### V` `Advanced Topics

### 28` `Algorithms That Exploit State

#### 28.1` `Disjoint Sets Redux

Here’s how we can use this to implement union-find afresh. We will try to keep things as similar to the previous version [Checking Component Connectedness] as possible, to enhance comparison.

`parent`

field be `mutable`

:
```
data Element:
| elt(val, ref parent :: Option<Element>)
end
```

`fynd`

. However, as we will soon see, `fynd`

no
longer needs to be given the entire set of elements. Because the only
reason `is-in-same-set`

consumed that set was to pass it on to
`fynd`

, we can remove it from here. Nothing else changes:
```
fun is-in-same-set(e1 :: Element, e2 :: Element) -> Boolean:
s1 = fynd(e1)
s2 = fynd(e2)
identical(s1, s2)
end
```

```
fun update-set-with(child :: Element, parent :: Element):
child!{parent: some(parent)}
end
```

`parent: some(parent)`

, the first `parent`

is the name of
the field, while the second one is the parameter name. In addition, we
must use `some`

to satisfy the option type. Naturally, it is not
`none`

because the entire point of this mutation is to change the
parent to be the other element, irrespective of what was there before.`union`

also stays largely unchanged,
other than the change to the return type. Previously, it needed to
return the updated set of elements; now, because the update is
performed by mutation, there is no longer any need to return anything:
```
fun union(e1 :: Element, e2 :: Element):
s1 = fynd(e1)
s2 = fynd(e2)
if identical(s1, s2):
s1
else:
update-set-with(s1, s2)
end
end
```

`fynd`

. Its implementation is now remarkably
simple. There is no longer any need to search through the
set. Previously, we had to search because after union operations have
occurred, the parent reference might have no longer been valid. Now,
any such changes are automatically reflected by mutation. Hence:
```
fun fynd(e :: Element) -> Element:
cases (Option) e!parent:
| none => e
| some(p) => fynd(p)
end
end
```

##### 28.1.1` `Optimizations

Look again at `fynd`

. In the `some`

case, the element bound
to `e`

is not the set name; that is obtained by recursively
traversing `parent`

references. As this value returns, however,
we don’t do anything to reflect this new knowledge! Instead, the next
time we try to find the parent of this element, we’re going to perform
this same recursive traversal all over again.

```
fun fynd(e :: Element) -> Element:
cases (Option) e!parent block:
| none => e
| some(p) =>
new-parent = fynd(p)
e!{parent: some(new-parent)}
new-parent
end
end
```

`fynd`

to
any of those elements the next time around will benefit from
this update. This idea is called path compression.There is one more interesting idea we can apply. This is to maintain a rank of each element, which is roughly the depth of the tree of elements for which that element is their set name. When we union two elements, we then make the one with larger rank the parent of the one with the smaller rank. This has the effect of avoiding growing very tall paths to set name elements, instead tending towards “bushy” trees. This too reduces the number of parents that must be traversed to find the representative.

##### 28.1.2` `Analysis

This optimized union-find data structure has a remarkble analysis. In
the worst case, of course, we must traverse the entire chain of
parents to find the name element, which takes time proportional to the
number of elements in the set. However, once we apply the above
optimizations, we never need to traverse that same chain again! In
particular, if we conduct an amortized analysis over a sequence
of set equality tests after a collection of union operations, we find
that the cost for subsequent checks is very small—

#### 28.2` `Set Membership by Hashing Redux

We have already seen solutions to set membership. First we saw how to
represent sets as lists [Representing Sets by Lists], then as
(balanced) binary trees [A Fine Balance: Tree Surgery].Don’t
confuse this with union-find, which is a different kind of problem on
sets [Disjoint Sets Redux]. With this we were able to reduce
insertion and membership to logarithmic time in the number of
elements. Along the way, we also learned that the essence of using
these representations was to reduce any datatype to a comparable,
ordered element—

Let us now ask whether we can use these numbers in any other way. Suppose our set has only five elements, which map densely to the values between 0 and 4. We can then have a five element list of boolean values, where the boolean at each index of the list indicates whether the element corresponding to that position is in the set or not. Both membership and insertion, however, require traversing potentially the entire list, giving us solutions linear in the number of elements.

That’s not all. Unless we can be certain that there will be only five elements, we can’t be sure to bound the size of the representation. Also, we haven’t yet shown how to actually hash in a way that makes the representation dense; barring that, our space consumption gets much worse, in turn affecting time.

