+The Church numerals are well behaved with respect to types.
+To see this, consider the first three Church numerals (starting with zero):
+
+ \s z . z
+ \s z . s z
+ \s z . s (s z)
+
+Given the internal structure of the term we are using to represent
+zero, its type must have the form ρ -> σ -> σ for
+some ρ and σ. This type is consistent with term for one,
+but the structure of the definition of one is more restrictive:
+because the first argument (`s`) must apply to the second argument
+(`z`), the type of the first argument must describe a function from
+expressions of type σ to some result type. So we can refine
+ρ by replacing it with the more specific type σ -> τ.
+At this point, the overall type is (σ -> τ) -> σ ->
+σ. Note that this refined type remains compatible with the
+definition of zero. Finally, by examinining the definition of two, we
+see that expressions of type τ must be suitable to serve as
+arguments to functions of type σ -> τ, since the result of
+applying `s` to `z` serves as the argument of `s`. The most general
+way for that to be true is if τ ≡ σ. So at this
+point, we have the overall type of (σ -> σ) -> σ
+-> σ.
+
+<!-- Make sure there is talk about unification and computation of the
+principle type-->
+
+## Predecessor and lists are not representable in simply typed lambda-calculus ##
+
+
+This is not because there is any difficulty typing what the functions
+involved do "from the outside": for instance, the predecessor function
+is a function from numbers to numbers, or τ -> τ, where τ
+is our type for Church numbers (i.e., (σ -> σ) -> σ
+-> σ). (Though this type will only be correct if we decide that
+the predecessor of zero should be a number, perhaps zero.)
+
+Rather, the problem is that the definition of the function requires
+subterms that can't be simply-typed. We'll illustrate with our
+implementation of the predecessor function, based on the discussion in
+Pierce 2002:547:
+
+ let zero = \s z. z in
+ let fst = \x y. x in
+ let snd = \x y. y in
+ let pair = \x y . \f . f x y in
+ let succ = \n s z. s (n s z) in
+ let shift = \p. pair (succ (p fst)) (p fst) in
+ let pred = \n. n shift (pair zero zero) snd in
+
+Note that `shift` takes a pair `p` as argument, but makes use of only
+the first element of the pair. Why does it do that? In order to
+understand what this code is doing, it is helpful to go through a
+sample computation, the predecessor of 3:
+
+ pred 3
+ 3 shift (pair zero zero) snd
+ (\s z.s(s(s z))) shift (pair zero zero) snd
+ shift (shift (shift (\f.f 0 0))) snd
+ shift (shift (pair (succ ((\f.f 0 0) fst)) ((\f.f 0 0) fst))) snd
+ shift (shift (\f.f 1 0)) snd
+ shift (\f. f 2 1) snd
+ (\f. f 3 2) snd
+ snd 3 2
+ 2
+
+At each stage, `shift` sees an ordered pair that contains two numbers
+related by the successor function. It can safely discard the second
+element without losing any information. The reason we carry around
+the second element at all is that when it comes time to complete the
+computation---that is, when we finally apply the top-level ordered
+pair to `snd`---it's the second element of the pair that will serve as
+the final result.
+
+Let's see how far we can get typing these terms. `zero` is the Church
+encoding of zero. Using `N` as the type for Church numbers (i.e.,
+<code>N ≡ (σ -> σ) -> σ -> σ</code> for
+some σ, `zero` has type `N`. `snd` takes two numbers, and
+returns the second, so `snd` has type `N -> N -> N`. Then the type of
+`pair` is `N -> N -> (type(snd)) -> N`, that is, `N -> N -> (N -> N ->
+N) -> N`. Likewise, `succ` has type `N -> N`, and `shift` has type
+`pair -> pair`, where `pair` is the type of an ordered pair of
+numbers, namely, <code>pair ≡ (N -> N -> N) -> N</code>. So far
+so good.
