+++ /dev/null
-Order matters
-
-Declarative versus imperative:
-
-In a pure declarative language, the order in which expressions are
-evaluated (reduced, simplified) does not affect the outcome.
-
-(3 + 4) * (5 + 11) = 7 * (5 + 11) = 7 * 16 = 112
-(3 + 4) * (5 + 11) = (3 + 4) * 16 = 7 * 16 = 112
-
-In an imperative language, order makes a difference.
-
-x := 2
-x := x + 1
-x == 3
-[true]
-
-x := x + 1
-x := 2
-x == 3
-[false]
-
-
-Declaratives: assertions of statements.
-No matter what order you assert true facts, they remain true:
-
-The value is the product of x and y.
-x is the sum of 3 and 4.
-y is the sum of 5 and 11.
-The value is 112.
-
-Imperatives: performative utterances expressing a deontic or bouletic
-modality ("Be polite", "shut the door")
-Resource-sensitive, order sensitive:
-
-Make x == 2.
-Add one to x.
-See if x == 3.
-
-----------------------------------------------------
-
-Untype (monotyped) lambda calculus
-
-Syntax:
-
-Variables: x, x', x'', x''', ...
-(Cheat: x, y, z, x1, x2, ...)
-
-Each variable is a term.
-For all terms M and N and variable a, the following are also terms:
-
-(M N) The application of M to N
-(\a M) The abstraction of a over M
-
-Examples of terms:
-
-x
-(y x)
-(x x)
-(\x y)
-(\x x)
-(\x (\y x))
-(x (\x x))
-((\x (x x))(\x (x x)))
-
-Reduction/conversion/equality:
-
-Lambda terms express recipes for combining terms into new terms.
-The key operation in the lambda calculus is beta-conversion.
-
-((\a M) N) ~~>_beta M{a := N}
-
-The term on the left of the arrow is an application whose first
-element is a lambda abstraction. (Such an application is called a
-"redex".) The beta reduction rule says that a redex is
-beta-equivalent to a term that is constructed by replacing every
-(free) occurrence of a in M by a copy of N. For example,
-
-((\x x) z) ~~>_beta z
-((\x (x x)) z) ~~>_beta (z z)
-((\x x) (\y y)) ~~>_beta (\y y)
-
-Beta reduction is only allowed to replace *free* occurrences of a variable.
-An occurrence of a variable a is BOUND in T if T has the form (\a N).
-If T has the form (M N), and the occurrence of a is in M, then a is
-bound in T just in case a is bound in M; if the occurrence of a is in
-N, than a is bound in T just in case a is bound in N. An occurrence
-of a variable a is FREE in a term T iff it is not bound in T.
-For instance:
-
-T = (x (\x (\y (x (y z)))))
-
-The first occurrence of x in T is free. The second occurrence of x
-immediately follows a lambda, and is bound. The third occurrence of x
-occurs within a form that begins with "\x", so it is bound as well.
-Both occurrences of y are bound, and the only occurrence of z is free.
-
-Lambda terms represent functions.
-All (recursively computable) functions can be represented by lambda
-terms (the untyped lambda calculus is Turning complete).
-For some lambda terms, it is easy to see what function they represent:
-
-(\x x) the identity function: given any argument M, this function
-simply returns M: ((\x x) M) ~~>_beta M.
-
-(\x (x x)) duplicates its argument:
-((\x (x x)) M) ~~> (M M)
-
-(\x (\y x)) throws away its second argument:
-(((\x (\y x)) M) N) ~~> M
-
-and so on.
-
-It is easy to see that distinct lambda terms can represent the same
-function. For instance, (\x x) and (\y y) both express the same
-function, namely, the identity function.
-
------------------------------------------
-Dot notation: dot means "put a left paren here, and put the right
-paren as far the right as possible without creating unbalanced
-parentheses". So (\x(\y(xy))) = \x\y.xy, and \x\y.(z y) x =
-(\x(\y((z y) z))), but (\x\y.(z y)) x = ((\x(\y(z y))) x).
