cpython/Doc/lib/libdifflib.tex
2001-04-10 19:56:09 +00:00

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\section{\module{difflib} ---
Helpers for computing deltas}
\declaremodule{standard}{difflib}
\modulesynopsis{Helpers for computing differences between objects.}
\moduleauthor{Tim Peters}{tim.one@home.com}
\sectionauthor{Tim Peters}{tim.one@home.com}
% LaTeXification by Fred L. Drake, Jr. <fdrake@acm.org>.
\versionadded{2.1}
\begin{funcdesc}{get_close_matches}{word, possibilities\optional{,
n\optional{, cutoff}}}
Return a list of the best ``good enough'' matches. \var{word} is a
sequence for which close matches are desired (typically a string),
and \var{possibilities} is a list of sequences against which to
match \var{word} (typically a list of strings).
Optional argument \var{n} (default \code{3}) is the maximum number
of close matches to return; \var{n} must be greater than \code{0}.
Optional argument \var{cutoff} (default \code{0.6}) is a float in
the range [0, 1]. Possibilities that don't score at least that
similar to \var{word} are ignored.
The best (no more than \var{n}) matches among the possibilities are
returned in a list, sorted by similarity score, most similar first.
\begin{verbatim}
>>> get_close_matches('appel', ['ape', 'apple', 'peach', 'puppy'])
['apple', 'ape']
>>> import keyword
>>> get_close_matches('wheel', keyword.kwlist)
['while']
>>> get_close_matches('apple', keyword.kwlist)
[]
>>> get_close_matches('accept', keyword.kwlist)
['except']
\end{verbatim}
\end{funcdesc}
\begin{classdesc}{SequenceMatcher}{\unspecified}
This is a flexible class for comparing pairs of sequences of any
type, so long as the sequence elements are hashable. The basic
algorithm predates, and is a little fancier than, an algorithm
published in the late 1980's by Ratcliff and Obershelp under the
hyperbolic name ``gestalt pattern matching.'' The idea is to find
the longest contiguous matching subsequence that contains no
``junk'' elements (the Ratcliff and Obershelp algorithm doesn't
address junk). The same idea is then applied recursively to the
pieces of the sequences to the left and to the right of the matching
subsequence. This does not yield minimal edit sequences, but does
tend to yield matches that ``look right'' to people.
\strong{Timing:} The basic Ratcliff-Obershelp algorithm is cubic
time in the worst case and quadratic time in the expected case.
\class{SequenceMatcher} is quadratic time for the worst case and has
expected-case behavior dependent in a complicated way on how many
elements the sequences have in common; best case time is linear.
\end{classdesc}
\begin{seealso}
\seetitle{Pattern Matching: The Gestalt Approach}{Discussion of a
similar algorithm by John W. Ratcliff and D. E. Metzener.
This was published in
\citetitle[http://www.ddj.com/]{Dr. Dobb's Journal} in
July, 1988.}
\end{seealso}
\subsection{SequenceMatcher Objects \label{sequence-matcher}}
\begin{classdesc}{SequenceMatcher}{\optional{isjunk\optional{,
a\optional{, b}}}}
Optional argument \var{isjunk} must be \code{None} (the default) or
a one-argument function that takes a sequence element and returns
true if and only if the element is ``junk'' and should be ignored.
\code{None} is equivalent to passing \code{lambda x: 0}, i.e.\ no
elements are ignored. For example, pass
\begin{verbatim}
lambda x: x in " \t"
\end{verbatim}
if you're comparing lines as sequences of characters, and don't want
to synch up on blanks or hard tabs.
The optional arguments \var{a} and \var{b} are sequences to be
compared; both default to empty strings. The elements of both
sequences must be hashable.
\end{classdesc}
\class{SequenceMatcher} objects have the following methods:
\begin{methoddesc}{set_seqs}{a, b}
Set the two sequences to be compared.
\end{methoddesc}
\class{SequenceMatcher} computes and caches detailed information about
the second sequence, so if you want to compare one sequence against
many sequences, use \method{set_seq2()} to set the commonly used
sequence once and call \method{set_seq1()} repeatedly, once for each
of the other sequences.
\begin{methoddesc}{set_seq1}{a}
Set the first sequence to be compared. The second sequence to be
compared is not changed.
\end{methoddesc}
\begin{methoddesc}{set_seq2}{b}
Set the second sequence to be compared. The first sequence to be
compared is not changed.