There is, actually, a relatively simple solution to the problem of reducing numbers densely to a range: given the hash, we apply modular arithmetic. That is, if we want to use a list of five elements to represent the set, we simply compute the hash’s modulo five. This gives us an easy solution to that problem.

`[list: true, false, false, false, false]`

`true`

represents 5, 15, 25, or
any other value whose modulus 5 is 0. Therefore, we have
to record the actual elements in the set; for type-consistency, we
should be using an `Option`

:
`[list: some(5), none, none, none, none]`

`[list: [list: 5], empty, empty, empty, empty]`

`[list: [list: 5, 10], empty, empty, empty, empty]`

Good; now we have another way of representing sets so we can check for membership. However, in the worst case one of those lists is going to contain all elements in the set, and we may have to traverse the entire list to find an element in it, which means membership testing will take time linear in the number of elements. Insertion, in turn, takes time proportional to the size of the modulus because we may have to traverse the entire outer list to get to the right sub-list.

Can we improve on this?

##### 28.2.1` `Improving Access Time

Given that we currently have no way of ensuring we won’t get hash collisions, for now we’re stuck with a list of elements at each position that could be the size of the set we are trying to represent. Therefore, we can’t get around that (yet). But, we’re currently paying time in the size of the outer list just to insert an element, and surely we can do better than that!

Accessing the nth element of an array takes constant, not linear, time in n. This is sometimes known as random-access, because it takes the same time to access any random element, as opposed to just a known element.

Arrays are updated by mutation. Thus, a change to an array is seen by all references to the array.

```
SIZE = 19
v = array-of(empty, SIZE)
```

`fun find-bucket(n): num-modulo(n, SIZE) end`

```
fun get-bucket(n): array-get-now(v, find-bucket(n)) end
fun is-in(n): get-bucket(n).member(n) end
```

```
fun set-bucket(n, anew): array-set-now(v, find-bucket(n), anew) end
fun put(n):
when not(is-in(n)):
set-bucket(n, link(n, get-bucket(n)))
end
end
```

Exercise

What impact do duplicate elements have on the complexity of operations?

The data structure we have defined above is known as a hash table (which is a slightly confusing name, because it isn’t really a table of hashes, but this is the name used conventionally in computer science).

##### 28.2.2` `Better Hashing

Using arrays therefore appears to address one issue:
insertion. Finding the relevant bucket takes constant time, linking
the new element takes constant time, and so the entire operation takes
constant time...except, we have to also check whether the element is
already in the bucket, to avoid storing duplicates. We have gotten rid
of the traversal through the outer list representing the set, but the
`member`

operation on the inner list remains unchanged. In
principle it won’t, but in practice we can make it much better.

Note that collisions are virtually inevitable. If we have uniformly distributed data, then collisions show up sooner than we might expect.This follows from the reasoning behind what is known as the birthday problem, commonly presented as how many people need to be in a room before the likelihood that two of them share a birthday exceeds some percentage. For the likelihood to exceed half we need just 23 people! Therefore, it is wise to prepare for the possibility of collisions.

The key is to know something about the distribution of hash values. For instance, if we knew our hash values are all multiples of 10, then using a table size of 10 would be a terrible idea (because all elements would hash to the same bucket, turning our hash table into a list). In practice, it is common to use uncommon prime numbers as the table size, since a random value is unlikely to have it as a divisor. This does not yield a theoretical improvement (unless you can make certain assumptions about the input, or work through the math very carefully), but it works well in practice. In particular, since the typical hashing function uses memory addresses for objects on the heap, and on most systems these addresses are multiples of 4, using a prime like 31 is often a fairly good bet.

##### 28.2.3` `Bloom Filters

Another way to improve the space and time complexity is to relax the
properties we expect of the operations. Right now, set membership
gives perfect answers, in that it answers `true`

exactly when the
element being checked was previously inserted into the set. But
suppose we’re in a setting where we can accept a more relaxed notion
of correctness, where membership tests can “lie” slightly in one
direction or the other (but not both, because that makes the
representation almost useless). Specifically, let’s say that “no
means no” (i.e., if the set representation says the element isn’t
present, it really isn’t) but “yes sometimes means no” (i.e., if the
set representation says an element is present, sometimes it
might not be). In short, if the set says the element isn’t in it, this
should be guaranteed; but if the set says the element is present,
it may not be. In the latter case, we either need some
other—

