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15 Commits
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Author SHA1 Message Date
James Eversole
33c2119708 Don't require available library to run REPL or decoder
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2025-01-27 16:28:40 -06:00
James Eversole
3b833ca75b Gracefully ignore no-op redefs
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2025-01-27 16:19:59 -06:00
James Eversole
203bc1898d README typo 2025-01-27 16:07:32 -06:00
James Eversole
87aed72ab2 # Modules
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Basic implementation of a module system including tests.
 2025-01-27 16:04:04 -06:00
James Eversole
f71f88dce3 Small dependency ordering optimizations 2025-01-26 16:08:34 -06:00
James Eversole
918d929c09 # File eval mode now relies on main function
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To encourage organizing code in a way that helps in understanding, I
have implemented the common idiom of requiring a `main` function. In
tricu and other functional languages, it is usually placed near the top
of the module. The evaluator gracefully handles the situation of passing
multiple files where the intermediary "library" files do not have main functions.
 2025-01-26 15:33:12 -06:00
James Eversole
a64b3f0829 Definition dependency analysis
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tricu now allows defining terms in any order and will resolve
dependencies to ensure that they're evaluated in the right order.
Undefined terms are detected and throw errors during dependency
ordering.
For now we can't define top-level mutually recursive terms.
 2025-01-26 14:50:39 -06:00
James Eversole
e2621bc09d Allow lambda expressions without explicit paren
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2025-01-26 08:52:28 -06:00
James Eversole
ea128929da Add optimization cases for triage and composition 2025-01-25 15:12:28 -06:00
James Eversole
2bd388c871 Eval optimization! Tests for demos
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2025-01-25 09:18:13 -06:00
James Eversole
1f5a910fb2 Immutable definitions and documentation updates
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2025-01-24 16:14:33 -06:00
James Eversole
8b043911ca Add size demo 2025-01-23 18:57:59 -06:00
James Eversole
2e246eb1c8 Remove Nix caching that can't work due to /nix/store permissions
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2025-01-23 17:59:47 -06:00
James Eversole
ba340ae56f Update README to reflect demo
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2025-01-23 17:36:39 -06:00
James Eversole
739851c864 Minify and mark as pre-release
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2025-01-23 17:23:02 -06:00
36 changed files with 840 additions and 377 deletions
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39
.gitea/workflows/test-and-build.yml
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@ -28,16 +28,6 @@ jobs:
restore-keys: | restore-keys: |
cabal- cabal-
- name: Set up cache for Nix
uses: actions/cache@v4
with:
path: |
/nix/store
/nix/var/nix/cache
key: nix-${{ hashFiles('flake.lock') }}
restore-keys: |
nix-
- name: Initialize Cabal and update package list - name: Initialize Cabal and update package list
run: | run: |
nix develop --command cabal update nix develop --command cabal update
@ -58,29 +48,18 @@ jobs:
with: with:
fetch-depth: 0 fetch-depth: 0
- name: Set up cache for Nix - name: Build and shrink binary
uses: actions/cache@v4
with:
path: |
/nix/store
/nix/var/nix/cache
key: nix-${{ hashFiles('flake.lock') }}
restore-keys: |
nix-
- name: Build binary
run: | run: |
nix build nix build
ls -alh ./result/bin/tricu cp -L ./result/bin/tricu ./tricu
chmod 755 ./tricu
- name: Setup go for release actoin nix develop --command upx ./tricu
uses: actions/setup-go@v5
with:
go-version: '>=1.20.1'
- name: Release binary - name: Release binary
uses: https://gitea.com/actions/release-action@main uses: akkuman/gitea-release-action@v1
with: with:
files: |- files: |-
./result/bin/tricu ./tricu
api_key: '${{ secrets.RELEASE_TOKEN }}' token: '${{ secrets.RELEASE_TOKEN }}'
body: '${{ gitea.event.head_commit.message }}'
prerelease: true

39
README.md
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@ -2,21 +2,23 @@
## Introduction ## Introduction
tricu (pronounced "tree-shoe") is a purely functional interpreted language implemented in Haskell. [I'm](https://eversole.co) developing tricu to further research the possibilities offered by the various forms of [Tree Calculi](https://github.com/barry-jay-personal/typed_tree_calculus/blob/main/typed_program_analysis.pdf). tricu (pronounced "tree-shoe") is a purely functional interpreted language implemented in Haskell. It is fundamentally based on the application of [Tree Calculus](https://github.com/barry-jay-personal/typed_tree_calculus/blob/main/typed_program_analysis.pdf) terms, but minimal syntax sugar is included to provide a useful programming tool. tricu is under active development and you can expect breaking changes with nearly every commit.
tricu offers minimal syntax sugar yet manages to provide a complete, intuitive, and familiar programming environment. There is great power in simplicity. tricu offers: tricu is the word for "tree" in Lojban: `(x1) is a tree of species/cultivar (x2)`.
1. `t` operator behaving by the rules of Tree Calculus ## Features
1. Function definitions/assignments
1. Lambda abstractions eliminated to Tree Calculus forms
1. List, Number, and String literals
1. Parentheses for grouping function application
These features move us cleanly out of the [turing tarpit](https://en.wikipedia.org/wiki/Turing_tarpit) territory that you may find yourself in if you try working only with the `t` operator. - Tree Calculus operator: `t`
- Assignments: `x = t t`
- Immutable definitions
- Lambda abstraction syntax: `id = (\a : a)`
- List, Number, and String literals: `[(2) ("Hello")]`
- Function application: `not (not false)`
- Higher order/first-class functions: `map (\a : lconcat a "!") [("Hello")]`
- Intensionality blurs the distinction between functions and data (see REPL examples)
- Simple module system for code organization
tricu is the word for "tree" in Lojban: `(x1) is a tree of species/cultivar (x2)`. This project was named "sapling" until I discovered the name is already being used for other (completely unrelated) programming language development projects. ## REPL examples
## What does it look like?
``` ```
tricu < -- Anything after `--` on a single line is a comment tricu < -- Anything after `--` on a single line is a comment
@ -26,19 +28,24 @@ tricu > "Hello, world!"
tricu < id (head (map (\i : lconcat i " world!") [("Hello, ")])) tricu < id (head (map (\i : lconcat i " world!") [("Hello, ")]))
tricu > "Hello, world!" tricu > "Hello, world!"
tricu < -- Intensionality! We can inspect the structure of a function. tricu < -- Intensionality! We can inspect the structure of a function or data.
tricu < triage = (\a b c : t (t a b) c) tricu < triage = (\a b c : t (t a b) c)
tricu < test = triage "Leaf" (\z : "Stem") (\a b : "Fork") tricu < test = triage "Leaf" (\z : "Stem") (\a b : "Fork")
tricu < test (t t) tricu < test (t t)
tricu > "Stem" tricu > "Stem"
tricu < -- We can even write a function to convert a term back to source code tricu < -- We can even convert a term back to source code (/demos/toSource.tri)
tricu < toSource not? tricu < toSource not?
tricu > "(t (t (t t) (t t t)) (t t (t t t)))" tricu > "(t (t (t t) (t t t)) (t t (t t t)))"
tricu < -- or calculate its size (/demos/size.tri)
tricu < size not?
tricu > 12
``` ```
## Installation and Use ## Installation and Use
You can easily build and/or run this project using [Nix](https://nixos.org/download/). [Releases are available for Linux.](https://git.eversole.co/James/tricu/releases)
Or you can easily build and run this project using [Nix](https://nixos.org/download/).
- Quick Start (REPL): - Quick Start (REPL):
- `nix run git+https://git.eversole.co/James/tricu` - `nix run git+https://git.eversole.co/James/tricu`
@ -65,7 +72,7 @@ tricu eval [OPTIONS]
-f --file=FILE Input file path(s) for evaluation. -f --file=FILE Input file path(s) for evaluation.
Defaults to stdin. Defaults to stdin.
-t --form=FORM Optional output form: (tree|fsl|ast|ternary|ascii). -t --form=FORM Optional output form: (tree|fsl|ast|ternary|ascii|decode).
Defaults to tricu-compatible `t` tree form. Defaults to tricu-compatible `t` tree form.
tricu decode [OPTIONS] tricu decode [OPTIONS]
@ -79,4 +86,4 @@ tricu decode [OPTIONS]
Tree Calculus was discovered by [Barry Jay](https://github.com/barry-jay-personal/blog). Tree Calculus was discovered by [Barry Jay](https://github.com/barry-jay-personal/blog).
[treecalcul.us](https://treecalcul.us) is an excellent website with an intuitive playground created by [Johannes Bader](https://johannes-bader.com/) that introduced me to Tree Calculus. If tricu sounds interesting but compiling this repo sounds like a hassle, you should check out his site. [treecalcul.us](https://treecalcul.us) is an excellent website with an intuitive Tree Calculus code playground created by [Johannes Bader](https://johannes-bader.com/) that introduced me to Tree Calculus.

43
demos/equality.tri
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@ -1,24 +1,41 @@
false = t !module Equality
true = t t
triage = (\a b c : t (t a b) c) !import "lib/base.tri" Lib
matchBool = (\ot of : triage main = lambdaEqualsTC
-- We represent `false` with a Leaf and `true` with a Stem Leaf
demo_false = t
demo_true = t t
-- Tree Calculus representation of the Boolean `not` function
not_TC? = t (t (t t) (t t t)) (t t (t t t))
-- /demos/toSource.tri contains an explanation of `triage`
demo_triage = \a b c : t (t a b) c
demo_matchBool = (\ot of : demo_triage
of of
(\_ : ot) (\_ : ot)
(\_ _ : ot) (\_ _ : ot)
) )
-- Lambda representation of the Boolean `not` function
not_Lambda? = demo_matchBool demo_false demo_true
not_TC? = t (t (t t) (t t t)) (t t (t t t)) -- Since tricu eliminates Lambda terms to SKI combinators, the tree form of many
not_Lambda? = matchBool false true -- functions defined via Lambda terms are larger than the most efficient TC
-- representation. Between different languages that evaluate to tree calculus
-- terms, the exact implementation of Lambda elimination may differ and lead
-- to different tree representations even if they share extensional behavior.
areEqual? = equal not_TC not_Lambda -- Let's see if these are the same:
lambdaEqualsTC = Lib.equal? not_TC? not_Lambda?
true_TC? = not_TC false -- Here are some checks to verify their extensional behavior is the same:
false_TC? = not_TC true true_TC? = not_TC? demo_false
false_TC? = not_TC? demo_true
true_Lambda? = not_Lambda false true_Lambda? = not_Lambda? demo_false
false_Lambda? = not_Lambda true false_Lambda? = not_Lambda? demo_true
areTrueEqual? = equal true_TC true_Lambda bothTrueEqual? = Lib.equal? true_TC? true_Lambda?
areFalseEqual? = equal false_TC false_Lambda bothFalseEqual? = Lib.equal? false_TC? false_Lambda?