-
------------------------------------------
-
-Church figured out how to encode integers and arithmetic operations
-using lambda terms. Here are the basics:
-
-0 = \f\x.fx
-1 = \f\x.f(fx)
-2 = \f\x.f(f(fx))
-3 = \f\x.f(f(f(fx)))
-...
-
-Adding two integers involves applying a special function + such that
-(+ 1) 2 = 3. Here is a term that works for +:
-
-+ = \m\n\f\x.m(f((n f) x))
-
-So (+ 0) 0 =
-(((\m\n\f\x.m(f((n f) x))) ;+
- \f\x.fx) ;0
- \f\x.fx) ;0
-
-~~>_beta targeting m for beta conversion
-
-((\n\f\x.[\f\x.fx](f((n f) x)))
- \f\x.fx)
-
-\f\x.[\f\x.fx](f(([\f\x.fx] f) x))
-
-\f\x.[\f\x.fx](f(fx))
-
-\f\x.\x.[f(fx)]x
-
-\f\x.f(fx)
-
-
-
-----------------------------------------------------
-
-A concrete example: "damn" side effects
-
-1. Sentences have truth conditions.
-2. If "John read the book" is true, then
- John read something,
- Someone read the book,
- John did something to the book,
- etc.
-3. If "John read the damn book",
- all the same entailments follow.
- To a first approximation, "damn" does not affect at-issue truth
- conditions.
-4. "Damn" does contribute information about the attitude of the speaker
- towards some aspect of the situation described by the sentence.
-
-
-
------------------------------------------
-Old notes, no longer operative:
-
-1. Theoretical computer science is beautiful.
-
- Google search for "anagram": Did you mean "nag a ram"?
- Google search for "recursion": Did you mean "recursion"?
-
- Y = \f.(\x.f (x x)) (\x.f (x x))
-
-
-1. Understanding the meaning(use) of programming languages
- helps understanding the meaning(use) of natural langauges
-
- 1. Richard Montague. 1970. Universal Grammar. _Theoria_ 34:375--98.
- "There is in my opinion no important theoretical difference
- between natural languages and the artificial languages of
- logicians; indeed, I consider it possible to comprehend the
- syntax and semantics of both kinds of languages within a
- single natural and mathematically precise theory."
-
- 2. Similarities:
-
- Function/argument structure:
- f(x)
- kill(it)
- pronominal binding:
- x := x + 1
- John is his own worst enemy
- Quantification:
- foreach x in [1..10] print x
- Print every number from 1 to 10
-
- 3. Possible differences:
-
- Parentheses:
- 3 * (4 + 7)
- ?It was four plus seven that John computed 3 multiplied by
- (compare: John computed 3 multiplied by four plus seven)
- Ambiguity:
- 3 * 4 + 7
- Time flies like and arrow, fruit flies like a banana.
- Vagueness:
- 3 * 4
- A cloud near the mountain
- Unbounded numbers of distinct pronouns:
- f(x1) + f(x2) + f(x3) + ...
- He saw her put it in ...
- [In ASL, dividing up the signing space...]
-
-
-2. Standard methods in linguistics are limited.
-
- 1. First-order predicate calculus
-
- Invented for reasoning about mathematics (Frege's quantification)
-
- Alethic, order insensitive: phi & psi == psi & phi
- But: John left and Mary left too /= Mary left too and John left
-
- 2. Simply-typed lambda calculus
-
- Can't express the Y combinator
-
-
-3. Meaning is computation.
-
- 1. Semantics is programming
-
- 2. Good programming is good semantics
-
- 1. Example
-
- 1. Programming technique
-
- Exceptions
- throw (raise)
- catch (handle)
-
- 2. Application to linguistics
- presupposition
- expressives
-
- Develop application:
- fn application
- divide by zero
- test and repair
- raise and handle
-
- fn application
- presupposition failure
- build into meaning of innocent predicates?
- expressives
- throw
- handle
- resume computation
-