Where is such a data structure of use? Suppose we are building a Web site that uses password-based authentication. Because many passwords have been leaked in well-publicized breaches, it is safe to assume that hackers have them and will guess them. As a result, we want to not allow users to select any of these as passwords. We could use a hash-table to reject precisely the known leaked passwords. But for efficiency, we could use this imperfect hash instead. If it says “no”, then we allow the user to use that password. But if it says “yes”, then either they are using a password that has been leaked, or they have an entirely different password that, purely by accident, has the same hash value, but no matter; we can just disallow that password as well.A related use is for filtering out malicious Web sites. The URL shortening system, bitly, uses it for this purpose.

Another example is in updating databases or memory stores. Suppose we have a database of records, which we update frequently. It is often more efficient to maintain a journal of changes: i.e., a list that sequentially records all the changes that have occurred. At some interval (say overnight), the journal is “flushed”, meaning all these changes are applied to the database proper. But that means every read operation has become highly inefficient, because it has to check the entire journal first (for updates) before accessing the database. Again, here we can use this faulty notion of a hash table: if the hash of the record locator says “no”, then the record certainly hasn’t been modified and we go directly to the database; if it says “yes” then we have to check the journal.

We have already seen a simple example implementation of this idea earlier, when we used a single list (or array) of booleans, with modular arithmetic, to represent the set. When the set said 4 was not present, this was absolutely true; but when it said 5 and 10 are both present, only one of these was present. The advantage was a huge saving in space and time: we needed only one bit per bucket, and did not need to search through a list to answer for membership. The downside, of course, was a hugely inaccurate set data structure, and one with correlated failure tied to the modulus.

There is a simple way to improve this solution: instead of having just one array, have several (but a fixed number of them). When an element is added to the set, it is added to each array; when checking for membership, every array is consulted. The set only answers affirmatively to membership if all the arrays do so.

Naturally, using multiple arrays offers absolutely no advantage if the arrays are all the same size: since both insertion and lookup are deterministic, all will yield the same answer. However, there is a simple antidote to this: use different array sizes. In particular, by using array sizes that are relatively prime to one another, we minimize the odds of a clash (only hashes that are the product of all the array sizes will fool the array).

This data structure, called a Bloom Filter, is a probabilistic data structure. Unlike our earlier set data structure, this one is not guaranteed to always give the right answer; but contrary to the ☛ space-time tradeoff, we save both space and time by changing the problem slightly to accept incorrect answers. If we know something about the distribution of hash values, and we have some acceptable bound of error, we can design hash table sizes so that with high probability, the Bloom Filter will lie within the acceptable error bounds.

#### 28.3` `Avoiding Recomputation by Remembering Answers

We have on several instances already referred to a ☛ space-time tradeoff. The most obvious tradeoff is when a computation “remembers” prior results and, instead of recomputing them, looks them up and returns the answers. This is an instance of the tradeoff because it uses space (to remember prior answers) in place of time (recomputing the answer). Let’s see how we can write such computations.

##### 28.3.1` `An Interesting Numeric Sequence

Suppose we want to create properly-parenthesized expressions, and ignore all non-parenthetical symbols. How many ways are there of creating parenthesized expressions given a certain number of opening (equivalently, closing) parentheses?

If we have zero opening parentheses, the only expression we can create is the empty expression. If we have one opening parenthesis, the only one we can construct is “()” (there must be a closing parenthesis since we’re interested only in properly-parenthesized expressions). If we have two opening parentheses, we can construct “(())” and “()()”. Given three, we can construct “((()))”, “(())()”, “()(())”, “()()()”, and “(()())”, for a total of five. And so on. Observe that the solutions at each level use all the possible solutions at one level lower, combined in all the possible ways.

```
fun catalan(n):
if n == 0: 1
else if n > 0:
for fold(acc from 0, k from range(0, n)):
acc + (catalan(k) * catalan(n - 1 - k))
end
end
end
```

```
check:
catalan(0) is 1
catalan(1) is 1
catalan(2) is 2
catalan(3) is 5
catalan(4) is 14
catalan(5) is 42
catalan(6) is 132
catalan(7) is 429
catalan(8) is 1430
catalan(9) is 4862
catalan(10) is 16796
catalan(11) is 58786
end
```

`10`

and `20`

—Do Now!