54
demos/levelOrderTraversal.tri
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@ -1,11 +1,14 @@
!module LOT
!import "lib/base.tri" Lib
main = exampleTwo
-- Level Order Traversal of a labelled binary tree -- Level Order Traversal of a labelled binary tree
-- Objective: Print each "level" of the tree on a separate line -- Objective: Print each "level" of the tree on a separate line
-- --
-- NOTICE: This demo relies on tricu base library functions -- We model labelled binary trees as nested lists where values act as labels. We
--
-- We model labelled binary trees as sublists where values act as labels. We
-- require explicit notation of empty nodes. Empty nodes can be represented -- require explicit notation of empty nodes. Empty nodes can be represented
-- with an empty list, `[]`, which is equivalent to a single node `t`. -- with an empty list, `[]`, which evaluates to a single node `t`.
-- --
-- Example tree inputs: -- Example tree inputs:
-- [("1") [("2") [("4") t t] t] [("3") [("5") t t] [("6") t t]]]] -- [("1") [("2") [("4") t t] t] [("3") [("5") t t] [("6") t t]]]]
@ -15,43 +18,42 @@
-- 2 3 -- 2 3
-- / / \ -- / / \
-- 4 5 6 -- 4 5 6
--
label = (\node : head node) label = \node : Lib.head node
left = (\node : if (emptyList node) left = (\node : Lib.if (Lib.emptyList? node)
[] []
(if (emptyList (tail node)) (Lib.if (Lib.emptyList? (Lib.tail node))
[] []
(head (tail node)))) (Lib.head (Lib.tail node))))
right = (\node : if (emptyList node) right = (\node : Lib.if (Lib.emptyList? node)
[] []
(if (emptyList (tail node)) (Lib.if (Lib.emptyList? (Lib.tail node))
[] []
(if (emptyList (tail (tail node))) (Lib.if (Lib.emptyList? (Lib.tail (Lib.tail node)))
[] []
(head (tail (tail node)))))) (Lib.head (Lib.tail (Lib.tail node))))))
processLevel = y (\self queue : if (emptyList queue) processLevel = Lib.y (\self queue : Lib.if (Lib.emptyList? queue)
[] []
(pair (map label queue) (self (filter (Lib.pair (Lib.map label queue) (self (Lib.filter
(\node : not (emptyList node)) (\node : Lib.not? (Lib.emptyList? node))
(lconcat (map left queue) (map right queue)))))) (Lib.lconcat (Lib.map left queue) (Lib.map right queue))))))
levelOrderTraversal_ = (\a : processLevel (t a t)) levelOrderTraversal_ = \a : processLevel (t a t)
toLineString = y (\self levels : if (emptyList levels) toLineString = Lib.y (\self levels : Lib.if (Lib.emptyList? levels)
"" ""
(lconcat (Lib.lconcat
(lconcat (map (\x : lconcat x " ") (head levels)) "") (Lib.lconcat (Lib.map (\x : Lib.lconcat x " ") (Lib.head levels)) "")
(if (emptyList (tail levels)) "" (lconcat (t (t 10 t) t) (self (tail levels)))))) (Lib.if (Lib.emptyList? (Lib.tail levels)) "" (Lib.lconcat (t (t 10 t) t) (self (Lib.tail levels))))))
levelOrderToString = (\s : toLineString (levelOrderTraversal_ s)) levelOrderToString = \s : toLineString (levelOrderTraversal_ s)
flatten = foldl (\acc x : lconcat acc x) "" flatten = Lib.foldl (\acc x : Lib.lconcat acc x) ""
levelOrderTraversal = (\s : lconcat (t 10 t) (flatten (levelOrderToString s))) levelOrderTraversal = \s : Lib.lconcat (t 10 t) (flatten (levelOrderToString s))
exampleOne = levelOrderTraversal [("1") exampleOne = levelOrderTraversal [("1")
[("2") [("4") t t] t] [("2") [("4") t t] t]
@ -61,5 +63,3 @@ exampleTwo = levelOrderTraversal [("1")
[("2") [("4") [("8") t t] [("9") t t]] [("2") [("4") [("8") t t] [("9") t t]]
[("6") [("10") t t] [("12") t t]]] [("6") [("10") t t] [("12") t t]]]
[("3") [("5") [("11") t t] t] [("7") t t]]] [("3") [("5") [("11") t t] t] [("7") t t]]]
exampleTwo

25
demos/size.tri Normal file
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@ -0,0 +1,25 @@
!module Size
!import "lib/base.tri" Lib
main = size size
compose = \f g x : f (g x)
succ = Lib.y (\self :
Lib.triage
1
t
(Lib.triage
(t (t t))
(\_ Lib.tail : t t (self Lib.tail))
t))
size = (\x :
(Lib.y (\self x :
compose succ
(Lib.triage
(\x : x)
self
(\x y : compose (self x) (self y))
x)) x 0))

45
demos/toSource.tri
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@ -1,46 +1,51 @@
!module ToSource
!import "lib/base.tri" Lib
main = toSource Lib.not?
-- Thanks to intensionality, we can inspect the structure of a given value -- Thanks to intensionality, we can inspect the structure of a given value
-- even if it's a function. This includes lambdas which are eliminated to -- even if it's a function. This includes lambdas which are eliminated to
-- Tree Calculus (TC) terms during evaluation. -- Tree Calculus (TC) terms during evaluation.
-- Triage takes four arguments: the first three represent behaviors for each -- `triage` takes four arguments: the first three represent behaviors for each
-- structural case in Tree Calculus (Leaf, Stem, and Fork). -- structural case in Tree Calculus (Leaf, Stem, and Fork).
-- The fourth argument is the value whose structure is inspected. By evaluating -- The fourth argument is the value whose structure is inspected. By evaluating
-- the Tree Calculus term, `triage` enables branching logic based on the term's -- the Tree Calculus term, `triage` enables branching logic based on the term's
-- shape, making it possible to perform structure-specific operations such as -- shape, making it possible to perform structure-specific operations such as
-- reconstructing the terms' source code representation. -- reconstructing the terms' source code representation.
triage = (\a b c : t (t a b) c) -- triage = (\leaf stem fork : t (t leaf stem) fork)
-- Base case of a single Leaf -- Base case of a single Leaf
sourceLeaf = t (head "t") sourceLeaf = t (Lib.head "t")
-- Stem case -- Stem case
sourceStem = (\convert : (\a rest : sourceStem = (\convert : (\a rest :
t (head "(") -- Start with a left parenthesis "(". t (Lib.head "(") -- Start with a left parenthesis "(".
(t (head "t") -- Add a "t" (t (Lib.head "t") -- Add a "t"
(t (head " ") -- Add a space. (t (Lib.head " ") -- Add a space.
(convert a -- Recursively convert the argument. (convert a -- Recursively convert the argument.
(t (head ")") rest)))))) -- Close with ")" and append the rest. (t (Lib.head ")") rest)))))) -- Close with ")" and append the rest.
-- Fork case -- Fork case
sourceFork = (\convert : (\a b rest : sourceFork = (\convert : (\a b rest :
t (head "(") -- Start with a left parenthesis "(". t (Lib.head "(") -- Start with a left parenthesis "(".
(t (head "t") -- Add a "t" (t (Lib.head "t") -- Add a "t"
(t (head " ") -- Add a space. (t (Lib.head " ") -- Add a space.
(convert a -- Recursively convert the first arg. (convert a -- Recursively convert the first arg.
(t (head " ") -- Add another space. (t (Lib.head " ") -- Add another space.
(convert b -- Recursively convert the second arg. (convert b -- Recursively convert the second arg.
(t (head ")") rest)))))))) -- Close with ")" and append the rest. (t (Lib.head ")") rest)))))))) -- Close with ")" and append the rest.
-- Wrapper around triage -- Wrapper around triage
toSource_ = y (\self arg : toSource_ = Lib.y (\self arg :
triage Lib.triage
sourceLeaf -- Triage `a` case, Leaf sourceLeaf -- `triage` "a" case, Leaf
(sourceStem self) -- Triage `b` case, Stem (sourceStem self) -- `triage` "b" case, Stem
(sourceFork self) -- Triage `c` case, Fork (sourceFork self) -- `triage` "c" case, Fork
arg) -- The term to be inspected arg) -- The term to be inspected
-- toSource takes a single TC term and returns a String -- toSource takes a single TC term and returns a String
toSource = (\v : toSource_ v "") toSource = \v : toSource_ v ""
exampleOne = toSource true -- OUT: "(t t)" exampleOne = toSource Lib.true -- OUT: "(t t)"
exampleTwo = toSource not -- OUT: "(t (t (t t) (t t t)) (t t (t t t)))" exampleTwo = toSource Lib.not? -- OUT: "(t (t (t t) (t t t)) (t t (t t t)))"

7
flake.nix
View File

@ -32,10 +32,11 @@
defaultPackage = self.packages.${system}.default; defaultPackage = self.packages.${system}.default;
devShells.default = pkgs.mkShell { devShells.default = pkgs.mkShell {
buildInputs = with pkgs.haskellPackages; [ buildInputs = with pkgs; [
cabal-install haskellPackages.cabal-install
ghcid haskellPackages.ghcid
customGHC customGHC
upx
]; ];
inputsFrom = builtins.attrValues self.packages.${system}; inputsFrom = builtins.attrValues self.packages.${system};
}; };

43
lib/base.tri
View File

@ -7,18 +7,15 @@ s = t (t (k t)) t
m = s i i m = s i i
b = s (k s) k b = s (k s) k
c = s (s (k s) (s (k k) s)) (k k) c = s (s (k s) (s (k k) s)) (k k)
iC = (\a b c : s a (k c) b) id = \a : a
iD = b (b iC) iC
iE = b (b iD) iC
yi = (\i : b m (c b (i m)))
y = yi iC
yC = yi iD
yD = yi iE
id = (\a : a)
pair = t pair = t
if = (\cond then else : t (t else (t t then)) t cond) if = \cond then else : t (t else (t t then)) t cond
triage = (\a b c : t (t a b) c) y = ((\mut wait fun : wait mut (\x : fun (wait mut x)))
(\x : x x)
(\a0 a1 a2 : t (t a0) (t t a2) a1))
triage = \leaf stem fork : t (t leaf stem) fork
test = triage "Leaf" (\_ : "Stem") (\_ _ : "Fork") test = triage "Leaf" (\_ : "Stem") (\_ _ : "Fork")
matchBool = (\ot of : triage matchBool = (\ot of : triage
@ -27,17 +24,9 @@ matchBool = (\ot of : triage
(\_ _ : ot) (\_ _ : ot)
) )
matchList = (\oe oc : triage matchList = \a b : triage a _ b
oe
_
oc
)
matchPair = (\op : triage matchPair = \a : triage _ _ a
_
_
op
)
not? = matchBool false true not? = matchBool false true
and? = matchBool id (\_ : false) and? = matchBool id (\_ : false)
@ -53,20 +42,18 @@ lconcat = y (\self : matchList
lAnd = (triage lAnd = (triage
(\_ : false) (\_ : false)
(\_ x : x) (\_ x : x)
(\_ _ x : x) (\_ _ x : x))
)
lOr = (triage lOr = (triage
(\x : x) (\x : x)
(\_ _ : true) (\_ _ : true)
(\_ _ _ : true) (\_ _ _ : true))
)
map_ = y (\self : map_ = y (\self :
matchList matchList
(\_ : t) (\_ : t)
(\head tail f : pair (f head) (self tail f))) (\head tail f : pair (f head) (self tail f)))
map = (\f l : map_ l f) map = \f l : map_ l f
equal? = y (\self : triage equal? = y (\self : triage
(triage (triage
@ -87,10 +74,10 @@ equal? = y (\self : triage
filter_ = y (\self : matchList filter_ = y (\self : matchList
(\_ : t) (\_ : t)
(\head tail f : matchBool (t head) i (f head) (self tail f))) (\head tail f : matchBool (t head) i (f head) (self tail f)))
filter = (\f l : filter_ l f) filter = \f l : filter_ l f
foldl_ = y (\self f l x : matchList (\acc : acc) (\head tail acc : self f tail (f acc head)) l x) foldl_ = y (\self f l x : matchList (\acc : acc) (\head tail acc : self f tail (f acc head)) l x)
foldl = (\f x l : foldl_ f l x) foldl = \f x l : foldl_ f l x
foldr_ = y (\self x f l : matchList x (\head tail : f (self x f tail) head) l) foldr_ = y (\self x f l : matchList x (\head tail : f (self x f tail) head) l)
foldr = (\f x l : foldr_ x f l) foldr = \f x l : foldr_ x f l

