
if bkind is BTREE_NORMAL:
# push the kids, in reverse order (so they're popped off
# the stack in forward order)
n = len(kids)
for i in range(len(kids)-1, -1, -1):
newlo, newhi = lo, hi
if i < n-1:
newhi = keys[i]
if i > 0:
newlo = keys[i-1]
stack.append((kids[i],
path + [i],
obj,
newlo,
newhi))
elif bkind is BTREE_EMPTY:
pass
else:
assert bkind is BTREE_ONE
# Yuck. There isn't a bucket object to pass on, as
# the bucket state is embedded directly in the BTree
# state. Synthesize a bucket.
assert kids is None # and "keys" is really the bucket
# state
bucket = _btree2bucket[type(obj)]()
bucket.__setstate__(keys)
stack.append((bucket,
path + [0],
obj,
lo,
hi))
keys = []
kids = [bucket]
self.visit_btree(obj,
path,
parent,
is_mapping,
keys,
kids,
lo,
hi)
else:
assert kind is TYPE_BUCKET
keys, values = crack_bucket(obj, is_mapping)
self.visit_bucket(obj,
path,
parent,
is_mapping,
keys,
values,
lo,
hi)
class Checker(Walker):
def __init__(self, obj):
Walker.__init__(self, obj)
self.errors = []
def check(self):
self.walk()
if self.errors:
s = "Errors found in %s:" % type_and_adr(self.obj)
self.errors.insert(0, s)
s = "\n".join(self.errors)
raise AssertionError(s)
def visit_btree(self, obj, path, parent, is_mapping,
keys, kids, lo, hi):
self.check_sorted(obj, path, keys, lo, hi)
def visit_bucket(self, obj, path, parent, is_mapping,
keys, values, lo, hi):
self.check_sorted(obj, path, keys, lo, hi)
def check_sorted(self, obj, path, keys, lo, hi):
i, n = 0, len(keys)
for x in keys:
if lo is not None and not lo <= x:
s = "key %r < lower bound %r at index %d" % (x, lo, i)
self.complain(s, obj, path)
if hi is not None and not x < hi:
s = "key %r >= upper bound %r at index %d" % (x, hi, i)
self.complain(s, obj, path)
if i < n-1 and not x < keys[i+1]:
s = "key %r at index %d >= key %r at index %d" % (
x, i, keys[i+1], i+1)
self.complain(s, obj, path)
i += 1
def complain(self, msg, obj, path):
s = "%s, in %s, path from root %s" % (
msg,
type_and_adr(obj),
".".join(map(str, path)))
self.errors.append(s)
class Printer(Walker):
def __init__(self, obj):
Walker.__init__(self, obj)
def display(self):
self.walk()
def visit_btree(self, obj, path, parent, is_mapping,
keys, kids, lo, hi):
indent = " " * len(path)
print "%s%s %s with %d children" % (
indent,
".".join(map(str, path)),
type_and_adr(obj),
len(kids))
indent += " "
n = len(keys)
for i in range(n):
print "%skey %d: %r" % (indent, i, keys[i])
def visit_bucket(self, obj, path, parent, is_mapping,
keys, values, lo, hi):
indent = " " * len(path)
print "%s%s %s with %d keys" % (
indent,
".".join(map(str, path)),
type_and_adr(obj),
len(keys))
indent += " "
n = len(keys)
for i in range(n):
print "%skey %d: %r" % (indent, i, keys[i]),
if is_mapping:
print "value %r" % (values[i],)
def check(btree):
"""Check internal value-based invariants in a BTree or TreeSet.
The btree._check() method checks internal C-level pointer consistency.
The check() function here checks value-based invariants: whether the
keys in leaf bucket and internal nodes are in strictly increasing order,
and whether they all lie in their expected range. The latter is a subtle
invariant that can't be checked locally -- it requires propagating
range info down from the root of the tree, and modifying it at each
level for each child.
Raises AssertionError if anything is wrong, with a string detail
explaining the problems. The entire tree is checked before
AssertionError is raised, and the string detail may be large (depending
on how much went wrong).
"""
Checker(btree).check()
def display(btree):
"Display the internal structure of a BTree, Bucket, TreeSet or Set."
Printer(btree).display()
def _test():
t = OOBTree()
for i in range(31):
t[i] = 2*i
display(t)
check(t)
s = t.__getstate__()
# Looks like (state, first_bucket)
# where state looks like (bucket0, 15, bucket1).
assert len(s) == 2
assert len(s[0]) == 3
assert s[0][1] == 15
# Damage an invariant by dropping the BTree key to 14.
news = (s[0][0], 14, s[0][2]), s[1]
t.__setstate__(news)
display(t)
check(t)
if __name__ == "__main__":
_test()