Check at what value you start to observe a significant slowdown on your machine. Plot the graph of running time against input size. What does this suggest?

The reason the Catalan computation takes so long is precisely because of what we alluded to earlier: at each level, we depend on computing the Catalan number of all the smaller levels; this computation in turn needs the numbers of all of its smaller levels; and so on down the road.

Exercise

Map the subcomputations of

`catalan`

to see why the computation time explodes as it does. What is the worst-case time complexity of this function?

##### 28.3.1.1` `Using State to Remember Past Answers

Therefore, this is clearly a case where trading space for time is likely to be of help. How do we do this? We need a notion of memory that records all previous answers and, on subsequent attempts to compute them, checks whether they are already known and, if so, just returns them instead of recomputing them.

Do Now!

What critical assumption is this based on?

Naturally, this assumes that for a given input, the answer will
always be the same. As we have seen, functions with state violate
this liberally, so typical stateful functions cannot utilize this
optimization. Ironically, we will use state to implement this
optimization, so we will have a stateful function that always returns
the same answer on a given input—

```
data MemoryCell:
| mem(in, out)
end
var memory :: List<MemoryCell> = empty
```

`catalan`

need to change? We have to first look for
whether the value is already in `memory`

; if it is, we return it
without any further computation, but if it isn’t, then we compute the
result, store it in `memory`

, and then return it:
```
fun catalan(n :: Number) -> Number:
answer = find(lam(elt): elt.in == n end, memory)
cases (Option) answer block:
| none =>
result =
if n == 0: 1
else if n > 0:
for fold(acc from 0, k from range(0, n)):
acc + (catalan(k) * catalan(n - 1 - k))
end
end
memory := link(mem(n, result), memory)
result
| some(v) => v.out
end
end
```

`catalan(50)`

.This process, of converting a function into a version that remembers its past answers, is called memoization.

##### 28.3.1.2` `From a Tree of Computation to a DAG

What we have subtly done is to convert a tree of computation into a
DAG over the same computation, with equivalent calls being
reused. Whereas previously each call was generating lots of recursive
calls, which induced still more recursive calls, now we are reusing
previous recursive calls—

This has an important complexity benefit. Whereas previously we were
performing a super-exponential number of calls, now we perform only
one call per input and share all previous calls—`catalan(n)`

to take a number of fresh calls proportional to
`n`

. Looking up the result of a previous call takes time
proportional to the size of `memory`

(because we’ve represented
it as a list; better representations would improve on that), but that
only contributes another linear multiplicative factor, reducing the
overall complexity to quadratic in the size of the input. This is a
dramatic reduction in overall complexity. In contrast, other uses of
memoization may result in much less dramatic improvements, turning the
use of this technique into a true engineering trade-off.

##### 28.3.1.3` `The Complexity of Numbers

As we start to run larger computations, however, we may start to
notice that our computations are starting to take longer than linear
growth. This is because our numbers are growing arbitrarily
large—`catalan(100)`

is
`896519947090131496687170070074100632420837521538745909320`

—

##### 28.3.1.4` `Abstracting Memoization

Now we’ve achieved the desired complexity improvement, but there is
still something unsatisfactory about the structure of our revised
definition of `catalan`

: the act of memoization is deeply
intertwined with the definition of a Catalan number, even though these
should be intellectually distinct. Let’s do that next.

In effect, we want to separate our program into two parts. One part
defines a general notion of memoization, while the other defines
`catalan`

in terms of this general notion.

```
data MemoryCell:
| mem(in, out)
end
fun memoize-1<T, U>(f :: (T -> U)) -> (T -> U):
var memory :: List<MemoryCell> = empty
lam(n):
answer = find(lam(elt): elt.in == n end, memory)
cases (Option) answer block:
| none =>
result = f(n)
memory := link(mem(n, result), memory)
result
| some(v) => v.out
end
end
end
```

`memoize-1`

to indicate that this is a
memoizer for single-argument functions. Observe that the code
above is virtually identical to what we had before, except where we
had the logic of Catalan number computation, we now have the parameter
`f`

determining what to do.`catalan`

as follows:
```
rec catalan :: (Number -> Number) =
memoize-1(
lam(n):
if n == 0: 1
else if n > 0:
for fold(acc from 0, k from range(0, n)):
acc + (catalan(k) * catalan(n - 1 - k))
end
end
end)
```

We don’t write

`fun catalan(...): ...;`

because the procedure bound to`catalan`

is produced by`memoize-1`

.Note carefully that the recursive calls to

`catalan`

have to be to the function bound to the result of memoization, thereby behaving like an object. Failing to refer to this same shared procedure means the recursive calls will not be memoized, thereby losing the benefit of this process.We need to use

`rec`

for reasons we saw earlier [Streams From Functions].Each invocation of

`memoize-1`

creates a new table of stored results. Therefore the memoization of different functions will each get their own tables rather than sharing tables, which is a bad idea!