\end{methoddesc}
\begin{methoddesc}{find_longest_match}{alo, ahi, blo, bhi}
Find longest matching block in \code{\var{a}[\var{alo}:\var{ahi}]}
and \code{\var{b}[\var{blo}:\var{bhi}]}.
If \var{isjunk} was omitted or \code{None},
\method{get_longest_match()} returns \code{(\var{i}, \var{j},
\var{k})} such that \code{\var{a}[\var{i}:\var{i}+\var{k}]} is equal
to \code{\var{b}[\var{j}:\var{j}+\var{k}]}, where
\code{\var{alo} <= \var{i} <= \var{i}+\var{k} <= \var{ahi}} and
\code{\var{blo} <= \var{j} <= \var{j}+\var{k} <= \var{bhi}}.
For all \code{(\var{i'}, \var{j'}, \var{k'})} meeting those
conditions, the additional conditions
\code{\var{k} >= \var{k'}},
\code{\var{i} <= \var{i'}},
and if \code{\var{i} == \var{i'}}, \code{\var{j} <= \var{j'}}
are also met.
In other words, of all maximal matching blocks, return one that
starts earliest in \var{a}, and of all those maximal matching blocks
that start earliest in \var{a}, return the one that starts earliest
in \var{b}.
\begin{verbatim}
>>> s = SequenceMatcher(None, " abcd", "abcd abcd")
>>> s.find_longest_match(0, 5, 0, 9)
(0, 4, 5)
\end{verbatim}
If \var{isjunk} was provided, first the longest matching block is
determined as above, but with the additional restriction that no
junk element appears in the block. Then that block is extended as
far as possible by matching (only) junk elements on both sides.
So the resulting block never matches on junk except as identical
junk happens to be adjacent to an interesting match.
Here's the same example as before, but considering blanks to be junk.
That prevents \code{' abcd'} from matching the \code{' abcd'} at the
tail end of the second sequence directly. Instead only the
\code{'abcd'} can match, and matches the leftmost \code{'abcd'} in
the second sequence:
\begin{verbatim}
>>> s = SequenceMatcher(lambda x: x==" ", " abcd", "abcd abcd")
>>> s.find_longest_match(0, 5, 0, 9)
(1, 0, 4)
\end{verbatim}
If no blocks match, this returns \code{(\var{alo}, \var{blo}, 0)}.
\end{methoddesc}
\begin{methoddesc}{get_matching_blocks}{}
Return list of triples describing matching subsequences.
Each triple is of the form \code{(\var{i}, \var{j}, \var{n})}, and
means that \code{\var{a}[\var{i}:\var{i}+\var{n}] ==
\var{b}[\var{j}:\var{j}+\var{n}]}. The triples are monotonically
increasing in \var{i} and \var{j}.
The last triple is a dummy, and has the value \code{(len(\var{a}),
len(\var{b}), 0)}. It is the only triple with \code{\var{n} == 0}.
% Explain why a dummy is used!
\begin{verbatim}
>>> s = SequenceMatcher(None, "abxcd", "abcd")
>>> s.get_matching_blocks()
[(0, 0, 2), (3, 2, 2), (5, 4, 0)]
\end{verbatim}
\end{methoddesc}
\begin{methoddesc}{get_opcodes}{}
Return list of 5-tuples describing how to turn \var{a} into \var{b}.
Each tuple is of the form \code{(\var{tag}, \var{i1}, \var{i2},
\var{j1}, \var{j2})}. The first tuple has \code{\var{i1} ==
\var{j1} == 0}, and remaining tuples have \var{i1} equal to the
\var{i2} from the preceeding tuple, and, likewise, \var{j1} equal to
the previous \var{j2}.
The \var{tag} values are strings, with these meanings:
\begin{tableii}{l|l}{code}{Value}{Meaning}
\lineii{'replace'}{\code{\var{a}[\var{i1}:\var{i2}]} should be
replaced by \code{\var{b}[\var{j1}:\var{j2}]}.}
\lineii{'delete'}{\code{\var{a}[\var{i1}:\var{i2}]} should be
deleted. Note that \code{\var{j1} == \var{j2}} in
this case.}
\lineii{'insert'}{\code{\var{b}[\var{j1}:\var{j2}]} should be
inserted at \code{\var{a}[\var{i1}:\var{i1}]}.
