this chapter:
- (change to new syntax…)
- function abstraction
- variable binding – 变量绑定
- substitution – 替换
Overview
“Base Types”, only Bool for now. – 基类型
…again, exactly following TAPL.
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t ::=
| x variable
| \x:T1.t2 abstraction -- haskell-ish lambda
| t1 t2 application
| tru constant true
| fls constant false
| test t1 then t2 else t3 conditional
T ::=
| Bool
| T → T arrow type
-- example
\x:Bool. \y:Bool. x
(\x:Bool. \y:Bool. x) fls tru
\f:Bool→Bool. f (f tru)
Some known λ-idioms:
two-arg functions are higher-order one-arg fun, i.e. curried no named functions yet, all “anonymous” – 匿名函数
Slide QA 1
- 2
Bool,fls
Syntax
Formalize syntax.
things are, as usual, in the Type level, so we can “check” them w/ dependent type.
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Inductive ty : Type :=
| Bool : ty
| Arrow : ty → ty → ty.
Inductive tm : Type :=
| var : string → tm
| app : tm → tm → tm
| abs : string → ty → tm → tm
| tru : tm
| fls : tm
| test : tm → tm → tm → tm.
Noted that,
\x:T.t(formally,abs x T t), the argument type is explicitly annotated (not inferred.)
另外,这里介绍了一个小 trick: 用 Notation (更接近 宏 ) 而非 Defintion 使得我们可以使用 auto…
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(** idB = \x:Bool. x **)
Notation idB := (abs x Bool (var x)).
Operational Semantics
Values 值
truandflsare values- what about function?
\x:T. tis value ifftvalue. – Coq\x:T. tis always value – most FP lang, either CBV or CBN
Coq 这么做挺奇怪的,不过对 Coq 来说:
terms can be considered equiv up to the computation VM (在其项化简可以做到的范围内都算相等) this rich the notion of Coq’s value (所以 Coq 的值的概念是比一般要大的)
Three ways to construct value (unary relation = predicate)
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Inductive value : tm → Prop :=
| v_abs : ∀x T t, value (abs x T t)
| v_tru : value tru
| v_fls : value fls.
STLC Programs 「程序」的概念也是要定义的
- closed = term not refer any undefined var = complete program
- open term = term with free variable
Having made the choice not to reduce under abstractions, we don’t need to worry about whether variables are values, since we’ll always be reducing programs “from the outside in,” and that means the step relation will always be working with closed terms.
if we could reduce under abstraction and variables are values… What’s the implication here? 始终不懂…
Substitution (IMPORTANT!) 替换
[x:=s]tand pronounced “substitute s for x in t.”
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(\x:Bool. test x then tru else x) fls ==> test fls then tru else fls
Important capture example:
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[x:=tru] (\x:Bool. x) ==> \x:Bool. x -- x is bound, we need α-conversion here
!=> \x:Bool. tru
Informal definition…
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[x:=s]x = s
[x:=s]y = y if x ≠ y
[x:=s](\x:T11. t12) = \x:T11. t12
[x:=s](\y:T11. t12) = \y:T11. [x:=s]t12 if x ≠ y
[x:=s](t1 t2) = ([x:=s]t1) ([x:=s]t2)
...
and formally:
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Reserved Notation "'[' x ':=' s ']' t" (at level 20).
Fixpoint subst (x : string) (s : tm) (t : tm) : tm :=
match t with
| var x' ⇒ if eqb_string x x' then s else t (* <-- computational eqb_string *)
| abs x' T t1 ⇒ abs x' T (if eqb_string x x' then t1 else ([x:=s] t1))
| app t1 t2 ⇒ app ([x:=s] t1) ([x:=s] t2)
...
Computable
Fixpointmeans meta-function! (in metalanguage, Coq here)
如果我们考虑用于替换掉某个变量的项 s 其本身也含有自由变量, 那么定义替换将会变得困难一点。
Is if x ≠ y for function abstraction one sufficient? – 在 PLT 中我们采取了更严格的定义
Only safe if we only consider
sis closed term.
Prof.Mtf:
here…it’s not really “defining on closed terms”. Technically, you can still write open terms. if we want, we could define the real
closed_term…more works to prove things tho.
Prof.Mtf:
In some more rigorous setting…we might define
well_typed_termand the definition itself is the proof ofPreservation!
Slide QA 2
- (3)
Reduction (beta-reduction) beta-归约
Should be familar
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value v2
---------------------------- (ST_AppAbs) until value, i.e. function (β-reduction)
(\x:T.t12) v2 --> [x:=v2]t12
t1 --> t1'
---------------- (ST_App1) reduce lhs, Function side
t1 t2 --> t1' t2
value v1
t2 --> t2'
---------------- (ST_App2) reduce rhs, Arg side
v1 t2 --> v1 t2'
Formally, (I was expecting they invents some new syntax for this one…so we only have AST)
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Reserved Notation "t1 '-->' t2" (at level 40).
Inductive step : tm → tm → Prop :=
| ST_AppAbs : ∀x T t12 v2,
value v2 →
(app (abs x T t12) v2) --> [x:=v2]t12
| ST_App1 : ∀t1 t1' t2,
t1 --> t1' →
app t1 t2 --> app t1' t2
| ST_App2 : ∀v1 t2 t2',
value v1 →
t2 --> t2' →
app v1 t2 --> app v1 t2'
...
Slide QA 3
- (1)
idBB idB -> idB - (1)
idBB (idBB idB) -> idB - if () ill-typed
idBB (notB tru) -> idBB fls ....- we don’t type check in step
- (3)
idB fls - NOT…ill-typed one & open term
Typing
Typing Contexts 类型上下文
we need something like environment but for Types.
three-place typing judgment, informally written – 三元类型断言
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Gamma ⊢ t ∈ T
“under the assumptions in Gamma, the term t has the type T.”
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Definition context := partial_map ty.
(X ⊢> T11, Gamma)
Why partial_map here?
IMP can use total_map because it gave default value for undefined var.
Typing Relations
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Gamma x = T
---------------- (T_Var) look up
Gamma |- x \in T
(x |-> T11 ; Gamma) |- t12 \in T12
---------------------------------- (T_Abs) type check against context w/ arg
Gamma |- \x:T11.t12 \in T11->T12
Gamma |- t1 \in T11->T12
Gamma |- t2 \in T11
---------------------- (T_App)
Gamma |- t1 t2 \in T12
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Example typing_example_1 :
empty ⊢ abs x Bool (var x) ∈ Arrow Bool Bool.
Proof.
apply T_Abs. apply T_Var. reflexivity. Qed.
example_2
eapplyA?? looks like need need another environment to look upA…
Typable / Deciable
decidable type system = decide term if typable or not. done by type checker…
can we prove…?
∀ Γ e, ∃ τ, (Γ ⊢ e : τ) ∨ ¬(Γ ⊢ e : τ)– a type inference algorithm!
Provability in Coq witness decidabile operations.
show term is “not typeable”
Keep inversion till the contradiction.