Exercise

Why is sharing memoization tables a bad idea? Be concrete.

##### 28.3.2` `Edit-Distance for Spelling Correction

Text editors, word processors, mobile phones, and various other devices now routinely implement spelling correction or offer suggestions on (mis-)spellings. How do they do this? Doing so requires two capabilities: computing the distance between words, and finding words that are nearby according to this metric. In this section we will study the first of these questions. (For the purposes of this discussion, we will not dwell on the exact definition of what a “word” is, and just deal with strings instead. A real system would need to focus on this definition in considerable detail.)

Do Now!

Think about how you might define the “distance between two words”. Does it define a metric space?

Exercise

Will the definition we give below define a metric space over the set of words?

That the distance from a word to itself be zero.

That the distance from a word to any word other than itself be strictly positive. (Otherwise, given a word that is already in the dictionary, the “correction” might be a different dictionary word.)

That the distance between two words be symmetric, i.e., it shouldn’t matter in which order we pass arguments.

Exercise

Observe that we have not included the triangle inequality relative to the properties of a metric. Why not? If we don’t need the triangle inequality, does this let us define more interesting distance functions that are not metrics?

we left out a character;

we typed a character twice; or,

we typed one character when we meant another.

There are several variations of this definition possible. For now, we will consider the simplest one, which assumes that each of these errors has equal cost. For certain input devices, we may want to assign different costs to these mistakes; we might also assign different costs depending on what wrong character was typed (two characters adjacent on a keyboard are much more likely to be a legitimate error than two that are far apart). We will return briefly to some of these considerations later [Nature as a Fat-Fingered Typist].

```
check:
levenshtein(empty, empty) is 0
levenshtein([list:"x"], [list: "x"]) is 0
levenshtein([list: "x"], [list: "y"]) is 1
# one of about 600
levenshtein(
[list: "b", "r", "i", "t", "n", "e", "y"],
[list: "b", "r", "i", "t", "t", "a", "n", "y"])
is 3
# http://en.wikipedia.org/wiki/Levenshtein_distance
levenshtein(
[list: "k", "i", "t", "t", "e", "n"],
[list: "s", "i", "t", "t", "i", "n", "g"])
is 3
levenshtein(
[list: "k", "i", "t", "t", "e", "n"],
[list: "k", "i", "t", "t", "e", "n"])
is 0
# http://en.wikipedia.org/wiki/Levenshtein_distance
levenshtein(
[list: "S", "u", "n", "d", "a", "y"],
[list: "S", "a", "t", "u", "r", "d", "a", "y"])
is 3
# http://www.merriampark.com/ld.htm
levenshtein(
[list: "g", "u", "m", "b", "o"],
[list: "g", "a", "m", "b", "o", "l"])
is 2
# http://www.csse.monash.edu.au/~lloyd/tildeStrings/Alignment/92.IPL.html
levenshtein(
[list: "a", "c", "g", "t", "a", "c", "g", "t", "a", "c", "g", "t"],
[list: "a", "c", "a", "t", "a", "c", "t", "t", "g", "t", "a", "c", "t"])
is 4
levenshtein(
[list: "s", "u", "p", "e", "r", "c", "a", "l", "i",
"f", "r", "a", "g", "i", "l", "i", "s", "t" ],
[list: "s", "u", "p", "e", "r", "c", "a", "l", "y",
"f", "r", "a", "g", "i", "l", "e", "s", "t" ])
is 2
end
```

```
rec levenshtein :: (List<String>, List<String> -> Number) =
<levenshtein-body>
```

`if is-empty(s) and is-empty(t): 0`

```
else if is-empty(s): t.length()
else if is-empty(t): s.length()
```

```
else:
if s.first == t.first:
levenshtein(s.rest, t.rest)
else:
min3(
1 + levenshtein(s.rest, t),
1 + levenshtein(s, t.rest),
1 + levenshtein(s.rest, t.rest))
end
end
```

