fixed index
This commit is contained in:
commit
5d4997bc0c
7 changed files with 2758 additions and 2529 deletions
21
README.md
21
README.md
|
@ -15,13 +15,14 @@ and
|
|||
[Philip Wadler](
|
||||
http://homepages.inf.ed.ac.uk/wadler/
|
||||
).
|
||||
Please send us comments! Contact details below.
|
||||
|
||||
|
||||
## How to host literate code
|
||||
|
||||
In directory `sf/` run the following:
|
||||
|
||||
$ make clobber
|
||||
$ make clobber
|
||||
$ make
|
||||
$ make serve &
|
||||
|
||||
|
@ -29,18 +30,6 @@ The visible page appears at
|
|||
|
||||
localhost:4000/sf/<permalink>
|
||||
|
||||
## Markdown
|
||||
|
||||
For markdown commands see [Daring Fireball](
|
||||
https://daringfireball.net/projects/markdown/syntax
|
||||
).
|
||||
|
||||
## Important git commands
|
||||
|
||||
git pull
|
||||
git commit -am "message"
|
||||
git push
|
||||
|
||||
## Unicode abbreviations
|
||||
|
||||
|
||||
|
@ -68,3 +57,9 @@ Also see [here](
|
|||
http://agda.readthedocs.io/en/latest/tools/emacs-mode.html
|
||||
).
|
||||
|
||||
## Markdown
|
||||
|
||||
For markdown commands see [Daring Fireball](
|
||||
https://daringfireball.net/projects/markdown/syntax
|
||||
).
|
||||
|
||||
|
|
|
@ -8,10 +8,10 @@ author: Wen Kokke
|
|||
contributors:
|
||||
- name: Wen Kokke
|
||||
email: wen.kokke@ed.ac.uk
|
||||
github_username: wenkokke
|
||||
twitter_username: wenkokke
|
||||
- name: Philip Wadler
|
||||
email: wadler@inf.ed.ac.uk
|
||||
github_username: wadler
|
||||
twitter_username: philipwadler
|
||||
|
||||
description: >
|
||||
Software Foundations in Agda.
|
||||
|
|
4835
out/Stlc.md
4835
out/Stlc.md
File diff suppressed because it is too large
Load diff
188
src/Basics.lagda
188
src/Basics.lagda
|
@ -1,3 +1,4 @@
|
|||
|
||||
---
|
||||
title : "Basics: Functional Programming in Agda"
|
||||
layout : page
|
||||
|
@ -5,133 +6,94 @@ permalink : /Basics
|
|||
---
|
||||
|
||||
\begin{code}
|
||||
open import Relation.Binary.PropositionalEquality using (_≡_; refl)
|
||||
open import Data.Empty using (⊥; ⊥-elim)
|
||||
open import Relation.Nullary using (¬_; Dec; yes; no)
|
||||
open import Relation.Binary.PropositionalEquality
|
||||
using (_≡_; refl; _≢_; trans; sym)
|
||||
\end{code}
|
||||
|
||||
The functional programming style brings programming closer to
|
||||
simple, everyday mathematics: If a procedure or method has no side
|
||||
effects, then (ignoring efficiency) all we need to understand
|
||||
about it is how it maps inputs to outputs -- that is, we can think
|
||||
of it as just a concrete method for computing a mathematical
|
||||
function. This is one sense of the word "functional" in
|
||||
"functional programming." The direct connection between programs
|
||||
and simple mathematical objects supports both formal correctness
|
||||
proofs and sound informal reasoning about program behavior.
|
||||
|
||||
The other sense in which functional programming is "functional" is
|
||||
that it emphasizes the use of functions (or methods) as
|
||||
_first-class_ values -- i.e., values that can be passed as
|
||||
arguments to other functions, returned as results, included in
|
||||
data structures, etc. The recognition that functions can be
|
||||
treated as data in this way enables a host of useful and powerful
|
||||
idioms.
|
||||
|
||||
Other common features of functional languages include _algebraic
|
||||
data types_ and _pattern matching_, which make it easy to
|
||||
construct and manipulate rich data structures, and sophisticated
|
||||
_polymorphic type systems_ supporting abstraction and code reuse.
|
||||
Agda shares all of these features.
|
||||
|
||||
This chapter introduces the most essential elements of Agda.
|
||||
|
||||
## Enumerated Types
|
||||
|
||||
One unusual aspect of Agda is that its set of built-in
|
||||
features is _extremely_ small. For example, instead of providing
|
||||
the usual palette of atomic data types (booleans, integers,
|
||||
strings, etc.), Agda offers a powerful mechanism for defining new
|
||||
data types from scratch, from which all these familiar types arise
|
||||
as instances.
