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Programming Language Theory

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The Church-Turing Thesis equates a vaguely-defined set of "computable" functions with the partial recursive functions. Several systems have been proven equivalent to the partial recursives in power, such as Turing machines and the λ-calculus (practical programming languages generally provide further syntaxes and semantics, but a Real Programmer is perfectly happy with combinatory logic and a beer). Peter J. Landin's 1965 ACM report, "A correspondence between ALGOL 60 and Church's Lambda-notation", is blamed by most textbooks for jump-starting the study of programming language theory, ensuring computer scientists forty years later would still be exploring "topoi", "sheaves" and "fixed-point combinators".

There may, indeed, be other applications of the system than its use as a logic. -- Alonzo Church, 1932

Functions and Declarative Programming

Expressions in functional programs compose functions (as opposed to "values"). Backus proposed three tiers of complexity in his Turing Award lecture:

  • Simply functional language (fp): No state, limited names, finitely many functional forms, simple substitution semantics, algebraic laws
  • Formal functional system (ffp): Extensible functional forms, functions represented by objects, translation of object representation to applicable form, formal semantics
  • Applicative state transition system (ast): ffp plus mutable state and coarse-grained operations thereupon

Higher-order functions map one or more functions to a function. First-order support of functions provides composition of functions at runtime.

Combinatory Logic

Built from only variables, a set of primitive combinators (closed λ-expressions with their own reduction rules), and function application, combinatory logic provides no abstraction mechanism. A Turing-complete kernel of primitive combinators is complete. The SKI calculus requires only the K and S combinators; Chris Barker's Iota and Jot require only one each.

SKI Calculus

  • I ≡ λx. x (identity)
  • K ≡ λx, y. x (generation of constant functions)
  • S ≡ λx, y, z. (x z (y z)) (generalized function application)

Grammar

C-term ::= C-app | C-prim | var
C-app ::= C-term C-term

Divergent Combinators

The omega combinator is divergent. It can be reduced, but has no normal form:

  • omega ≡ (λx. x x) (λx. x x)

A combinator which is in normal form, but not reduced to a value, is said to be stuck. One of the major objective of static typing systems is to detect possible "stuck" reductions.

Fixed-Point Combinators

For a function F, its set of fixed points are those inputs which map to themselves. Provided algebraic functions, for instance, fixed points of a function F(x) would be found by setting F(x) = x and solving for the roots. Provided an ordered, finite domain, looping through the domain will find all solutions. For an infinite ordered domain, looping is a semi-decision: if there is a least fixed point, it will be found, but the loop never terminates otherwise. The fixed-point combinators compute fixed points of their functional inputs. Curry's Y-combinator was the first (it always computes the least fixed point):

  • Y ≡ λf. (λx. f (x x)) (λx. f (x x)) (untyped λ-calculus)
  • Y ≡ S (K (S I I)) (S (S (K S) K) (K (S I I))) (SKI calculus)

Divergence-free evaluation of the Y-combinator requires call-by-name semantics. Call-by-value semantics can make use of the Θv (Turing) or Z-combinators:

  • Θv ≡ (λx. λy. (y (λz. x x y z))) (λx. λy. (y (λz. x x y z)))
  • Z ≡ λf. (λx. f (λy. x x y)) (λx. f (λy. x x y)) (via η-expansion on Y)

The infinitely many fixed-point combinators of untyped λ-calculus are recursively enumerable.

Untyped λ-calculus

Two operators (function definition and application) upon one operand type (λ-expression).

  • Function definition: boundparam. body)
  • Function application: function(actualparam)

The body is made up of free and bound variables. Those not present in the λ's list of bound variables are free. A λ-expression with no free variables is closed (closed expressions are equivalent in power to combinatory logic). A λ-expression enclosed in scopes of its free variables is meaningful. Distinct free variables specify a λ-expression's distinct substitution classes.