`s`

has one too many characters, so
we compute the cost as if we’re deleting it and finding the lowest
cost for the rest of the strings (but charging one for this deletion);
in the second case, we symmetrically assume `t`

has one too many;
and in the third case, we assume one character got replaced by
another, so we charge one but consider the rest of both words (e.g.,
assume “s” was typed for “k” and continue with “itten” and
“itting”). This uses the following helper function:
```
fun min3(a :: Number, b :: Number, c :: Number):
num-min(a, num-min(b, c))
end
```

This algorithm will indeed pass all the tests we have written above, but with a problem: the running time grows exponentially. That is because, each time we find a mismatch, we recur on three subproblems. In principle, therefore, the algorithm takes time proportional to three to the power of the length of the shorter word. In practice, any prefix that matches causes no branching, so it is mismatches that incur branching (thus, confirming that the distance of a word with itself is zero only takes time linear in the size of the word).

Observe, however, that many of these subproblems are the same. For instance, given “kitten” and “sitting”, the mismatch on the initial character will cause the algorithm to compute the distance of “itten” from “itting” but also “itten” from “sitting” and “kitten” from “itting”. Those latter two distance computations will also involve matching “itten” against “itting”. Thus, again, we want the computation tree to turn into a DAG of expressions that are actually evaluated.

```
data MemoryCell2<T, U, V>:
| mem(in-1 :: T, in-2 :: U, out :: V)
end
fun memoize-2<T, U, V>(f :: (T, U -> V)) -> (T, U -> V):
var memory :: List<MemoryCell2<T, U, V>> = empty
lam(p, q):
answer = find(
lam(elt): (elt.in-1 == p) and (elt.in-2 == q) end,
memory)
cases (Option) answer block:
| none =>
result = f(p, q)
memory :=
link(mem(p, q, result), memory)
result
| some(v) => v.out
end
end
end
```

`levenshtein`

to use memoization:
```
rec levenshtein :: (List<String>, List<String> -> Number) =
memoize-2(
lam(s, t):
if is-empty(s) and is-empty(t): 0
else if is-empty(s): t.length()
else if is-empty(t): s.length()
else:
if s.first == t.first:
levenshtein(s.rest, t.rest)
else:
min3(
1 + levenshtein(s.rest, t),
1 + levenshtein(s, t.rest),
1 + levenshtein(s.rest, t.rest))
end
end
end)
```

`memoize-2`

is precisely what we saw
earlier as <levenshtein-body> (and now you know why we
defined `levenshtein`

slightly oddly, not using `fun`

).The complexity of this algorithm is still non-trivial. First, let’s introduce the term suffix: the suffix of a string is the rest of the string starting from any point in the string. (Thus “kitten”, “itten”, “ten”, “n”, and “” are all suffixes of “kitten”.) Now, observe that in the worst case, starting with every suffix in the first word, we may need to perform a comparison against every suffix in the second word. Fortunately, for each of these suffixes we perform a constant computation relative to the recursion. Therefore, the overall time complexity of computing the distance between strings of length \(m\) and \(n\) is \(O([m, n \rightarrow m \cdot n])\). (We will return to space consumption later [Contrasting Memoization and Dynamic Programming].)

Exercise

Modify the above algorithm to produce an actual (optimal) sequence of edit operations. This is sometimes known as the traceback.

##### 28.3.3` `Nature as a Fat-Fingered Typist

We have talked about how to address mistakes made by humans. However, humans are not the only bad typists: nature is one, too!

When studying living matter we obtain sequences of amino acids and
other such chemicals that comprise molecules, such as DNA, that hold
important and potentially determinative information about the
organism. These sequences consist of similar fragments that we wish to
identify because they represent relationships in
the organism’s behavior or evolution.This section may
need to be skipped in
some states and countries.
Unfortunately, these sequences are never identical: like all
low-level programmers, nature slips up and sometimes makes mistakes in
copying (called—

The only difference between traditional presentations of Levenshtein and Smith-Waterman is something we alluded to earlier: why is every edit given a distance of one? Instead, in the Smith-Waterman presentation, we assume that we have a function that gives us the gap score, i.e., the value to assign every character’s alignment, i.e., scores for both matches and edits, with scores driven by biological considerations. Of course, as we have already noted, this need is not peculiar to biology; we could just as well use a “gap score” to reflect the likelihood of a substitution based on keyboard characteristics.