|
||||
|
||||
Naturally, the Agda distribution comes with an extensive standard
|
||||
library providing definitions of booleans, numbers, and many
|
||||
common data structures like lists and hash tables. But there is
|
||||
nothing magic or primitive about these library definitions. To
|
||||
illustrate this, we will explicitly recapitulate all the
|
||||
definitions we need in this course, rather than just getting them
|
||||
implicitly from the library.
|
||||
|
||||
To see how this definition mechanism works, let's start with a
|
||||
very simple example.
|
||||
|
||||
### Days of the Week
|
||||
|
||||
The following declaration tells Agda that we are defining
|
||||
a new set of data values -- a _type_.
|
||||
# Natural numbers
|
||||
|
||||
\begin{code}
|
||||
data Day : Set where
|
||||
monday : Day
|
||||
tuesday : Day
|
||||
wednesday : Day
|
||||
thursday : Day
|
||||
friday : Day
|
||||
saturday : Day
|
||||
sunday : Day
|
||||
data ℕ : Set where
|
||||
zero : ℕ
|
||||
suc : ℕ → ℕ
|
||||
{-# BUILTIN NATURAL ℕ #-}
|
||||
\end{code}
|
||||
|
||||
The type is called `day`, and its members are `monday`,
|
||||
`tuesday`, etc. The second and following lines of the definition
|
||||
can be read "`monday` is a `day`, `tuesday` is a `day`, etc."
|
||||
|
||||
Having defined `day`, we can write functions that operate on
|
||||
days.
|
||||
|
||||
\begin{code}
|
||||
nextWeekday : Day -> Day
|
||||
nextWeekday monday = tuesday
|
||||
nextWeekday tuesday = wednesday
|
||||
nextWeekday wednesday = thursday
|
||||
nextWeekday thursday = friday
|
||||
nextWeekday friday = monday
|
||||
nextWeekday saturday = monday
|
||||
nextWeekday sunday = monday
|
||||
congruent : ∀ {m n} → m ≡ n → suc m ≡ suc n
|
||||
congruent refl = refl
|
||||
|
||||
injective : ∀ {m n} → suc m ≡ suc n → m ≡ n
|
||||
injective refl = refl
|
||||
|
||||
distinct : ∀ {m} → zero ≢ suc m
|
||||
distinct ()
|
||||
\end{code}
|
||||
|
||||
One thing to note is that the argument and return types of
|
||||
this function are explicitly declared. Like most functional
|
||||
programming languages, Agda can often figure out these types for
|
||||
itself when they are not given explicitly -- i.e., it performs
|
||||
_type inference_ -- but we'll include them to make reading
|
||||
easier.
|
||||
|
||||
Having defined a function, we should check that it works on
|
||||
some examples. There are actually three different ways to do this
|
||||
in Agda.
|
||||
|
||||
First, we can use the Emacs command `C-c C-n` to evaluate a
|
||||
compound expression involving `nextWeekday`. For instance, `nextWeekday
|
||||
friday` should evaluate to `monday`. If you have a computer handy, this
|
||||
would be an excellent moment to fire up Agda and try this for yourself.
|
||||
Load this file, `Basics.lagda`, load it using `C-c C-l`, submit the
|
||||
above example to Agda, and observe the result.
|
||||
|
||||
Second, we can record what we _expect_ the result to be in the
|
||||
form of an Agda type:
|
||||
|
||||
\begin{code}
|
||||
test-nextWeekday : nextWeekday (nextWeekday saturday) ≡ tuesday
|
||||
_≟_ : ∀ (m n : ℕ) → Dec (m ≡ n)
|
||||
zero ≟ zero = yes refl
|
||||
zero ≟ suc n = no (λ())
|
||||
suc m ≟ zero = no (λ())
|
||||
suc m ≟ suc n with m ≟ n
|
||||
... | yes refl = yes refl
|
||||
... | no p = no (λ r → p (injective r))
|
||||
\end{code}
|
||||
|
||||
This declaration does two things: it makes an assertion (that the second
|
||||
weekday after `saturday` is `tuesday`), and it gives the assertion a name
|
||||
that can be used to refer to it later.
|
||||
|
||||
Having made the assertion, we must also verify it. We do this by giving
|
||||
a term of the above type:
|
||||
# Addition and its properties
|
||||
|
||||
\begin{code}
|
||||
test-nextWeekday = refl
|
||||
_+_ : ℕ → ℕ → ℕ
|
||||
zero + n = n
|
||||
suc m + n = suc (m + n)
|
||||
\end{code}
|
||||
|
||||
There is no essential difference between the definition for
|
||||
`test-nextWeekday` here and the definition for `nextWeekday` above,
|
||||
except for the new symbol for equality `≡` and the constructor `refl`.