Note that \code{\var{i1} == \var{i2}} in this
case.}
\lineii{'equal'}{\code{\var{a}[\var{i1}:\var{i2}] ==
\var{b}[\var{j1}:\var{j2}]} (the sub-sequences are
equal).}
\end{tableii}
For example:
\begin{verbatim}
>>> a = "qabxcd"
>>> b = "abycdf"
>>> s = SequenceMatcher(None, a, b)
>>> for tag, i1, i2, j1, j2 in s.get_opcodes():
... print ("%7s a[%d:%d] (%s) b[%d:%d] (%s)" %
... (tag, i1, i2, a[i1:i2], j1, j2, b[j1:j2]))
delete a[0:1] (q) b[0:0] ()
equal a[1:3] (ab) b[0:2] (ab)
replace a[3:4] (x) b[2:3] (y)
equal a[4:6] (cd) b[3:5] (cd)
insert a[6:6] () b[5:6] (f)
\end{verbatim}
\end{methoddesc}
\begin{methoddesc}{ratio}{}
Return a measure of the sequences' similarity as a float in the
range [0, 1].
Where T is the total number of elements in both sequences, and M is
the number of matches, this is 2.0*M / T. Note that this is \code{1.}
if the sequences are identical, and \code{0.} if they have nothing in
common.
This is expensive to compute if \method{get_matching_blocks()} or
\method{get_opcodes()} hasn't already been called, in which case you
may want to try \method{quick_ratio()} or
\method{real_quick_ratio()} first to get an upper bound.
\end{methoddesc}
\begin{methoddesc}{quick_ratio}{}
Return an upper bound on \method{ratio()} relatively quickly.
This isn't defined beyond that it is an upper bound on
\method{ratio()}, and is faster to compute.
\end{methoddesc}
\begin{methoddesc}{real_quick_ratio}{}
Return an upper bound on \method{ratio()} very quickly.
This isn't defined beyond that it is an upper bound on
\method{ratio()}, and is faster to compute than either
\method{ratio()} or \method{quick_ratio()}.
\end{methoddesc}
The three methods that return the ratio of matching to total characters
can give different results due to differing levels of approximation,
although \method{quick_ratio()} and \method{real_quick_ratio()} are always
at least as large as \method{ratio()}:
\begin{verbatim}
>>> s = SequenceMatcher(None, "abcd", "bcde")
>>> s.ratio()
0.75
>>> s.quick_ratio()
0.75
>>> s.real_quick_ratio()
1.0
\end{verbatim}
\subsection{Examples \label{difflib-examples}}
This example compares two strings, considering blanks to be ``junk:''
\begin{verbatim}
>>> s = SequenceMatcher(lambda x: x == " ",
... "private Thread currentThread;",
... "private volatile Thread currentThread;")
\end{verbatim}
\method{ratio()} returns a float in [0, 1], measuring the similarity
of the sequences. As a rule of thumb, a \method{ratio()} value over
0.6 means the sequences are close matches:
\begin{verbatim}
>>> print round(s.ratio(), 3)
0.866
\end{verbatim}
If you're only interested in where the sequences match,
\method{get_matching_blocks()} is handy:
\begin{verbatim}
>>> for block in s.get_matching_blocks():
... print "a[%d] and b[%d] match for %d elements" % block
a[0] and b[0] match for 8 elements
a[8] and b[17] match for 6 elements
a[14] and b[23] match for 15 elements
a[29] and b[38] match for 0 elements
\end{verbatim}
Note that the last tuple returned by \method{get_matching_blocks()} is
always a dummy, \code{(len(\var{a}), len(\var{b}), 0)}, and this is
the only case in which the last tuple element (number of elements
matched) is \code{0}.
If you want to know how to change the first sequence into the second,
use \method{get_opcodes()}:
\begin{verbatim}
>>> for opcode in s.get_opcodes():
... print "%6s a[%d:%d] b[%d:%d]" % opcode
equal a[0:8] b[0:8]
insert a[8:8] b[8:17]
equal a[8:14] b[17:23]
equal a[14:29] b[23:38]
\end{verbatim}
See \file{Tools/scripts/ndiff.py} from the Python source distribution
for a fancy human-friendly file differencer, which uses
\class{SequenceMatcher} both to view files as sequences of lines, and
lines as sequences of characters.
See also the function \function{get_close_matches()} in this module,
which shows how simple code building on \class{SequenceMatcher} can be
used to do useful work.