Grammar

λ-term ::= λ-app | λ-abst | var
λ-app ::= λ-term λ-term
λ-abst ::= 'λ'var'.' λ-term

This abstract grammar can be augmented with associativity rules and grouping syntax (parentheses) to provide a concrete grammar. If verbosity is no issue, no associativity rules need be specified for the following grammar:

λ-term ::= λ-app | λ-abst | var
λ-app ::= '(' λ-term λ-term ')'
λ-abst ::= '(' 'λ'var'.' λ-term ')'

Evaluation via Substitution

We'll use a substitution syntax to rewrite λ-calculus strings. Heavyweight de Bruijn indexing is one substitution semantic, as is the Barendregt convention. The following simple semantic is due Rugaber, possibly through Pierce: {N / X}M substitutes expression N for free instances of X in expression M:

  • If M is a variable ({N / X}V), replace M with X if and only if M is N.
  • If M is a λ-app ({N / X}(A B)), {N / X}M = (({N / X}A) ({N / X}B))
  • Otherwise, M is a λ-abst ({N / X}(λV. B)).
    • If X is V, M is unchanged (X is bound in M).
    • If X does not appear in B, M is unchanged (no free X in M)
    • If V occurs free in N, substitute N for X throughout B.
    • Otherwise, the substitution in this form is invalid (but it can be made valid...)

With this syntax, we define evaluation rules. Application of the a rule preserves its equivalence.:

  • ɑ-conversion renames bound variables with any variable y which is not free, preserving ɑ-equivalence:
    • λx. m →ɑ λy. {y / x}m
  • β-reduction replaces a formal parameter with an actual parameter, preserving β-equivalence:
    • (λx. m) n →β {n / x}m
    • An expression is in β-normal form if no β-reductions are possible. It is otherwise a β-redex.
  • η-reduction eliminates bindings unused within a scope, preserving η-equivalence:
    • (λx. (f x)) →η f
    • An expression is in β-η-normal form ("Beta-eta-normal form") if neither β- nor η-reductions are possible
      • If a η-reduction is applicable, the expression is a η-redex.

According to the Church-Rosser Theorem, all terminating evaluations will compute the same function. Certain application orders might not terminate for a given expression, though, despite termination via other orders (proofs under arbitrary reduction ordering are said to operate under full beta reduction). This gives rise to the core difference between call-by-value and call-by-name semantics:

  • leftmost-innermost application evaluates arguments as soon as possible, and is equivalent to leftmost call-by-value ("applicative order")
    • only the outermost redexes are reduced, and the right hand side must be in β-η-normal form before reducing the left
    • this is strict evaluation (arguments are always evaluated, whether used or not)
  • leftmost-outermost application substitutes prior to evaluation, and is equivalent to lazy call-by-name sans memoization ("normal order")

Call-by-name terminates if any order does, but might require more total reductions. Call-by-value only β-reduces abstractions, not applications. Call-by-need memoizes the results of evaluated functions, and is operationally equivalent to call-by-name if side-effects are disallowed (it can be more efficient, but also more complicated: reduction is performed on abstract syntax graphs rather than abstract syntax trees). Call-by-name is text substitution augmented by capture avoidance. Wikipedia's evaluation strategy page is pretty thorough.

Numerics

The integers (or any countably infinite set) can be represented via the Church encoding (or Mogensen-Scott, or others):

  • 0 ≡ λf. λx. x (referred to as c0, and ɑ-equivalent to false as defined below)
  • 1 ≡ λf. λx. f x
  • 2 ≡ λf. λx. f (f x)
  • 3 ≡ λf. λx. f (f (f x))
  • n ≡ λf. λx. fnx (...up thorugh cn)

Some basic arithmetic operations:

  • plus ≡ λm. λn. λf. λx. m f (n f x) (from f(m + n)(x) = fm(fn(x)))
  • succ ≡ λn. λf. λx. f (n f x) (β-equivalent to (plus 1) for our 1 from above)
  • mult ≡ λm. λn. λf. n (m f) (from f(m * n)(x) = (fm(x))n)
    • alternatively, mult ≡ λm. λn. m (plus n) c0
  • pow ≡ λm. λn. n m
  • pred ≡ λn. λf. λx. n (λg. λh. h (g f)) (λu. x) (λu. u) (returns 0 when applied to 0)
  • sub ≡ λm. λn. (n pred) m (using pred from above)

Pairs

  • pair ≡ λf. λs. λb. b f s
  • first ≡ λp. p true
  • second ≡ λp. p false

Logic

The Church booleans evaluate to one of their two arguments:

  • true ≡ λa. λb. a
  • false ≡ λa. λb. b (note that false is ɑ-equivalent to c0!)