|
||||
The details of these are not important for now (we'll come back to them in
|
||||
a bit), but essentially `refl` can be read as "The assertion we've made
|
||||
can be proved by observing that both sides of the equality evaluate to the
|
||||
same thing, after some simplification."
|
||||
\begin{code}
|
||||
+-assoc : ∀ m n p → (m + n) + p ≡ m + (n + p)
|
||||
+-assoc zero n p = refl
|
||||
+-assoc (suc m) n p rewrite +-assoc m n p = refl
|
||||
|
||||
Third, we can ask Agda to _compile_ some program involving our definition,
|
||||
This facility is very interesting, since it gives us a way to construct
|
||||
_fully certified_ programs. We'll come back to this topic in later chapters.
|
||||
+-zero : ∀ m → m + zero ≡ m
|
||||
+-zero zero = refl
|
||||
+-zero (suc m) rewrite +-zero m = refl
|
||||
|
||||
+-suc : ∀ m n → m + (suc n) ≡ suc (m + n)
|
||||
+-suc zero n = refl
|
||||
+-suc (suc m) n rewrite +-suc m n = refl
|
||||
|
||||
+-comm : ∀ m n → m + n ≡ n + m
|
||||
+-comm m zero = +-zero m
|
||||
+-comm m (suc n) rewrite +-suc m n | +-comm m n = refl
|
||||
\end{code}
|
||||
|
||||
# Equality and decidable equality for naturals
|
||||
|
||||
|
||||
|
||||
|
||||
# Showing `double` injective
|
||||
|
||||
\begin{code}
|
||||
double : ℕ → ℕ
|
||||
double zero = zero
|
||||
double (suc n) = suc (suc (double n))
|
||||
\end{code}
|
||||
|
||||
\begin{code}
|
||||
double-injective : ∀ m n → double m ≡ double n → m ≡ n
|
||||
double-injective zero zero refl = refl
|
||||
double-injective zero (suc n) ()
|
||||
double-injective (suc m) zero ()
|
||||
double-injective (suc m) (suc n) r =
|
||||
congruent (double-injective m n (injective (injective r)))
|
||||
\end{code}
|
||||
|
||||
In Coq, the inductive proof for `double-injective`
|
||||
is sensitive to how one inducts on `m` and `n`. In Agda, that aspect
|
||||
is straightforward. However, Agda requires helper functions for
|
||||
injection and congruence which are not required in Coq.
|
||||
|
||||
I can remove the use of `congruent` by rewriting with its argument.
|
||||
Is there an easy way to remove the two uses of `injective`?
|
||||
|
|
99
src/Basics0.lagda
Normal file
99
src/Basics0.lagda
Normal file
|
@ -0,0 +1,99 @@
|
|||
|
||||
---
|
||||
title : "Basics: Functional Programming in Agda"
|
||||
layout : page
|
||||
permalink : /Basics
|
||||
---
|
||||
|
||||
\begin{code}
|
||||
open import Data.Empty using (⊥; ⊥-elim)
|
||||
open import Relation.Nullary using (¬_; Dec; yes; no)
|
||||
open import Relation.Binary.PropositionalEquality
|
||||
using (_≡_; refl; _≢_; trans; sym)
|
||||
\end{code}
|
||||
|
||||
# Natural numbers
|
||||
|
||||
\begin{code}
|
||||
data ℕ : Set where
|
||||
zero : ℕ
|
||||
suc : ℕ → ℕ
|
||||
{-# BUILTIN NATURAL ℕ #-}
|
||||
\end{code}
|
||||
|
||||
\begin{code}
|
||||
congruent : ∀ {m n} → m ≡ n → suc m ≡ suc n
|
||||
congruent refl = refl
|
||||
|
||||
injective : ∀ {m n} → suc m ≡ suc n → m ≡ n
|
||||
injective refl = refl
|
||||
|
||||
distinct : ∀ {m} → zero ≢ suc m
|
||||
distinct ()
|
||||
\end{code}
|
||||
|
||||
\begin{code}
|
||||
_≟_ : ∀ (m n : ℕ) → Dec (m ≡ n)
|
||||
zero ≟ zero = yes refl
|
||||
zero ≟ suc n = no (λ())
|
||||
suc m ≟ zero = no (λ())
|
||||
suc m ≟ suc n with m ≟ n
|
||||
... | yes refl = yes refl
|
||||
... | no p = no (λ r → p (injective r))
|
||||
\end{code}
|
||||
|
||||
# Addition and its properties
|
||||
|
||||
\begin{code}
|
||||
_+_ : ℕ → ℕ → ℕ
|
||||
zero + n = n
|
||||
suc m + n = suc (m + n)
|
||||
\end{code}
|
||||
|
||||
\begin{code}
|
||||
+-assoc : ∀ m n p → (m + n) + p ≡ m + (n + p)