##### 28.3.4` `Dynamic Programming

We have used memoization as our canonical means of saving the values of past computations to reuse later. There is another popular technique for doing this called dynamic programming. This technique is closely related to memoization; indeed, it can be viewed as the dual method for achieving the same end. First we will see dynamic programming at work, then discuss how it differs from memoization.

Dynamic programming also proceeds by building up a memory of answers, and looking them up instead of recomputing them. As such, it too is a process for turning a computation’s shape from a tree to a DAG of actual calls. The key difference is that instead of starting with the largest computation and recurring to smaller ones, it starts with the smallest computations and builds outward to larger ones.

We will revisit our previous examples in light of this approach.

##### 28.3.4.1` `Catalan Numbers with Dynamic Programming

```
MAX-CAT = 11
answers :: Array<Option<Number>> = array-of(none, MAX-CAT + 1)
```

`catalan`

function simply looks up the answer in this
array:
```
fun catalan(n):
cases (Option) array-get-now(answers, n):
| none => raise("looking at uninitialized value")
| some(v) => v
end
end
```

```
fun fill-catalan(upper):
array-set-now(answers, 0, some(1))
when upper > 0:
for map(n from range(1, upper + 1)):
block:
cat-at-n =
for fold(acc from 0, k from range(0, n)):
acc + (catalan(k) * catalan(n - 1 - k))
end
array-set-now(answers, n, some(cat-at-n))
end
end
end
end
fill-catalan(MAX-CAT)
```

Notice that we have had to undo the natural recursive
definition—`catalan`

to some value, that index of `answers`

will have
not yet been initialized, resultingin an error. In fact, however, we
know that because we fill all smaller indices in `answers`

before
computing the next larger one, we will never actually encounter this
error. Note that this requires careful reasoning about our program,
which we did not need to perform when using memoization because
there we made precisely the recursive call we needed, which either
looked up the value or computed it afresh.

##### 28.3.4.2` `Levenshtein Distance and Dynamic Programming

```
fun levenshtein(s1 :: List<String>, s2 :: List<String>):
<levenshtein-dp/1>
end
```

`s1`

and as many columns as the length of
`s2`

. At each position, we will record the edit distance for the
prefixes of `s1`

and `s2`

up to the indices represented by
that position in the table.```
s1-len = s1.length()
s2-len = s2.length()
answers = array2d(s1-len + 1, s2-len + 1, none)
<levenshtein-dp/2>
```

`answers`

inside `levenshtein`

, we
can determine the exact size it needs to be based on the inputs,
rather than having to over-allocate or dynamically grow the array.`none`

, so we will get an
error if we accidentally try to use an uninitialized
entry.Which proved to be necessary when
writing and debugging this code! It will
therefore be convenient to create helper functions that let us
pretend the table contains only numbers:
```
fun put(s1-idx :: Number, s2-idx :: Number, n :: Number):
answers.set(s1-idx, s2-idx, some(n))
end
fun lookup(s1-idx :: Number, s2-idx :: Number) -> Number:
a = answers.get(s1-idx, s2-idx)
cases (Option) a:
| none => raise("looking at uninitialized value")
| some(v) => v
end
end
```

`s2`

is empty, and the
column where `s1`

is empty. At \((0, 0)\), the edit distance is
zero; at every position thereafter, it is the distance of that
position from zero, because that many characters must be added to one
or deleted from the other word for the two to coincide:
```
for each(s1i from range(0, s1-len + 1)):
put(s1i, 0, s1i)
end
for each(s2i from range(0, s2-len + 1)):
put(0, s2i, s2i)
end
<levenshtein-dp/4>
```

`0`

to `s1-len - 1`

and `s2-len - 1`

, which are
precisely the ranges of values produced by `range(0, s1-len)`

and
`range(0, s2-len)`

.
```
for each(s1i from range(0, s1-len)):
for each(s2i from range(0, s2-len)):
<levenshtein-dp/compute-dist>
end
end
<levenshtein-dp/get-result>
```

Do Now!

Is this strictly true?

No, it isn’t. We did first fill in values for the “borders” of the table. This is because doing so in the midst of <levenshtein-dp/compute-dist> would be much more annoying. By initializing all the known values, we keep the core computation cleaner. But it does mean the order in which we fill in the table is fairly complex.