163
src/Eval.hs
View File

@ -3,32 +3,42 @@ module Eval where
import Parser import Parser
import Research import Research
import Data.List (partition, (\\))
import Data.Map (Map) import Data.Map (Map)
import qualified Data.Map as Map import qualified Data.Map as Map
import qualified Data.Set as Set import qualified Data.Set as Set
evalSingle :: Env -> TricuAST -> Env evalSingle :: Env -> TricuAST -> Env
evalSingle env term evalSingle env term
| SFunc name [] body <- term = | SDef name [] body <- term
= case Map.lookup name env of
Just existingValue
| existingValue == evalAST env body -> env
| otherwise -> errorWithoutStackTrace $
"Unable to rebind immutable identifier: '" ++ name
Nothing ->
let res = evalAST env body let res = evalAST env body
in Map.insert "__result" res (Map.insert name res env) in Map.insert "!result" res (Map.insert name res env)
| SApp func arg <- term = | SApp func arg <- term
let res = apply (evalAST env func) (evalAST env arg) = let res = apply (evalAST env func) (evalAST env arg)
in Map.insert "__result" res env in Map.insert "!result" res env
| SVar name <- term = | SVar name <- term
case Map.lookup name env of = case Map.lookup name env of
Just v -> Map.insert "__result" v env Just v -> Map.insert "!result" v env
Nothing -> errorWithoutStackTrace $ "Variable " ++ name ++ " not defined" Nothing ->
| otherwise = errorWithoutStackTrace $ "Variable `" ++ name ++ "` not defined\n\
Map.insert "__result" (evalAST env term) env \This error should never occur here. Please report this as an issue."
| otherwise
= Map.insert "!result" (evalAST env term) env
evalTricu :: Env -> [TricuAST] -> Env evalTricu :: Env -> [TricuAST] -> Env
evalTricu env [] = env evalTricu env x = go env (reorderDefs env x)
evalTricu env [x] = where
go env [] = env
go env [x] =
let updatedEnv = evalSingle env x let updatedEnv = evalSingle env x
in Map.insert "__result" (result updatedEnv) updatedEnv in Map.insert "!result" (result updatedEnv) updatedEnv
evalTricu env (x:xs) = go env (x:xs) =
evalTricu (evalSingle env x) xs evalTricu (evalSingle env x) xs
evalAST :: Env -> TricuAST -> T evalAST :: Env -> TricuAST -> T
@ -49,11 +59,24 @@ evalAST env term
(errorWithoutStackTrace $ "Variable " ++ name ++ " not defined") (errorWithoutStackTrace $ "Variable " ++ name ++ " not defined")
name env name env
-- https://github.com/barry-jay-personal/typed_tree_calculus/blob/main/typed_program_analysis.pdf
-- Chapter 4: Lambda-Abstraction
elimLambda :: TricuAST -> TricuAST elimLambda :: TricuAST -> TricuAST
elimLambda = go elimLambda = go
where where
-- η-reduction
go (SLambda [v] (SApp f (SVar x)))
| v == x && not (isFree v f) = elimLambda f
-- Triage optimization
go (SLambda [a] (SLambda [b] (SLambda [c] body)))
| body == triageBody = _TRIAGE
where
triageBody =
(SApp (SApp TLeaf (SApp (SApp TLeaf (SVar a)) (SVar b))) (SVar c))
-- Composition optimization
go (SLambda [f] (SLambda [g] (SLambda [x] body)))
| body == composeBody = _COMPOSE
where
composeBody = SApp (SVar f) (SApp (SVar g) (SVar x))
-- General elimination
go (SLambda (v:vs) body) go (SLambda (v:vs) body)
| null vs = toSKI v (elimLambda body) | null vs = toSKI v (elimLambda body)
| otherwise = elimLambda (SLambda [v] (SLambda vs body)) | otherwise = elimLambda (SLambda [v] (SLambda vs body))
@ -68,25 +91,101 @@ elimLambda = go
| otherwise = SApp (SApp _S (toSKI x n)) (toSKI x u) | otherwise = SApp (SApp _S (toSKI x n)) (toSKI x u)
toSKI x t toSKI x t
| not (isFree x t) = SApp _K t | not (isFree x t) = SApp _K t
| otherwise = SApp (SApp _S (toSKI x t)) TLeaf | otherwise = errorWithoutStackTrace "Unhandled toSKI conversion"
_S = parseSingle "t (t (t t t)) t" _S = parseSingle "t (t (t t t)) t"
_K = parseSingle "t t" _K = parseSingle "t t"
_I = parseSingle "t (t (t t)) t" _I = parseSingle "t (t (t t)) t"
_TRIAGE = parseSingle "t (t (t t (t (t (t t t))))) t"
_COMPOSE = parseSingle "t (t (t t (t (t (t t t)) t))) (t t)"
isFree x = Set.member x . freeVars isFree :: String -> TricuAST -> Bool
freeVars (SVar v ) = Set.singleton v isFree x = Set.member x . freeVars
freeVars (SInt _ ) = Set.empty
freeVars (SStr _ ) = Set.empty freeVars :: TricuAST -> Set.Set String
freeVars (SList s ) = foldMap freeVars s freeVars (SVar v ) = Set.singleton v
freeVars (SApp f a ) = freeVars f <> freeVars a freeVars (SInt _ ) = Set.empty
freeVars (TLeaf ) = Set.empty freeVars (SStr _ ) = Set.empty
freeVars (SFunc _ _ b) = freeVars b freeVars (SList s ) = foldMap freeVars s
freeVars (TStem t ) = freeVars t freeVars (SApp f a ) = freeVars f <> freeVars a
freeVars (TFork l r ) = freeVars l <> freeVars r freeVars (TLeaf ) = Set.empty
freeVars (SLambda v b ) = foldr Set.delete (freeVars b) v freeVars (SDef _ _ b) = freeVars b
freeVars (TStem t ) = freeVars t
freeVars (TFork l r ) = freeVars l <> freeVars r
freeVars (SLambda v b ) = foldr Set.delete (freeVars b) v
freeVars _ = Set.empty
reorderDefs :: Env -> [TricuAST] -> [TricuAST]
reorderDefs env defs
| not (null missingDeps) =
errorWithoutStackTrace $
"Missing dependencies detected: " ++ show missingDeps
| otherwise = orderedDefs ++ others
where
(defsOnly, others) = partition isDef defs
defNames = [ name | SDef name _ _ <- defsOnly ]
defsWithFreeVars = [(def, freeVars body) | def@(SDef _ _ body) <- defsOnly]
graph = buildDepGraph defsOnly
sortedDefs = sortDeps graph
defMap = Map.fromList [(name, def) | def@(SDef name _ _) <- defsOnly]
orderedDefs = map (\name -> defMap Map.! name) sortedDefs
freeVarsDefs = foldMap snd defsWithFreeVars
freeVarsOthers = foldMap freeVars others
allFreeVars = freeVarsDefs <> freeVarsOthers
validNames = Set.fromList defNames `Set.union` Set.fromList (Map.keys env)
missingDeps = Set.toList (allFreeVars `Set.difference` validNames)
isDef (SDef _ _ _) = True
isDef _ = False
buildDepGraph :: [TricuAST] -> Map.Map String (Set.Set String)
buildDepGraph topDefs
| not (null duplicateNames) =
errorWithoutStackTrace $
"Duplicate definitions detected: " ++ show duplicateNames
| otherwise =
Map.fromList
[ (name, depends topDefs (SDef name [] body))
| SDef name _ body <- topDefs]
where
names = [name | SDef name _ _ <- topDefs]
duplicateNames =
[ name | (name, count) <- Map.toList (countOccurrences names) , count > 1]
countOccurrences = foldr (\x -> Map.insertWith (+) x 1) Map.empty
sortDeps :: Map.Map String (Set.Set String) -> [String]
sortDeps graph = go [] Set.empty (Map.keys graph)
where
go sorted sortedSet [] = sorted
go sorted sortedSet remaining =
let ready = [ name | name <- remaining
, let deps = Map.findWithDefault Set.empty name graph
, Set.isSubsetOf deps sortedSet ]
notReady = remaining \\ ready
in if null ready
then errorWithoutStackTrace
"ERROR: Cyclic dependency detected and prohibited.\n\
\RESOLVE: Use nested lambdas."
else go (sorted ++ ready)
(Set.union sortedSet (Set.fromList ready))
notReady
depends :: [TricuAST] -> TricuAST -> Set.Set String
depends topDefs (SDef _ _ body) =
Set.intersection
(Set.fromList [n | SDef n _ _ <- topDefs])
(freeVars body)
depends _ _ = Set.empty
result :: Env -> T result :: Env -> T
result r = case Map.lookup "__result" r of result r = case Map.lookup "!result" r of
Just a -> a Just a -> a
Nothing -> errorWithoutStackTrace "No __result field found in provided environment" Nothing -> errorWithoutStackTrace "No !result field found in provided env"
mainResult :: Env -> T
mainResult r = case Map.lookup "main" r of
Just a -> a
Nothing -> errorWithoutStackTrace "No valid definition for `main` found."