|
||||
+-assoc zero n p = refl
|
||||
+-assoc (suc m) n p rewrite +-assoc m n p = refl
|
||||
|
||||
+-zero : ∀ m → m + zero ≡ m
|
||||
+-zero zero = refl
|
||||
+-zero (suc m) rewrite +-zero m = refl
|
||||
|
||||
+-suc : ∀ m n → m + (suc n) ≡ suc (m + n)
|
||||
+-suc zero n = refl
|
||||
+-suc (suc m) n rewrite +-suc m n = refl
|
||||
|
||||
+-comm : ∀ m n → m + n ≡ n + m
|
||||
+-comm m zero = +-zero m
|
||||
+-comm m (suc n) rewrite +-suc m n | +-comm m n = refl
|
||||
\end{code}
|
||||
|
||||
# Equality and decidable equality for naturals
|
||||
|
||||
|
||||
|
||||
|
||||
# Showing `double` injective
|
||||
|
||||
\begin{code}
|
||||
double : ℕ → ℕ
|
||||
double zero = zero
|
||||
double (suc n) = suc (suc (double n))
|
||||
\end{code}
|
||||
|
||||
\begin{code}
|
||||
double-injective : ∀ m n → double m ≡ double n → m ≡ n
|
||||
double-injective zero zero refl = refl
|
||||
double-injective zero (suc n) ()
|
||||
double-injective (suc m) zero ()
|
||||
double-injective (suc m) (suc n) r =
|
||||
congruent (double-injective m n (injective (injective r)))
|
||||
\end{code}
|
||||
|
||||
In Coq, the inductive proof for `double-injective`
|
||||
is sensitive to how one inducts on `m` and `n`. In Agda, that aspect
|
||||
is straightforward. However, Agda requires helper functions for
|
||||
injection and congruence which are not required in Coq.
|
||||
|
||||
I can remove the use of `congruent` by rewriting with its argument.
|
||||
Is there an easy way to remove the two uses of `injective`?
|
|
@ -192,6 +192,9 @@ is sometimes called _alpha renaming_.
|
|||
As we descend from a term into its subterms, variables
|
||||
that are bound may become free. Consider the following terms.
|
||||
|
||||
|
||||
|
||||
|
||||
* `` λ[ f ∶ 𝔹 ⇒ 𝔹 ] λ[ x ∶ 𝔹 ] ` f · (` f · ` x) ``
|
||||
Both variable `f` and `x` are bound.
|
||||
|
||||
|
|
137
src/extra/Basics-old.lagda
Normal file
137
src/extra/Basics-old.lagda
Normal file
|
@ -0,0 +1,137 @@
|
|||
---
|
||||
title : "Basics: Functional Programming in Agda"
|
||||
layout : page
|
||||
permalink : /Basics
|
||||
---
|
||||
|
||||
\begin{code}
|
||||
open import Relation.Binary.PropositionalEquality using (_≡_; refl)
|
||||
\end{code}
|
||||
|
||||
The functional programming style brings programming closer to
|
||||
simple, everyday mathematics: If a procedure or method has no side
|
||||
effects, then (ignoring efficiency) all we need to understand
|
||||
about it is how it maps inputs to outputs -- that is, we can think
|
||||
of it as just a concrete method for computing a mathematical
|
||||
function. This is one sense of the word "functional" in
|
||||
"functional programming." The direct connection between programs
|
||||
and simple mathematical objects supports both formal correctness
|
||||
proofs and sound informal reasoning about program behavior.
|
||||
|
||||
The other sense in which functional programming is "functional" is
|
||||
that it emphasizes the use of functions (or methods) as
|
||||
_first-class_ values -- i.e., values that can be passed as
|
||||
arguments to other functions, returned as results, included in
|
||||
data structures, etc. The recognition that functions can be
|
||||
treated as data in this way enables a host of useful and powerful
|
||||
idioms.
|
||||
|
||||
Other common features of functional languages include _algebraic
|
||||
data types_ and _pattern matching_, which make it easy to
|
||||
construct and manipulate rich data structures, and sophisticated
|
||||
_polymorphic type systems_ supporting abstraction and code reuse.