```
dist =
if index(s1, s1i) == index(s2, s2i):
lookup(s1i, s2i)
else:
min3(
1 + lookup(s1i, s2i + 1),
1 + lookup(s1i + 1, s2i),
1 + lookup(s1i, s2i))
end
put(s1i + 1, s2i + 1, dist)
```

`-1`

so that the main computation looks
traditional.`lookup(s1-len, s2-len)`

```
fun levenshtein(s1 :: List<String>, s2 :: List<String>):
s1-len = s1.length()
s2-len = s2.length()
answers = array2d(s1-len + 1, s2-len + 1, none)
for each(s1i from range(0, s1-len + 1)):
put(s1i, 0, s1i)
end
for each(s2i from range(0, s2-len + 1)):
put(0, s2i, s2i)
end
for each(s1i from range(0, s1-len)):
for each(s2i from range(0, s2-len)):
dist =
if index(s1, s1i) == index(s2, s2i):
lookup(s1i, s2i)
else:
min3(
1 + lookup(s1i, s2i + 1),
1 + lookup(s1i + 1, s2i),
1 + lookup(s1i, s2i))
end
put(s1i + 1, s2i + 1, dist)
end
end
lookup(s1-len, s2-len)
end
```

##### 28.3.5` `Contrasting Memoization and Dynamic Programming

Now that we’ve seen two very different techniques for avoiding recomputation, it’s worth contrasting them. The important thing to note is that memoization is a much simpler technique: write the natural recursive definition; determine its space complexity; decide whether this is problematic enough to warrant a space-time trade-off; and if it is, apply memoization. The code remains clean, and subsequent readers and maintainers will be grateful for that. In contrast, dynamic programming requires a reorganization of the algorithm to work bottom-up, which can often make the code harder to follow and full of subtle invariants about boundary conditions and computation order.

That said, the dynamic programming solution can sometimes be more computationally efficient. For instance, in the Levenshtein case, observe that at each table element, we (at most) only ever use the ones that are from the previous row and column. That means we never need to store the entire table; we can retain just the fringe of the table, which reduces space to being proportional to the sum, rather than product, of the length of the words. In a computational biology setting (when using Smith-Waterman), for instance, this saving can be substantial. This optimization is essentially impossible for memoization.

Memoization |
| Dynamic Programming |

Top-down |
| Bottom-up |

Depth-first |
| Breadth-first |

Black-box |
| Requires code reorganization |

All stored calls are necessary |
| May do unnecessary computation |

Cannot easily get rid of unnecessary data |
| Can more easily get rid of unnecessary data |

Can never accidentally use an uninitialized answer |
| Can accidentally use an uninitialized answer |

Needs to check for the presence of an answer |
| Can be designed to not need to check for the presence of an answer |

From a software design perspective, there are two more considerations.

First, the performance of a memoized solution can trail that of dynamic programming when the memoized solution uses a generic data structure to store the memo table, whereas a dynamic programming solution will invariably use a custom data structure (since the code needs to be rewritten against it anyway). Therefore, before switching to dynamic programming for performance reasons, it makes sense to try to create a custom memoizer for the problem: the same knowledge embodied in the dynamic programming version can often be encoded in this custom memoizer (e.g., using an array instead of list to improve access times). This way, the program can enjoy speed comparable to that of dynamic programming while retaining readability and maintainability.

Second, suppose space is an important consideration and the dynamic programming version can make use of significantly less space. Then it does make sense to employ dynamic programming instead. Does this mean the memoized version is useless?

Do Now!

What do you think? Do we still have use for the memoized version?

Yes, of course we do! It can serve as an oracle [Oracles for Testing] for the dynamic
programming version, since the two are supposed to produce identical
answers anyway—

In short, always first produce the memoized version. If you need more performance, consider customizing the memoizer’s data structure. If you need to also save space, and can arrive at a more space-efficient dynamic programming solution, then keep both versions around, using the former to test the latter (the person who inherits your code and needs to alter it will thank you!).

Exercise

We have characterized the fundamental difference between memoization and dynamic programming as that between top-down, depth-first and bottom-up, breadth-first computation. This should naturally raise the question, what about:

top-down, breadth-first

bottom-up, depth-first

orders of computation. Do they also have special names that we just happen to not know? Are they uninteresting? Or do they not get discussed for a reason?