136
src/FileEval.hs
View File

@ -1,30 +1,150 @@
module FileEval where module FileEval where
import Eval import Eval
import Lexer
import Parser import Parser
import Research import Research
import Data.List (partition)
import Control.Monad (foldM)
import System.IO import System.IO
import qualified Data.Map as Map import qualified Data.Map as Map
import qualified Data.Set as Set
evaluateFileResult :: FilePath -> IO T evaluateFileResult :: FilePath -> IO T
evaluateFileResult filePath = do evaluateFileResult filePath = do
contents <- readFile filePath contents <- readFile filePath
let asts = parseTricu contents let tokens = lexTricu contents
let finalEnv = evalTricu Map.empty asts let moduleName = case parseProgram tokens of
case Map.lookup "__result" finalEnv of Right ((SModule name) : _) -> name
_ -> ""
case parseProgram tokens of
Left err -> errorWithoutStackTrace (handleParseError err)
Right _ -> do
ast <- preprocessFile filePath
let finalEnv = mainAlias moduleName $ evalTricu Map.empty ast
case Map.lookup "main" finalEnv of
Just finalResult -> return finalResult Just finalResult -> return finalResult
Nothing -> errorWithoutStackTrace "No expressions to evaluate found" Nothing -> errorWithoutStackTrace "No `main` function detected"
evaluateFile :: FilePath -> IO Env evaluateFile :: FilePath -> IO Env
evaluateFile filePath = do evaluateFile filePath = do
contents <- readFile filePath contents <- readFile filePath
let asts = parseTricu contents let tokens = lexTricu contents
pure $ evalTricu Map.empty asts let moduleName = case parseProgram tokens of
Right ((SModule name) : _) -> name
_ -> ""
case parseProgram tokens of
Left err -> errorWithoutStackTrace (handleParseError err)
Right _ -> do
ast <- preprocessFile filePath
pure $ mainAlias moduleName $ evalTricu Map.empty ast
evaluateFileWithContext :: Env -> FilePath -> IO Env evaluateFileWithContext :: Env -> FilePath -> IO Env
evaluateFileWithContext env filePath = do evaluateFileWithContext env filePath = do
contents <- readFile filePath contents <- readFile filePath
let asts = parseTricu contents let tokens = lexTricu contents
pure $ evalTricu env asts let moduleName = case parseProgram tokens of
Right ((SModule name) : _) -> name
_ -> ""
case parseProgram tokens of
Left err -> errorWithoutStackTrace (handleParseError err)
Right _ -> do
ast <- preprocessFile filePath
pure $ mainAlias moduleName $ evalTricu env ast
mainAlias :: String -> Env -> Env
mainAlias "" env = env
mainAlias moduleName env =
case Map.lookup (moduleName ++ ".main") env of
Just value -> Map.insert "main" value env
Nothing -> env
preprocessFile :: FilePath -> IO [TricuAST]
preprocessFile filePath = preprocessFile' Set.empty filePath
preprocessFile' :: Set.Set FilePath -> FilePath -> IO [TricuAST]
preprocessFile' inProgress filePath
| filePath `Set.member` inProgress =
errorWithoutStackTrace $ "Encountered cyclic import: " ++ filePath
| otherwise = do
contents <- readFile filePath
let tokens = lexTricu contents
case parseProgram tokens of
Left err -> errorWithoutStackTrace (handleParseError err)
Right asts -> do
let (moduleName, restAST) = extractModule asts
let (imports, nonImports) = partition isImport restAST
let newInProgress = Set.insert filePath inProgress
importedASTs <- concat <$> mapM (processImport newInProgress) imports
let namespacedAST = namespaceDefinitions moduleName nonImports
pure $ importedASTs ++ namespacedAST
where
extractModule :: [TricuAST] -> (String, [TricuAST])
extractModule ((SModule name) : xs) = (name, xs)
extractModule xs = ("", xs)
isImport :: TricuAST -> Bool
isImport (SImport _ _) = True
isImport _ = False
processImport :: Set.Set FilePath -> TricuAST -> IO [TricuAST]
processImport inProgress (SImport filePath moduleName) = do
importedAST <- preprocessFile' inProgress filePath
pure $ namespaceDefinitions moduleName importedAST
processImport _ _ = error "Unexpected non-import in processImport"
namespaceDefinitions :: String -> [TricuAST] -> [TricuAST]
namespaceDefinitions moduleName = map (namespaceDefinition moduleName)
namespaceDefinition :: String -> TricuAST -> TricuAST
namespaceDefinition "" def = def
namespaceDefinition moduleName (SDef name args body)
| isPrefixed name = SDef name args (namespaceBody moduleName body)
| otherwise = SDef (namespaceVariable moduleName name)
args (namespaceBody moduleName body)
namespaceDefinition moduleName other =
namespaceBody moduleName other
namespaceBody :: String -> TricuAST -> TricuAST
namespaceBody moduleName (SVar name)
| isPrefixed name = SVar name
| otherwise = SVar (namespaceVariable moduleName name)
namespaceBody moduleName (SApp func arg) =
SApp (namespaceBody moduleName func) (namespaceBody moduleName arg)
namespaceBody moduleName (SLambda args body) =
SLambda args (namespaceBodyScoped moduleName args body)
namespaceBody moduleName (SList items) =
SList (map (namespaceBody moduleName) items)
namespaceBody moduleName (TFork left right) =
TFork (namespaceBody moduleName left) (namespaceBody moduleName right)
namespaceBody moduleName (TStem subtree) =
TStem (namespaceBody moduleName subtree)
namespaceBody moduleName (SDef name args body)
| isPrefixed name = SDef name args (namespaceBody moduleName body)
| otherwise = SDef (namespaceVariable moduleName name)
args (namespaceBody moduleName body)
namespaceBody _ other = other
namespaceBodyScoped :: String -> [String] -> TricuAST -> TricuAST
namespaceBodyScoped moduleName args body = case body of
SVar name ->
if name `elem` args
then SVar name
else namespaceBody moduleName (SVar name)
SApp func arg -> SApp (namespaceBodyScoped moduleName args func) (namespaceBodyScoped moduleName args arg)
SLambda innerArgs innerBody -> SLambda innerArgs (namespaceBodyScoped moduleName (args ++ innerArgs) innerBody)
SList items -> SList (map (namespaceBodyScoped moduleName args) items)
TFork left right -> TFork (namespaceBodyScoped moduleName args left) (namespaceBodyScoped moduleName args right)
TStem subtree -> TStem (namespaceBodyScoped moduleName args subtree)
SDef name innerArgs innerBody ->
SDef (namespaceVariable moduleName name) innerArgs (namespaceBodyScoped moduleName (args ++ innerArgs) innerBody)
other -> other
isPrefixed :: String -> Bool
isPrefixed name = '.' `elem` name
namespaceVariable :: String -> String -> String
namespaceVariable "" name = name
namespaceVariable moduleName name = moduleName ++ "." ++ name

32
src/Lexer.hs
View File

@ -20,11 +20,11 @@ identifier = do
first <- letterChar <|> char '_' first <- letterChar <|> char '_'
rest <- many $ letterChar rest <- many $ letterChar
<|> digitChar <|> digitChar
<|> char '_' <|> char '-' <|> char '?' <|> char '!' <|> char '_' <|> char '-' <|> char '?' <|> char '.'
<|> char '$' <|> char '#' <|> char '@' <|> char '%' <|> char '$' <|> char '#' <|> char '@' <|> char '%'
let name = first : rest let name = first : rest
if (name == "t" || name == "__result") if (name == "t" || name == "!result")
then fail "Keywords (`t`, `__result`) cannot be used as an identifier" then fail "Keywords (`t`, `!result`) cannot be used as an identifier"
else return (LIdentifier name) else return (LIdentifier name)
integerLiteral :: Lexer LToken integerLiteral :: Lexer LToken
@ -39,6 +39,22 @@ stringLiteral = do
char '"' --" char '"' --"
return (LStringLiteral content) return (LStringLiteral content)
lModule :: Lexer LToken
lModule = do
_ <- string "!module"
space1
LIdentifier moduleName <- identifier
return (LModule moduleName)
lImport :: Lexer LToken
lImport = do
_ <- string "!import"
space1
LStringLiteral path <- stringLiteral
space1
LIdentifier name <- identifier
return (LImport path name)
assign :: Lexer LToken assign :: Lexer LToken
assign = char '=' *> pure LAssign assign = char '=' *> pure LAssign
@ -72,13 +88,21 @@ sc = space
tricuLexer :: Lexer [LToken] tricuLexer :: Lexer [LToken]
tricuLexer = do tricuLexer = do
sc sc
header <- many $ do
tok <- choice
[ try lModule
, try lImport
, lnewline
]
sc
pure tok
tokens <- many $ do tokens <- many $ do
tok <- choice tricuLexer' tok <- choice tricuLexer'
sc sc
pure tok pure tok
sc sc
eof eof
pure tokens pure (header ++ tokens)
where where
tricuLexer' = tricuLexer' =
[ try lnewline [ try lnewline

18
src/Main.hs
View File

@ -1,6 +1,6 @@
module Main where module Main where
import Eval (evalTricu, result) import Eval (evalTricu, mainResult, result)
import FileEval import FileEval
import Parser (parseTricu) import Parser (parseTricu)
import REPL import REPL
@ -16,7 +16,7 @@ import qualified Data.Map as Map
data TricuArgs data TricuArgs
= Repl = Repl
| Evaluate { file :: [FilePath], form :: EvaluatedForm } | Evaluate { file :: [FilePath], form :: EvaluatedForm }
| Decode { file :: [FilePath] } | TDecode { file :: [FilePath] }
deriving (Show, Data, Typeable) deriving (Show, Data, Typeable)
replMode :: TricuArgs replMode :: TricuArgs
@ -31,7 +31,7 @@ evaluateMode = Evaluate
\ Defaults to stdin." \ Defaults to stdin."
&= name "f" &= typ "FILE" &= name "f" &= typ "FILE"
, form = TreeCalculus &= typ "FORM" , form = TreeCalculus &= typ "FORM"
&= help "Optional output form: (tree|fsl|ast|ternary|ascii).\n \ &= help "Optional output form: (tree|fsl|ast|ternary|ascii|decode).\n \
\ Defaults to tricu-compatible `t` tree form." \ Defaults to tricu-compatible `t` tree form."
&= name "t" &= name "t"
} }
@ -40,7 +40,7 @@ evaluateMode = Evaluate
&= name "eval" &= name "eval"
decodeMode :: TricuArgs decodeMode :: TricuArgs
decodeMode = Decode decodeMode = TDecode
{ file = def { file = def
&= help "Optional input file path to attempt decoding.\n \ &= help "Optional input file path to attempt decoding.\n \
\ Defaults to stdin." \ Defaults to stdin."
@ -60,8 +60,7 @@ main = do
Repl -> do Repl -> do
putStrLn "Welcome to the tricu REPL" putStrLn "Welcome to the tricu REPL"
putStrLn "You can exit with `CTRL+D` or the `:_exit` command.`" putStrLn "You can exit with `CTRL+D` or the `:_exit` command.`"
library <- liftIO $ evaluateFile "./lib/base.tri" repl Map.empty
repl $ Map.delete "__result" library
Evaluate { file = filePaths, form = form } -> do Evaluate { file = filePaths, form = form } -> do
result <- case filePaths of result <- case filePaths of
[] -> do [] -> do
@ -70,15 +69,14 @@ main = do
(filePath:restFilePaths) -> do (filePath:restFilePaths) -> do
initialEnv <- evaluateFile filePath initialEnv <- evaluateFile filePath
finalEnv <- foldM evaluateFileWithContext initialEnv restFilePaths finalEnv <- foldM evaluateFileWithContext initialEnv restFilePaths
pure $ result finalEnv pure $ mainResult finalEnv
let fRes = formatResult form result let fRes = formatResult form result
putStr fRes putStr fRes
Decode { file = filePaths } -> do TDecode { file = filePaths } -> do
value <- case filePaths of value <- case filePaths of
[] -> getContents [] -> getContents
(filePath:_) -> readFile filePath (filePath:_) -> readFile filePath
library <- liftIO $ evaluateFile "./lib/base.tri" putStrLn $ decodeResult $ result $ evalTricu Map.empty $ parseTricu value
putStrLn $ decodeResult $ result $ evalTricu library $ parseTricu value
runTricu :: String -> T runTricu :: String -> T
runTricu input = runTricu input =