|
||||
Agda shares all of these features.
|
||||
|
||||
This chapter introduces the most essential elements of Agda.
|
||||
|
||||
## Enumerated Types
|
||||
|
||||
One unusual aspect of Agda is that its set of built-in
|
||||
features is _extremely_ small. For example, instead of providing
|
||||
the usual palette of atomic data types (booleans, integers,
|
||||
strings, etc.), Agda offers a powerful mechanism for defining new
|
||||
data types from scratch, from which all these familiar types arise
|
||||
as instances.
|
||||
|
||||
Naturally, the Agda distribution comes with an extensive standard
|
||||
library providing definitions of booleans, numbers, and many
|
||||
common data structures like lists and hash tables. But there is
|
||||
nothing magic or primitive about these library definitions. To
|
||||
illustrate this, we will explicitly recapitulate all the
|
||||
definitions we need in this course, rather than just getting them
|
||||
implicitly from the library.
|
||||
|
||||
To see how this definition mechanism works, let's start with a
|
||||
very simple example.
|
||||
|
||||
### Days of the Week
|
||||
|
||||
The following declaration tells Agda that we are defining
|
||||
a new set of data values -- a _type_.
|
||||
|
||||
\begin{code}
|
||||
data Day : Set where
|
||||
monday : Day
|
||||
tuesday : Day
|
||||
wednesday : Day
|
||||
thursday : Day
|
||||
friday : Day
|
||||
saturday : Day
|
||||
sunday : Day
|
||||
\end{code}
|
||||
|
||||
The type is called `day`, and its members are `monday`,
|
||||
`tuesday`, etc. The second and following lines of the definition
|
||||
can be read "`monday` is a `day`, `tuesday` is a `day`, etc."
|
||||
|
||||
Having defined `day`, we can write functions that operate on
|
||||
days.
|
||||
|
||||
\begin{code}
|
||||
nextWeekday : Day -> Day
|
||||
nextWeekday monday = tuesday
|
||||
nextWeekday tuesday = wednesday
|
||||
nextWeekday wednesday = thursday
|
||||
nextWeekday thursday = friday
|
||||
nextWeekday friday = monday
|
||||
nextWeekday saturday = monday
|
||||
nextWeekday sunday = monday
|
||||
\end{code}
|
||||
|
||||
One thing to note is that the argument and return types of
|
||||
this function are explicitly declared. Like most functional
|
||||
programming languages, Agda can often figure out these types for
|
||||
itself when they are not given explicitly -- i.e., it performs
|
||||
_type inference_ -- but we'll include them to make reading
|
||||
easier.
|
||||
|
||||
Having defined a function, we should check that it works on
|
||||
some examples. There are actually three different ways to do this
|
||||
in Agda.
|
||||
|
||||
First, we can use the Emacs command `C-c C-n` to evaluate a
|
||||
compound expression involving `nextWeekday`. For instance, `nextWeekday
|
||||
friday` should evaluate to `monday`. If you have a computer handy, this
|
||||
would be an excellent moment to fire up Agda and try this for yourself.
|
||||
Load this file, `Basics.lagda`, load it using `C-c C-l`, submit the
|
||||
above example to Agda, and observe the result.
|
||||
|
||||
Second, we can record what we _expect_ the result to be in the
|
||||
form of an Agda type:
|
||||
|
||||
\begin{code}
|
||||
test-nextWeekday : nextWeekday (nextWeekday saturday) ≡ tuesday
|
||||
\end{code}
|
||||
|
||||
This declaration does two things: it makes an assertion (that the second
|
||||
weekday after `saturday` is `tuesday`), and it gives the assertion a name
|
||||
that can be used to refer to it later.
|
||||
|
||||
Having made the assertion, we must also verify it. We do this by giving
|
||||
a term of the above type:
|
||||
|
||||
\begin{code}
|
||||
test-nextWeekday = refl
|
||||
\end{code}
|
||||
|
||||
There is no essential difference between the definition for
|
||||
`test-nextWeekday` here and the definition for `nextWeekday` above,
|
||||
except for the new symbol for equality `≡` and the constructor `refl`.
|
||||
The details of these are not important for now (we'll come back to them in
|
||||
a bit), but essentially `refl` can be read as "The assertion we've made
|
||||
can be proved by observing that both sides of the equality evaluate to the
|
||||
same thing, after some simplification."
|
||||
|
||||
Third, we can ask Agda to _compile_ some program involving our definition,
|
||||
This facility is very interesting, since it gives us a way to construct
|
||||
_fully certified_ programs. We'll come back to this topic in later chapters.
|
Loading…
Reference in a new issue