+
+The problem is the way in which `pred` puts these parts together. In
+particular, `pred` applies its argument, the number `n`, to the
+`shift` function. Since `n` is a number, its type is <code>(σ
+-> σ) -> σ -> σ</code>. This means that the type of
+`shift` has to match <code>σ -> σ</code>. But we
+concluded above that the type of `shift` also had to be `pair ->
+pair`. Putting these constraints together, it appears that
+<code>σ</code> must be the type of a pair of numbers. But we
+already decided that the type of a pair of numbers is `(N -> N -> N)
+-> N`. Here's the difficulty: `N` is shorthand for a type involving
+<code>σ</code>. If <code>σ</code> turns out to depend on
+`N`, and `N` depends in turn on <code>σ</code>, then
+<code>σ</code> is a proper subtype of itself, which is not
+allowed in the simply-typed lambda calculus.
+
+The way we got here is that the `pred` function relies on the built-in
+right-fold structure of the Church numbers to recursively walk down
+the spine of its argument. In order to do that, the argument had to
+apply to the `shift` operation. And since `shift` had to be the
+sort of operation that manipulates numbers, the infinite regress is
+established.
+
+Now, of course, this is only one of myriad possible implementations of
+the predecessor function in the lambda calculus. Could one of them
+possibly be simply-typeable? It turns out that this can't be done.
+See Oleg Kiselyov's discussion and works cited there for details:
+[[predecessor and lists can't be represented in the simply-typed
+lambda
+calculus|http://okmij.org/ftp/Computation/lambda-calc.html#predecessor]].
+
+Because lists are (in effect) a generalization of the Church numbers,
+computing the tail of a list is likewise beyond the reach of the
+simply-typed lambda calculus.
+
+This result is not obvious, to say the least. It illustrates how
+recursion is built into the structure of the Church numbers (and
+lists). Most importantly for the discussion of the simply-typed
+lambda calculus, it demonstrates that even fairly basic recursive
+computations are beyond the reach of a simply-typed system.
+
+
+## Montague grammar is based on a simply-typed lambda calculus
+
+Systems based on the simply-typed lambda calculus are the bread and
+butter of current linguistic semantic analysis. One of the most
+influential modern semantic formalisms---Montague's PTQ
+fragment---included a simply-typed version of the Predicate Calculus
+with lambda abstraction.
+
+Montague called the semantic part of his PTQ fragment *Intensional
+Logic*. Without getting too fussy about details, we'll present the
+popular Ty2 version of the PTQ types, roughly as proposed by Gallin
+(1975). [See Zimmermann, Ede. 1989. Intensional logic and two-sorted
+type theory. *Journal of Symbolic Logic* ***54.1***: 65--77 for a
+precise characterization of the correspondence between IL and
+two-sorted Ty2.]
+
+We'll need three base types: `e`, for individuals, `t`, for truth
+values, and `s` for evaluation indicies (world-time pairs). The set
+of types is defined recursively:
+
+ the base types e, t, and s are types
+ if a and b are types, <a,b> is a type
+
+So `<e,<e,t>>` and `<s,<<s,e>,t>>` are types. As we have mentioned,
+Montague's paper is the source for the convention in linguistics that
+a type of the form `<a, b>` corresponds to a functional type that we
+will write here as `a -> b`. So the type `<a, b>` is the type of a
+function that maps objects of type `a` onto objects of type `b`.
+
+Montague gave rules for the types of various logical formulas. Of
+particular interest here, he gave the following typing rules for
+functional application and for lambda abstracts, which match the rules
+for the simply-typed lambda calculus exactly:
+
+* If *α* is an expression of type *<a, b>*, and *β* is an
+expression of type b, then *α(β)* has type *b*.
+
+* If *α* is an expression of type *a*, and *u* is a variable of type *b*, then *λuα* has type <code><b, a></code>.
+
+When we talk about monads, we will consider Montague's treatment of
+intensionality in some detail. In the meantime, Montague's PTQ is
+responsible for making the simply-typed lambda calculus the baseline
+semantic analysis for linguistics.