108
src/Parser.hs
View File

@ -74,9 +74,33 @@ parseSingle input =
parseProgramM :: ParserM [TricuAST] parseProgramM :: ParserM [TricuAST]
parseProgramM = do parseProgramM = do
skipMany topLevelNewline skipMany topLevelNewline
moduleNode <- optional parseModuleM
skipMany topLevelNewline
importNodes <- many (do
node <- parseImportM
skipMany topLevelNewline
return node)
skipMany topLevelNewline
exprs <- sepEndBy parseOneExpression (some topLevelNewline) exprs <- sepEndBy parseOneExpression (some topLevelNewline)
skipMany topLevelNewline skipMany topLevelNewline
return exprs return (maybe [] (: []) moduleNode ++ importNodes ++ exprs)
parseModuleM :: ParserM TricuAST
parseModuleM = do
LModule moduleName <- satisfyM isModule
pure (SModule moduleName)
where
isModule (LModule _) = True
isModule _ = False
parseImportM :: ParserM TricuAST
parseImportM = do
LImport filePath moduleName <- satisfyM isImport
pure (SImport filePath moduleName)
where
isImport (LImport _ _) = True
isImport _ = False
parseOneExpression :: ParserM TricuAST parseOneExpression :: ParserM TricuAST
parseOneExpression = scnParserM *> parseExpressionM parseOneExpression = scnParserM *> parseExpressionM
@ -85,13 +109,10 @@ scnParserM :: ParserM ()
scnParserM = skipMany $ do scnParserM = skipMany $ do
t <- lookAhead anySingle t <- lookAhead anySingle
st <- get st <- get
if | (parenDepth st > 0 || bracketDepth st > 0) && case t of if | (parenDepth st > 0 || bracketDepth st > 0) && (t == LNewline) ->
LNewline -> True void $ satisfyM (== LNewline)
_ -> False -> void $ satisfyM $ \case | otherwise ->
LNewline -> True fail "In nested context or no space token" <|> empty
_ -> False
| otherwise -> fail "In nested context or no space token" <|> empty
eofM :: ParserM () eofM :: ParserM ()
eofM = lift eof eofM = lift eof
@ -109,32 +130,23 @@ parseExpressionM = choice
parseFunctionM :: ParserM TricuAST parseFunctionM :: ParserM TricuAST
parseFunctionM = do parseFunctionM = do
LIdentifier name <- satisfyM $ \case let ident = (\case LIdentifier _ -> True; _ -> False)
LIdentifier _ -> True LIdentifier name <- satisfyM ident
_ -> False args <- many $ satisfyM ident
args <- many $ satisfyM $ \case
LIdentifier _ -> True
_ -> False
_ <- satisfyM (== LAssign) _ <- satisfyM (== LAssign)
scnParserM scnParserM
body <- parseExpressionM body <- parseExpressionM
pure (SFunc name (map getIdentifier args) body) pure (SDef name (map getIdentifier args) body)
parseLambdaM :: ParserM TricuAST parseLambdaM :: ParserM TricuAST
parseLambdaM = parseLambdaM = do
between (satisfyM (== LOpenParen)) (satisfyM (== LCloseParen)) $ do let ident = (\case LIdentifier _ -> True; _ -> False)
_ <- satisfyM (== LBackslash) _ <- satisfyM (== LBackslash)
param <- satisfyM $ \case params <- some (satisfyM ident)
LIdentifier _ -> True
_ -> False
rest <- many $ satisfyM $ \case
LIdentifier _ -> True
_ -> False
_ <- satisfyM (== LColon) _ <- satisfyM (== LColon)
scnParserM scnParserM
body <- parseLambdaExpressionM body <- parseLambdaExpressionM
let nested = foldr (\v acc -> SLambda [getIdentifier v] acc) body rest pure $ foldr (\param acc -> SLambda [getIdentifier param] acc) body params
pure (SLambda [getIdentifier param] nested)
parseLambdaExpressionM :: ParserM TricuAST parseLambdaExpressionM :: ParserM TricuAST
parseLambdaExpressionM = choice parseLambdaExpressionM = choice
@ -180,9 +192,8 @@ parseAtomicBaseM = choice
parseTreeLeafM :: ParserM TricuAST parseTreeLeafM :: ParserM TricuAST
parseTreeLeafM = do parseTreeLeafM = do
_ <- satisfyM $ \case let keyword = (\case LKeywordT -> True; _ -> False)
LKeywordT -> True _ <- satisfyM keyword
_ -> False
notFollowedBy $ lift $ satisfy (== LAssign) notFollowedBy $ lift $ satisfy (== LAssign)
pure TLeaf pure TLeaf
@ -248,37 +259,38 @@ parseGroupedItemM = do
parseSingleItemM :: ParserM TricuAST parseSingleItemM :: ParserM TricuAST
parseSingleItemM = do parseSingleItemM = do
token <- satisfyM $ \case token <- satisfyM (\case LIdentifier _ -> True; LKeywordT -> True; _ -> False)
LIdentifier _ -> True if | LIdentifier name <- token -> pure (SVar name)
LKeywordT -> True | token == LKeywordT -> pure TLeaf
_ -> False | otherwise -> fail "Unexpected token in list item"
case token of
LIdentifier name -> pure (SVar name)
LKeywordT -> pure TLeaf
_ -> fail "Unexpected token in list item"
parseVarM :: ParserM TricuAST parseVarM :: ParserM TricuAST
parseVarM = do parseVarM = do
LIdentifier name <- satisfyM $ \case satisfyM (\case LIdentifier _ -> True; _ -> False) >>= \case
LIdentifier _ -> True LIdentifier name
_ -> False | name == "t" || name == "!result" ->
if name == "t" || name == "__result" fail ("Reserved keyword: " ++ name ++ " cannot be assigned.")
then fail ("Reserved keyword: " ++ name ++ " cannot be assigned.") | otherwise ->
else pure (SVar name) pure (SVar name)
_ -> fail "Unexpected token while parsing variable"
parseIntLiteralM :: ParserM TricuAST parseIntLiteralM :: ParserM TricuAST
parseIntLiteralM = do parseIntLiteralM = do
LIntegerLiteral value <- satisfyM $ \case let intL = (\case LIntegerLiteral _ -> True; _ -> False)
LIntegerLiteral _ -> True token <- satisfyM intL
_ -> False if | LIntegerLiteral value <- token ->
pure (SInt value) pure (SInt value)
| otherwise ->
fail "Unexpected token while parsing integer literal"
parseStrLiteralM :: ParserM TricuAST parseStrLiteralM :: ParserM TricuAST
parseStrLiteralM = do parseStrLiteralM = do
LStringLiteral value <- satisfyM $ \case let strL = (\case LStringLiteral _ -> True; _ -> False)
LStringLiteral _ -> True token <- satisfyM strL
_ -> False if | LStringLiteral value <- token ->
pure (SStr value) pure (SStr value)
| otherwise ->
fail "Unexpected token while parsing string literal"
getIdentifier :: LToken -> String getIdentifier :: LToken -> String
getIdentifier (LIdentifier name) = name getIdentifier (LIdentifier name) = name

13
src/REPL.hs
View File

@ -26,7 +26,7 @@ repl env = runInputT defaultSettings (loop env)
| Just s <- minput, strip s == "" -> do | Just s <- minput, strip s == "" -> do
outputStrLn "" outputStrLn ""
loop env loop env
| Just s <- minput, strip s == "!load" -> do | Just s <- minput, strip s == "!import" -> do
path <- getInputLine "File path to load < " path <- getInputLine "File path to load < "
if if
| Nothing <- path -> do | Nothing <- path -> do
@ -34,7 +34,7 @@ repl env = runInputT defaultSettings (loop env)
loop env loop env
| Just p <- path -> do | Just p <- path -> do
loadedEnv <- liftIO $ evaluateFileWithContext env (strip p) `catch` \e -> errorHandler env e loadedEnv <- liftIO $ evaluateFileWithContext env (strip p) `catch` \e -> errorHandler env e
loop $ Map.delete "__result" (Map.union loadedEnv env) loop $ Map.delete "!result" (Map.union loadedEnv env)
| Just s <- minput -> do | Just s <- minput -> do
if if
| take 2 s == "--" -> loop env | take 2 s == "--" -> loop env
@ -47,7 +47,7 @@ repl env = runInputT defaultSettings (loop env)
let asts = parseTricu input let asts = parseTricu input
newEnv = evalTricu env asts newEnv = evalTricu env asts
if if
| Just r <- Map.lookup "__result" newEnv -> do | Just r <- Map.lookup "!result" newEnv -> do
putStrLn $ "tricu > " ++ decodeResult r putStrLn $ "tricu > " ++ decodeResult r
| otherwise -> return () | otherwise -> return ()
return newEnv return newEnv
@ -59,10 +59,3 @@ repl env = runInputT defaultSettings (loop env)
strip :: String -> String strip :: String -> String
strip = dropWhileEnd isSpace . dropWhile isSpace strip = dropWhileEnd isSpace . dropWhile isSpace
decodeResult :: T -> String
decodeResult tc
| Right num <- toNumber tc = show num
| Right str <- toString tc = "\"" ++ str ++ "\""
| Right list <- toList tc = "[" ++ intercalate ", " (map decodeResult list) ++ "]"
| otherwise = formatResult TreeCalculus tc

16
src/Research.hs
View File

@ -19,13 +19,15 @@ data TricuAST
| SInt Int | SInt Int
| SStr String | SStr String
| SList [TricuAST] | SList [TricuAST]
| SFunc String [String] TricuAST | SDef String [String] TricuAST
| SApp TricuAST TricuAST | SApp TricuAST TricuAST
| TLeaf | TLeaf
| TStem TricuAST | TStem TricuAST
| TFork TricuAST TricuAST | TFork TricuAST TricuAST
| SLambda [String] TricuAST | SLambda [String] TricuAST
| SEmpty | SEmpty
| SModule String
| SImport String String
deriving (Show, Eq, Ord) deriving (Show, Eq, Ord)
-- Lexer Tokens -- Lexer Tokens
@ -42,10 +44,12 @@ data LToken
| LOpenBracket | LOpenBracket
| LCloseBracket | LCloseBracket
| LNewline | LNewline
| LModule String
| LImport String String
deriving (Show, Eq, Ord) deriving (Show, Eq, Ord)
-- Output formats -- Output formats
data EvaluatedForm = TreeCalculus | FSL | AST | Ternary | Ascii data EvaluatedForm = TreeCalculus | FSL | AST | Ternary | Ascii | Decode
deriving (Show, Data, Typeable) deriving (Show, Data, Typeable)
-- Environment containing previously evaluated TC terms -- Environment containing previously evaluated TC terms
@ -115,6 +119,7 @@ formatResult FSL = show
formatResult AST = show . toAST formatResult AST = show . toAST
formatResult Ternary = toTernaryString formatResult Ternary = toTernaryString
formatResult Ascii = toAscii formatResult Ascii = toAscii
formatResult Decode = decodeResult
toSimpleT :: String -> String toSimpleT :: String -> String
toSimpleT s = T.unpack toSimpleT s = T.unpack
@ -147,4 +152,9 @@ toAscii tree = go tree "" True
++ go left (prefix ++ (if isLast then " " else "| ")) False ++ go left (prefix ++ (if isLast then " " else "| ")) False
++ go right (prefix ++ (if isLast then " " else "| ")) True ++ go right (prefix ++ (if isLast then " " else "| ")) True
-- Utility decodeResult :: T -> String
decodeResult tc
| Right num <- toNumber tc = show num
| Right str <- toString tc = "\"" ++ str ++ "\""
| Right list <- toList tc = "[" ++ intercalate ", " (map decodeResult list) ++ "]"
| otherwise = formatResult TreeCalculus tc