Using them, we implement basic conditional logic:

  • test ≡ λa. λb. λc. a b c (using true/false for a, test reduces to b on true, and c on false)
  • not ≡ λt. t false true (β-equivalent to test(A, false, true))
  • iszro ≡ λm. m (λx. false) true

This definition of test will evaluate both arguments in a strict application, which is undesirable. Instead, define if as a function taking one argument (true/false), which evaluates to either the function first or second.

Syntactic sugar

  • Left-associative application as implicit parentheses
  • Use of definitions (allowing identifiers to stand in as λ-expressions)
  • Currying: (λx, y. x + y) rather than (λx. (λy. x + y))
  • Numeric literals rather than Church encoding
  • Function definition: binding a functional abstraction to an identifier
  • Pattern matching (piecewise function definition based on argument structure)
  • The de Bruijn notation (not to be confused with de Bruijn indexing as a substitution scheme) is another, probably superior, syntax. It has an abstractor wagon, which I whole-heartedly approve of.

Typed Functional Programming

Two mechanisms were proposed for adding types to the λ-calculus:

  • Church suggested explicit type annotations on all terms (simply-typed λ-calculus (λ), "simple" due to single type constructor →)
  • Curry suggested inferred types (now implemented via techniques such as Hindley-Milner)

Either way, we lose some properties of the untyped λ-calculus (there's no type for the Y-combinator, for instance!). Nonetheless, the benefits of typing (especially in the presence of type inference) lead to most functional programming languages making use of a strict typing system.

Logic Programming

FIXME unification, backtracking, cuts

Constraint Programming

FIXME

Nondeterminism

FIXME impossible in purely declarative programming!

Typing

Weak- vs strong-typing refers to the degree to which the language's typing system can be subverted, and whether this is regularly necessary. Static- vs dynamic-typing refers to (among other possible definitions) whether type is determined at compile-time or run-time (among dynamic typing, duck typing types based on (dynamically-bound) method availability). The benefits of static typing include:

  • Detection of many types of errors at compile-time
    • "Safety = Progress + Preservation" (Harper 1994) suggests well-typed expressions ought not get stuck, and that reductions of well-typed expressions are themselves well-typed.
  • Improved performance, reduced resource requirements
  • Secure data abstractions can be built atop the safety of strong typing systems

Properties of a typing system include:

  • Support for polymorphism (dispatch based on types of actual arguments)
    • Parametric polymorphism: Generation of a version for necessary types (Ada generics, C++ templates, SML type parameters)

Objects

FIXME object calculus, polymorphism...

Concurrency

FIXME π-calculus, CSS, CSP, petri nets, dataflow variables... FIXME message-passing, shared-state

Programming Language Design

Syntax

Pierce describes three means for describing language syntax, using terms to refer to language definitions involving at least one terminal:

  • Induction on successive terms (of which EBNF is a compact notation)
  • Inference from axioms (terminals) and successive inference terms
  • Concrete definition (generative grammar) placing successive sets of alternate terms in bijection with the ordinals

Semantics

Pierce describes three techniques of formalizing semantics:

  • Operational semantics define one or more formal abstract machines, and attempt to exhaustively describe the language constructs in these machines' terms. Emphasis is on proof of various abstract machines' equivalence (and correspondence to actual implementations), and thus proof of an implementation's correctness. When finite state machines are used (this is only possible for simple languages), this is Plotkin's small-step or structural operational semantics; more powerful languages might make use of Kahn's big-step or natural semantics.
  • Denotational semantics map between different semantic domains (the investigation of which constitutes domain theory) using interpretation functions. Domains are interesting if results have been proven for their properties, such as termination and safety results. Denotational semantics can thus lead to proof schemas for a language, but meaningful interpretation functions seem to largely require domain-driven language design.
  • While operational and denotational semantics define the behaviors of programs, and then prove laws about them, axiomatic semantics define the behavior of the language in terms of these laws themselves. As Pierce says: "The meaning of a term is just what can be proved about it."

Van Roy and Hiridi also mention logical semantics, which define a statement as a model of logical theory. This is claimed to work well for declarative and logical programming models.

Sources