200
test/Spec.hs
View File

@ -9,6 +9,7 @@ import Research
import Control.Exception (evaluate, try, SomeException) import Control.Exception (evaluate, try, SomeException)
import Control.Monad.IO.Class (liftIO) import Control.Monad.IO.Class (liftIO)
import Data.List (isInfixOf)
import Test.Tasty import Test.Tasty
import Test.Tasty.HUnit import Test.Tasty.HUnit
import Test.Tasty.QuickCheck import Test.Tasty.QuickCheck
@ -25,180 +26,217 @@ runTricu s = show $ result (evalTricu Map.empty $ parseTricu s)
tests :: TestTree tests :: TestTree
tests = testGroup "Tricu Tests" tests = testGroup "Tricu Tests"
[ lexerTests [ lexer
, parserTests , parser
, evaluationTests , simpleEvaluation
, lambdaEvalTests , lambdas
, libraryTests , baseLibrary
, fileEvaluationTests , fileEval
, modules
, demos
] ]
lexerTests :: TestTree lexer :: TestTree
lexerTests = testGroup "Lexer Tests" lexer = testGroup "Lexer Tests"
[ testCase "Lex simple identifiers" $ do [ testCase "Lex simple identifiers" $ do
let input = "x a b = a" let input = "x a b = a"
expect = Right [LIdentifier "x", LIdentifier "a", LIdentifier "b", LAssign, LIdentifier "a"] expect = Right [LIdentifier "x", LIdentifier "a", LIdentifier "b", LAssign, LIdentifier "a"]
runParser tricuLexer "" input @?= expect runParser tricuLexer "" input @?= expect
, testCase "Lex Tree Calculus terms" $ do , testCase "Lex Tree Calculus terms" $ do
let input = "t t t" let input = "t t t"
expect = Right [LKeywordT, LKeywordT, LKeywordT] expect = Right [LKeywordT, LKeywordT, LKeywordT]
runParser tricuLexer "" input @?= expect runParser tricuLexer "" input @?= expect
, testCase "Lex escaped characters in strings" $ do , testCase "Lex escaped characters in strings" $ do
let input = "\"hello\\nworld\"" let input = "\"hello\\nworld\""
expect = Right [LStringLiteral "hello\\nworld"] expect = Right [LStringLiteral "hello\\nworld"]
runParser tricuLexer "" input @?= expect runParser tricuLexer "" input @?= expect
, testCase "Lex mixed literals" $ do , testCase "Lex mixed literals" $ do
let input = "t \"string\" 42" let input = "t \"string\" 42"
expect = Right [LKeywordT, LStringLiteral "string", LIntegerLiteral 42] expect = Right [LKeywordT, LStringLiteral "string", LIntegerLiteral 42]
runParser tricuLexer "" input @?= expect runParser tricuLexer "" input @?= expect
, testCase "Lex invalid token" $ do , testCase "Lex invalid token" $ do
let input = "&invalid" let input = "&invalid"
case runParser tricuLexer "" input of case runParser tricuLexer "" input of
Left _ -> return () Left _ -> return ()
Right _ -> assertFailure "Expected lexer to fail on invalid token" Right _ -> assertFailure "Expected lexer to fail on invalid token"
, testCase "Drop trailing whitespace in definitions" $ do , testCase "Drop trailing whitespace in definitions" $ do
let input = "x = 5 " let input = "x = 5 "
expect = [LIdentifier "x",LAssign,LIntegerLiteral 5] expect = [LIdentifier "x",LAssign,LIntegerLiteral 5]
case (runParser tricuLexer "" input) of case (runParser tricuLexer "" input) of
Left _ -> assertFailure "Failed to lex input" Left _ -> assertFailure "Failed to lex input"
Right i -> i @?= expect Right i -> i @?= expect
, testCase "Error when using invalid characters in identifiers" $ do , testCase "Error when using invalid characters in identifiers" $ do
case (runParser tricuLexer "" "__result = 5") of case (runParser tricuLexer "" "!result = 5") of
Left _ -> return () Left _ -> return ()
Right _ -> assertFailure "Expected failure when trying to assign the value of __result" Right _ -> assertFailure "Expected failure when trying to assign the value of !result"
] ]
parserTests :: TestTree parser :: TestTree
parserTests = testGroup "Parser Tests" parser = testGroup "Parser Tests"
[ testCase "Error when assigning a value to T" $ do [ testCase "Error when assigning a value to T" $ do
let tokens = lexTricu "t = x" let tokens = lexTricu "t = x"
case parseSingleExpr tokens of case parseSingleExpr tokens of
Left _ -> return () Left _ -> return ()
Right _ -> assertFailure "Expected failure when trying to assign the value of T" Right _ -> assertFailure "Expected failure when trying to assign the value of T"
, testCase "Parse function definitions" $ do , testCase "Parse function definitions" $ do
let input = "x = (\\a b c : a)" let input = "x = (\\a b c : a)"
expect = SFunc "x" [] (SLambda ["a"] (SLambda ["b"] (SLambda ["c"] (SVar "a")))) expect = SDef "x" [] (SLambda ["a"] (SLambda ["b"] (SLambda ["c"] (SVar "a"))))
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse nested Tree Calculus terms" $ do , testCase "Parse nested Tree Calculus terms" $ do
let input = "t (t t) t" let input = "t (t t) t"
expect = SApp (SApp TLeaf (SApp TLeaf TLeaf)) TLeaf expect = SApp (SApp TLeaf (SApp TLeaf TLeaf)) TLeaf
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse sequential Tree Calculus terms" $ do , testCase "Parse sequential Tree Calculus terms" $ do
let input = "t t t" let input = "t t t"
expect = SApp (SApp TLeaf TLeaf) TLeaf expect = SApp (SApp TLeaf TLeaf) TLeaf
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse mixed list literals" $ do , testCase "Parse mixed list literals" $ do
let input = "[t (\"hello\") t]" let input = "[t (\"hello\") t]"
expect = SList [TLeaf, SStr "hello", TLeaf] expect = SList [TLeaf, SStr "hello", TLeaf]
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse function with applications" $ do , testCase "Parse function with applications" $ do
let input = "f = (\\x : t x)" let input = "f = (\\x : t x)"
expect = SFunc "f" [] (SLambda ["x"] (SApp TLeaf (SVar "x"))) expect = SDef "f" [] (SLambda ["x"] (SApp TLeaf (SVar "x")))
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse nested lists" $ do , testCase "Parse nested lists" $ do
let input = "[t [(t t)]]" let input = "[t [(t t)]]"
expect = SList [TLeaf,SList [SApp TLeaf TLeaf]] expect = SList [TLeaf,SList [SApp TLeaf TLeaf]]
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse complex parentheses" $ do , testCase "Parse complex parentheses" $ do
let input = "t (t t (t t))" let input = "t (t t (t t))"
expect = SApp TLeaf (SApp (SApp TLeaf TLeaf) (SApp TLeaf TLeaf)) expect = SApp TLeaf (SApp (SApp TLeaf TLeaf) (SApp TLeaf TLeaf))
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse empty list" $ do , testCase "Parse empty list" $ do
let input = "[]" let input = "[]"
expect = SList [] expect = SList []
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse multiple nested lists" $ do , testCase "Parse multiple nested lists" $ do
let input = "[[t t] [t (t t)]]" let input = "[[t t] [t (t t)]]"
expect = SList [SList [TLeaf,TLeaf],SList [TLeaf,SApp TLeaf TLeaf]] expect = SList [SList [TLeaf,TLeaf],SList [TLeaf,SApp TLeaf TLeaf]]
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse whitespace variance" $ do , testCase "Parse whitespace variance" $ do
let input1 = "[t t]" let input1 = "[t t]"
let input2 = "[ t t ]" let input2 = "[ t t ]"
expect = SList [TLeaf, TLeaf] expect = SList [TLeaf, TLeaf]
parseSingle input1 @?= expect parseSingle input1 @?= expect
parseSingle input2 @?= expect parseSingle input2 @?= expect
, testCase "Parse string in list" $ do , testCase "Parse string in list" $ do
let input = "[(\"hello\")]" let input = "[(\"hello\")]"
expect = SList [SStr "hello"] expect = SList [SStr "hello"]
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse parentheses inside list" $ do , testCase "Parse parentheses inside list" $ do
let input = "[t (t t)]" let input = "[t (t t)]"
expect = SList [TLeaf,SApp TLeaf TLeaf] expect = SList [TLeaf,SApp TLeaf TLeaf]
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse nested parentheses in function body" $ do , testCase "Parse nested parentheses in function body" $ do
let input = "f = (\\x : t (t (t t)))" let input = "f = (\\x : t (t (t t)))"
expect = SFunc "f" [] (SLambda ["x"] (SApp TLeaf (SApp TLeaf (SApp TLeaf TLeaf)))) expect = SDef "f" [] (SLambda ["x"] (SApp TLeaf (SApp TLeaf (SApp TLeaf TLeaf))))
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse lambda abstractions" $ do , testCase "Parse lambda abstractions" $ do
let input = "(\\a : a)" let input = "(\\a : a)"
expect = (SLambda ["a"] (SVar "a")) expect = (SLambda ["a"] (SVar "a"))
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Parse multiple arguments to lambda abstractions" $ do , testCase "Parse multiple arguments to lambda abstractions" $ do
let input = "x = (\\a b : a)" let input = "x = (\\a b : a)"
expect = SFunc "x" [] (SLambda ["a"] (SLambda ["b"] (SVar "a"))) expect = SDef "x" [] (SLambda ["a"] (SLambda ["b"] (SVar "a")))
parseSingle input @?= expect parseSingle input @?= expect
, testCase "Grouping T terms with parentheses in function application" $ do , testCase "Grouping T terms with parentheses in function application" $ do
let input = "x = (\\a : a)\nx (t)" let input = "x = (\\a : a)\nx (t)"
expect = [SFunc "x" [] (SLambda ["a"] (SVar "a")),SApp (SVar "x") TLeaf] expect = [SDef "x" [] (SLambda ["a"] (SVar "a")),SApp (SVar "x") TLeaf]
parseTricu input @?= expect parseTricu input @?= expect
, testCase "Comments 1" $ do , testCase "Comments 1" $ do
let input = "(t) (t) -- (t)" let input = "(t) (t) -- (t)"
expect = [SApp TLeaf TLeaf] expect = [SApp TLeaf TLeaf]
parseTricu input @?= expect parseTricu input @?= expect
, testCase "Comments 2" $ do , testCase "Comments 2" $ do
let input = "(t) -- (t) -- (t)" let input = "(t) -- (t) -- (t)"
expect = [TLeaf] expect = [TLeaf]
parseTricu input @?= expect parseTricu input @?= expect
] ]
evaluationTests :: TestTree simpleEvaluation :: TestTree
evaluationTests = testGroup "Evaluation Tests" simpleEvaluation = testGroup "Evaluation Tests"
[ testCase "Evaluate single Leaf" $ do [ testCase "Evaluate single Leaf" $ do
let input = "t" let input = "t"
let ast = parseSingle input let ast = parseSingle input
(result $ evalSingle Map.empty ast) @?= Leaf (result $ evalSingle Map.empty ast) @?= Leaf
, testCase "Evaluate single Stem" $ do , testCase "Evaluate single Stem" $ do
let input = "t t" let input = "t t"
let ast = parseSingle input let ast = parseSingle input
(result $ evalSingle Map.empty ast) @?= Stem Leaf (result $ evalSingle Map.empty ast) @?= Stem Leaf
, testCase "Evaluate single Fork" $ do , testCase "Evaluate single Fork" $ do
let input = "t t t" let input = "t t t"
let ast = parseSingle input let ast = parseSingle input
(result $ evalSingle Map.empty ast) @?= Fork Leaf Leaf (result $ evalSingle Map.empty ast) @?= Fork Leaf Leaf
, testCase "Evaluate nested Fork and Stem" $ do , testCase "Evaluate nested Fork and Stem" $ do
let input = "t (t t) t" let input = "t (t t) t"
let ast = parseSingle input let ast = parseSingle input
(result $ evalSingle Map.empty ast) @?= Fork (Stem Leaf) Leaf (result $ evalSingle Map.empty ast) @?= Fork (Stem Leaf) Leaf
, testCase "Evaluate `not` function" $ do , testCase "Evaluate `not` function" $ do
let input = "t (t (t t) (t t t)) t" let input = "t (t (t t) (t t t)) t"
let ast = parseSingle input let ast = parseSingle input
(result $ evalSingle Map.empty ast) @?= (result $ evalSingle Map.empty ast) @?=
Fork (Fork (Stem Leaf) (Fork Leaf Leaf)) Leaf Fork (Fork (Stem Leaf) (Fork Leaf Leaf)) Leaf
, testCase "Environment updates with definitions" $ do , testCase "Environment updates with definitions" $ do
let input = "x = t\ny = x" let input = "x = t\ny = x"
env = evalTricu Map.empty (parseTricu input) env = evalTricu Map.empty (parseTricu input)
Map.lookup "x" env @?= Just Leaf Map.lookup "x" env @?= Just Leaf
Map.lookup "y" env @?= Just Leaf Map.lookup "y" env @?= Just Leaf
, testCase "Variable substitution" $ do , testCase "Variable substitution" $ do
let input = "x = t t\ny = t x\ny" let input = "x = t t\ny = t x\ny"
env = evalTricu Map.empty (parseTricu input) env = evalTricu Map.empty (parseTricu input)
(result env) @?= Stem (Stem Leaf) (result env) @?= Stem (Stem Leaf)
, testCase "Multiline input evaluation" $ do , testCase "Multiline input evaluation" $ do
let input = "x = t\ny = t t\nx" let input = "x = t\ny = t t\nx"
env = evalTricu Map.empty (parseTricu input) env = evalTricu Map.empty (parseTricu input)
(result env) @?= Leaf (result env) @?= Leaf
, testCase "Evaluate string literal" $ do , testCase "Evaluate string literal" $ do
let input = "\"hello\"" let input = "\"hello\""
let ast = parseSingle input let ast = parseSingle input
(result $ evalSingle Map.empty ast) @?= ofString "hello" (result $ evalSingle Map.empty ast) @?= ofString "hello"
, testCase "Evaluate list literal" $ do , testCase "Evaluate list literal" $ do
let input = "[t (t t)]" let input = "[t (t t)]"
let ast = parseSingle input let ast = parseSingle input
(result $ evalSingle Map.empty ast) @?= ofList [Leaf, Stem Leaf] (result $ evalSingle Map.empty ast) @?= ofList [Leaf, Stem Leaf]
, testCase "Evaluate empty list" $ do , testCase "Evaluate empty list" $ do
let input = "[]" let input = "[]"
let ast = parseSingle input let ast = parseSingle input
(result $ evalSingle Map.empty ast) @?= ofList [] (result $ evalSingle Map.empty ast) @?= ofList []
, testCase "Evaluate variable dependency chain" $ do , testCase "Evaluate variable dependency chain" $ do
let input = "x = t (t t)\n \ let input = "x = t (t t)\n \
\ y = x\n \ \ y = x\n \
@ -207,10 +245,17 @@ evaluationTests = testGroup "Evaluation Tests"
\ variablewithamuchlongername" \ variablewithamuchlongername"
env = evalTricu Map.empty (parseTricu input) env = evalTricu Map.empty (parseTricu input)
(result env) @?= (Stem (Stem Leaf)) (result env) @?= (Stem (Stem Leaf))
, testCase "Evaluate variable shadowing" $ do
, testCase "Immutable definitions" $ do
let input = "x = t t\nx = t\nx" let input = "x = t t\nx = t\nx"
env = evalTricu Map.empty (parseTricu input) env = evalTricu Map.empty (parseTricu input)
(result env) @?= Leaf result <- try (evaluate (runTricu input)) :: IO (Either SomeException String)
case result of
Left _ -> return ()
Right _ -> assertFailure "Expected evaluation error"
, testCase "Apply identity to Boolean Not" $ do , testCase "Apply identity to Boolean Not" $ do
let not = "(t (t (t t) (t t t)) t)" let not = "(t (t (t t) (t t t)) t)"
let input = "x = (\\a : a)\nx " ++ not let input = "x = (\\a : a)\nx " ++ not
@ -218,174 +263,215 @@ evaluationTests = testGroup "Evaluation Tests"
result env @?= Fork (Fork (Stem Leaf) (Fork Leaf Leaf)) Leaf result env @?= Fork (Fork (Stem Leaf) (Fork Leaf Leaf)) Leaf
] ]
lambdaEvalTests :: TestTree lambdas :: TestTree
lambdaEvalTests = testGroup "Lambda Evaluation Tests" lambdas = testGroup "Lambda Evaluation Tests"
[ testCase "Lambda Identity Function" $ do [ testCase "Lambda Identity Function" $ do
let input = "id = (\\x : x)\nid t" let input = "id = (\\x : x)\nid t"
runTricu input @?= "Leaf" runTricu input @?= "Leaf"
, testCase "Lambda Constant Function (K combinator)" $ do , testCase "Lambda Constant Function (K combinator)" $ do
let input = "k = (\\x y : x)\nk t (t t)" let input = "k = (\\x y : x)\nk t (t t)"
runTricu input @?= "Leaf" runTricu input @?= "Leaf"
, testCase "Lambda Application with Variable" $ do , testCase "Lambda Application with Variable" $ do
let input = "id = (\\x : x)\nval = t t\nid val" let input = "id = (\\x : x)\nval = t t\nid val"
runTricu input @?= "Stem Leaf" runTricu input @?= "Stem Leaf"
, testCase "Lambda Application with Multiple Arguments" $ do , testCase "Lambda Application with Multiple Arguments" $ do
let input = "apply = (\\f x y : f x y)\nk = (\\a b : a)\napply k t (t t)" let input = "apply = (\\f x y : f x y)\nk = (\\a b : a)\napply k t (t t)"
runTricu input @?= "Leaf" runTricu input @?= "Leaf"
, testCase "Nested Lambda Application" $ do , testCase "Nested Lambda Application" $ do
let input = "apply = (\\f x y : f x y)\nid = (\\x : x)\napply (\\f x : f x) id t" let input = "apply = (\\f x y : f x y)\nid = (\\x : x)\napply (\\f x : f x) id t"
runTricu input @?= "Leaf" runTricu input @?= "Leaf"
, testCase "Lambda with a complex body" $ do , testCase "Lambda with a complex body" $ do
let input = "f = (\\x : t (t x))\nf t" let input = "f = (\\x : t (t x))\nf t"
runTricu input @?= "Stem (Stem Leaf)" runTricu input @?= "Stem (Stem Leaf)"
, testCase "Lambda returning a function" $ do , testCase "Lambda returning a function" $ do
let input = "f = (\\x : (\\y : x))\ng = f t\ng (t t)" let input = "f = (\\x : (\\y : x))\ng = f t\ng (t t)"
runTricu input @?= "Leaf" runTricu input @?= "Leaf"
, testCase "Lambda with Shadowing" $ do , testCase "Lambda with Shadowing" $ do
let input = "f = (\\x : (\\x : x))\nf t (t t)" let input = "f = (\\x : (\\x : x))\nf t (t t)"
runTricu input @?= "Stem Leaf" runTricu input @?= "Stem Leaf"
, testCase "Lambda returning another lambda" $ do , testCase "Lambda returning another lambda" $ do
let input = "k = (\\x : (\\y : x))\nk_app = k t\nk_app (t t)" let input = "k = (\\x : (\\y : x))\nk_app = k t\nk_app (t t)"
runTricu input @?= "Leaf" runTricu input @?= "Leaf"
, testCase "Lambda with free variables" $ do , testCase "Lambda with free variables" $ do
let input = "y = t t\nf = (\\x : y)\nf t" let input = "y = t t\nf = (\\x : y)\nf t"
runTricu input @?= "Stem Leaf" runTricu input @?= "Stem Leaf"
, testCase "SKI Composition" $ do , testCase "SKI Composition" $ do
let input = "s = (\\x y z : x z (y z))\nk = (\\x y : x)\ni = (\\x : x)\ncomp = s k i\ncomp t (t t)" let input = "s = (\\x y z : x z (y z))\nk = (\\x y : x)\ni = (\\x : x)\ncomp = s k i\ncomp t (t t)"
runTricu input @?= "Stem (Stem Leaf)" runTricu input @?= "Stem (Stem Leaf)"
, testCase "Lambda with multiple parameters and application" $ do , testCase "Lambda with multiple parameters and application" $ do
let input = "f = (\\a b c : t a b c)\nf t (t t) (t t t)" let input = "f = (\\a b c : t a b c)\nf t (t t) (t t t)"
runTricu input @?= "Stem Leaf" runTricu input @?= "Stem Leaf"
, testCase "Lambda with nested application in the body" $ do , testCase "Lambda with nested application in the body" $ do
let input = "f = (\\x : t (t (t x)))\nf t" let input = "f = (\\x : t (t (t x)))\nf t"
runTricu input @?= "Stem (Stem (Stem Leaf))" runTricu input @?= "Stem (Stem (Stem Leaf))"
, testCase "Lambda returning a function and applying it" $ do , testCase "Lambda returning a function and applying it" $ do
let input = "f = (\\x : (\\y : t x y))\ng = f t\ng (t t)" let input = "f = (\\x : (\\y : t x y))\ng = f t\ng (t t)"
runTricu input @?= "Fork Leaf (Stem Leaf)" runTricu input @?= "Fork Leaf (Stem Leaf)"
, testCase "Lambda applying a variable" $ do , testCase "Lambda applying a variable" $ do
let input = "id = (\\x : x)\na = t t\nid a" let input = "id = (\\x : x)\na = t t\nid a"
runTricu input @?= "Stem Leaf" runTricu input @?= "Stem Leaf"
, testCase "Nested lambda abstractions in the same expression" $ do , testCase "Nested lambda abstractions in the same expression" $ do
let input = "f = (\\x : (\\y : x y))\ng = (\\z : z)\nf g t" let input = "f = (\\x : (\\y : x y))\ng = (\\z : z)\nf g t"
runTricu input @?= "Leaf" runTricu input @?= "Leaf"
, testCase "Lambda with a string literal" $ do , testCase "Lambda with a string literal" $ do
let input = "f = (\\x : x)\nf \"hello\"" let input = "f = (\\x : x)\nf \"hello\""
runTricu input @?= "Fork (Fork Leaf (Fork Leaf (Fork Leaf (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) (Fork (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork Leaf (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) (Fork (Fork Leaf (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) (Fork (Fork Leaf (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) (Fork (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) Leaf))))" runTricu input @?= "Fork (Fork Leaf (Fork Leaf (Fork Leaf (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) (Fork (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork Leaf (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) (Fork (Fork Leaf (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) (Fork (Fork Leaf (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) (Fork (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork (Stem Leaf) Leaf))))))) Leaf))))"
, testCase "Lambda with an integer literal" $ do , testCase "Lambda with an integer literal" $ do
let input = "f = (\\x : x)\nf 42" let input = "f = (\\x : x)\nf 42"
runTricu input @?= "Fork Leaf (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) Leaf)))))" runTricu input @?= "Fork Leaf (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) (Fork Leaf (Fork (Stem Leaf) Leaf)))))"
, testCase "Lambda with a list literal" $ do , testCase "Lambda with a list literal" $ do
let input = "f = (\\x : x)\nf [t (t t)]" let input = "f = (\\x : x)\nf [t (t t)]"
runTricu input @?= "Fork Leaf (Fork (Stem Leaf) Leaf)" runTricu input @?= "Fork Leaf (Fork (Stem Leaf) Leaf)"
] ]
libraryTests :: TestTree baseLibrary :: TestTree
libraryTests = testGroup "Library Tests" baseLibrary = testGroup "Library Tests"
[ testCase "K combinator 1" $ do [ testCase "K combinator 1" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "k (t) (t t)" let input = "k (t) (t t)"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Leaf result env @?= Leaf
, testCase "K combinator 2" $ do , testCase "K combinator 2" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "k (t t) (t)" let input = "k (t t) (t)"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Stem Leaf result env @?= Stem Leaf
, testCase "K combinator 3" $ do , testCase "K combinator 3" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "k (t t t) (t)" let input = "k (t t t) (t)"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Fork Leaf Leaf result env @?= Fork Leaf Leaf
, testCase "S combinator" $ do , testCase "S combinator" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "s (t) (t) (t)" let input = "s (t) (t) (t)"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Fork Leaf (Stem Leaf) result env @?= Fork Leaf (Stem Leaf)
, testCase "SKK == I (fully expanded)" $ do , testCase "SKK == I (fully expanded)" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "s k k" let input = "s k k"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Fork (Stem (Stem Leaf)) (Stem Leaf) result env @?= Fork (Stem (Stem Leaf)) (Stem Leaf)
, testCase "I combinator" $ do , testCase "I combinator" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "i not?" let input = "i not?"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Fork (Fork (Stem Leaf) (Fork Leaf Leaf)) (Fork Leaf (Fork Leaf Leaf)) result env @?= Fork (Fork (Stem Leaf) (Fork Leaf Leaf)) (Fork Leaf (Fork Leaf Leaf))
, testCase "Triage test Leaf" $ do , testCase "Triage test Leaf" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "test t" let input = "test t"
env = decodeResult $ result $ evalTricu library (parseTricu input) env = decodeResult $ result $ evalTricu library (parseTricu input)
env @?= "\"Leaf\"" env @?= "\"Leaf\""
, testCase "Triage test (Stem Leaf)" $ do , testCase "Triage test (Stem Leaf)" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "test (t t)" let input = "test (t t)"
env = decodeResult $ result $ evalTricu library (parseTricu input) env = decodeResult $ result $ evalTricu library (parseTricu input)
env @?= "\"Stem\"" env @?= "\"Stem\""
, testCase "Triage test (Fork Leaf Leaf)" $ do , testCase "Triage test (Fork Leaf Leaf)" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "test (t t t)" let input = "test (t t t)"
env = decodeResult $ result $ evalTricu library (parseTricu input) env = decodeResult $ result $ evalTricu library (parseTricu input)
env @?= "\"Fork\"" env @?= "\"Fork\""
, testCase "Boolean NOT: true" $ do , testCase "Boolean NOT: true" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "not? true" let input = "not? true"
env = result $ evalTricu library (parseTricu input) env = result $ evalTricu library (parseTricu input)
env @?= Leaf env @?= Leaf
, testCase "Boolean NOT: false" $ do , testCase "Boolean NOT: false" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "not? false" let input = "not? false"
env = result $ evalTricu library (parseTricu input) env = result $ evalTricu library (parseTricu input)
env @?= Stem Leaf env @?= Stem Leaf
, testCase "Boolean AND TF" $ do , testCase "Boolean AND TF" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "and? (t t) (t)" let input = "and? (t t) (t)"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Leaf result env @?= Leaf
, testCase "Boolean AND FT" $ do , testCase "Boolean AND FT" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "and? (t) (t t)" let input = "and? (t) (t t)"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Leaf result env @?= Leaf
, testCase "Boolean AND FF" $ do , testCase "Boolean AND FF" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "and? (t) (t)" let input = "and? (t) (t)"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Leaf result env @?= Leaf
, testCase "Boolean AND TT" $ do , testCase "Boolean AND TT" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "and? (t t) (t t)" let input = "and? (t t) (t t)"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Stem Leaf result env @?= Stem Leaf
, testCase "List head" $ do , testCase "List head" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "head [(t) (t t) (t t t)]" let input = "head [(t) (t t) (t t t)]"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Leaf result env @?= Leaf
, testCase "List tail" $ do , testCase "List tail" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "head (tail (tail [(t) (t t) (t t t)]))" let input = "head (tail (tail [(t) (t t) (t t t)]))"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Fork Leaf Leaf result env @?= Fork Leaf Leaf
, testCase "List map" $ do , testCase "List map" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "head (tail (map (\\a : (t t t)) [(t) (t) (t)]))" let input = "head (tail (map (\\a : (t t t)) [(t) (t) (t)]))"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Fork Leaf Leaf result env @?= Fork Leaf Leaf
, testCase "Empty list check" $ do , testCase "Empty list check" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "emptyList? []" let input = "emptyList? []"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Stem Leaf result env @?= Stem Leaf
, testCase "Non-empty list check" $ do , testCase "Non-empty list check" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "not? (emptyList? [(1) (2) (3)])" let input = "not? (emptyList? [(1) (2) (3)])"
env = evalTricu library (parseTricu input) env = evalTricu library (parseTricu input)
result env @?= Stem Leaf result env @?= Stem Leaf
, testCase "Concatenate strings" $ do , testCase "Concatenate strings" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "lconcat \"Hello, \" \"world!\"" let input = "lconcat \"Hello, \" \"world!\""
env = decodeResult $ result $ evalTricu library (parseTricu input) env = decodeResult $ result $ evalTricu library (parseTricu input)
env @?= "\"Hello, world!\"" env @?= "\"Hello, world!\""
, testCase "Verifying Equality" $ do , testCase "Verifying Equality" $ do
library <- evaluateFile "./lib/base.tri" library <- evaluateFile "./lib/base.tri"
let input = "equal? (t t t) (t t t)" let input = "equal? (t t t) (t t t)"
@ -393,19 +479,75 @@ libraryTests = testGroup "Library Tests"
result env @?= Stem Leaf result env @?= Stem Leaf
] ]
fileEvaluationTests :: TestTree fileEval :: TestTree
fileEvaluationTests = testGroup "Evaluation tests" fileEval = testGroup "File evaluation tests"
[ testCase "Forks" $ do [ testCase "Forks" $ do
res <- liftIO $ evaluateFileResult "./test/fork.tri" res <- liftIO $ evaluateFileResult "./test/fork.tri"
res @?= Fork Leaf Leaf res @?= Fork Leaf Leaf
, testCase "File ends with comment" $ do , testCase "File ends with comment" $ do
res <- liftIO $ evaluateFileResult "./test/comments-1.tri" res <- liftIO $ evaluateFileResult "./test/comments-1.tri"
res @?= Fork (Stem Leaf) Leaf res @?= Fork (Stem Leaf) Leaf
, testCase "Mapping and Equality" $ do , testCase "Mapping and Equality" $ do
res <- liftIO $ evaluateFileResult "./test/map.tri" library <- liftIO $ evaluateFile "./lib/base.tri"
res @?= Stem Leaf fEnv <- liftIO $ evaluateFileWithContext library "./test/map.tri"
(mainResult fEnv) @?= Stem Leaf
, testCase "Eval and decoding string" $ do , testCase "Eval and decoding string" $ do
library <- liftIO $ evaluateFile "./lib/base.tri" library <- liftIO $ evaluateFile "./lib/base.tri"
res <- liftIO $ evaluateFileWithContext library "./test/string.tri" res <- liftIO $ evaluateFileWithContext library "./test/string.tri"
decodeResult (result res) @?= "\"String test!\"" decodeResult (result res) @?= "\"String test!\""
] ]
modules :: TestTree
modules = testGroup "Test modules"
[ testCase "Detect cyclic dependencies" $ do
result <- try (liftIO $ evaluateFileResult "./test/cycle-1.tri") :: IO (Either SomeException T)
case result of
Left e -> do
let errorMsg = show e
if "Encountered cyclic import" `isInfixOf` errorMsg
then return ()
else assertFailure $ "Unexpected error: " ++ errorMsg
Right _ -> assertFailure "Expected cyclic dependencies"
, testCase "Module imports and namespacing" $ do
res <- liftIO $ evaluateFileResult "./test/namespace-A.tri"
res @?= Leaf
, testCase "Multiple imports" $ do
res <- liftIO $ evaluateFileResult "./test/vars-A.tri"
res @?= Leaf
, testCase "Error on unresolved variable" $ do
result <- try (liftIO $ evaluateFileResult "./test/unresolved-A.tri") :: IO (Either SomeException T)
case result of
Left e -> do
let errorMsg = show e
if "undefinedVar" `isInfixOf` errorMsg
then return ()
else assertFailure $ "Unexpected error: " ++ errorMsg
Right _ -> assertFailure "Expected unresolved variable error"
, testCase "Multi-level imports" $ do
res <- liftIO $ evaluateFileResult "./test/multi-level-A.tri"
res @?= Leaf
, testCase "Lambda expression namespaces" $ do
res <- liftIO $ evaluateFileResult "./test/lambda-A.tri"
res @?= Leaf
]
-- All of our demo tests are also module tests
demos :: TestTree
demos = testGroup "Test provided demo functionality"
[ testCase "Structural equality demo" $ do
res <- liftIO $ evaluateFileResult "./demos/equality.tri"
decodeResult res @?= "t t"
, testCase "Convert values back to source code demo" $ do
res <- liftIO $ evaluateFileResult "./demos/toSource.tri"
decodeResult res @?= "\"(t (t (t t) (t t t)) (t t (t t t)))\""
, testCase "Determining the size of functions" $ do
res <- liftIO $ evaluateFileResult "./demos/size.tri"
decodeResult res @?= "454"
, testCase "Level Order Traversal demo" $ do
res <- liftIO $ evaluateFileResult "./demos/levelOrderTraversal.tri"
decodeResult res @?= "\"\n1 \n2 3 \n4 5 6 7 \n8 11 10 9 12 \""
]

2
test/comments-1.tri
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@ -2,7 +2,7 @@
-- t (t t) (t (t t t)) -- t (t t) (t (t t t))
-- t (t t t) (t t) -- t (t t t) (t t)
-- x = (\a : a) -- x = (\a : a)
t (t t) t -- Fork (Stem Leaf) Leaf main = t (t t) t -- Fork (Stem Leaf) Leaf
-- t t -- t t
-- x -- x
-- x = (\a : a) -- x = (\a : a)

5
test/cycle-1.tri Normal file
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@ -0,0 +1,5 @@
!module Cycle
!import "test/cycle-2.tri" Cycle2
cycle1 = t Cycle2.cycle2

5
test/cycle-2.tri Normal file
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@ -0,0 +1,5 @@
!module Cycle2
!import "test/cycle-1.tri" Cycle1
cycle2 = t Cycle1.cycle1

2
test/fork.tri
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@ -1 +1 @@
t t t main = t t t

2
test/lambda-A.tri Normal file
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@ -0,0 +1,2 @@
!module A
main = (\x : x) t

24
test/map.tri
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@ -1,24 +1,2 @@
false = t
true = t t
_ = t
k = t t
i = t (t k) t
s = t (t (k t)) t
m = s i i
b = s (k s) k
c = s (s (k s) (s (k k) s)) (k k)
iC = (\a b c : s a (k c) b)
yi = (\i : b m (c b (i m)))
y = yi iC
triage = (\a b c : t (t a b) c)
pair = t
matchList = (\oe oc : triage oe _ oc)
lconcat = y (\self : matchList (\k : k) (\h r k : pair h (self r k)))
hmap = y (\self : matchList (\f : t) (\hd tl f : pair (f hd) (self tl f)))
map = (\f l : hmap l f)
lAnd = triage (\x : false) (\_ x : x) (\_ _ x : x)
lOr = triage (\x : x) (\_ _ : true) (\_ _ x : true)
equal = y (\self : triage (triage true (\z : false) (\y z : false)) (\ax : triage false (self ax) (\y z : false)) (\ax ay : triage false (\z : false) (\bx by : lAnd (self ax bx) (self ay by))))
x = map (\i : lconcat "Successfully concatenated " i) [("two strings!")] x = map (\i : lconcat "Successfully concatenated " i) [("two strings!")]
equal x [("Successfully concatenated two strings!")] main = equal? x [("Successfully concatenated two strings!")]

5
test/modules-1.tri Normal file
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@ -0,0 +1,5 @@
!module Test
!import "lib/base.tri" Lib
main = Lib.not? t

1
test/modules-2.tri Normal file
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@ -0,0 +1 @@
n = t t t

3
test/multi-level-A.tri Normal file
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@ -0,0 +1,3 @@
!module A
!import "./test/multi-level-B.tri" B
main = B.main

3
test/multi-level-B.tri Normal file
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@ -0,0 +1,3 @@
!module B
!import "./test/multi-level-C.tri" C
main = C.val

2
test/multi-level-C.tri Normal file
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@ -0,0 +1,2 @@
!module C
val = t

3
test/namespace-A.tri Normal file
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@ -0,0 +1,3 @@
!module A
!import "./test/namespace-B.tri" B
main = B.x

2
test/namespace-B.tri Normal file
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@ -0,0 +1,2 @@
!module B
x = t

21
test/size.tri Normal file
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@ -0,0 +1,21 @@
compose = \f g x : f (g x)
succ = y (\self :
triage
1
t
(triage
(t (t t))
(\_ tail : t t (self tail))
t))
size = (\x :
(y (\self x :
compose succ
(triage
(\x : x)
self
(\x y : compose (self x) (self y))
x)) x 0))
size size

1
test/undefined.tri Normal file
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@ -0,0 +1 @@
namedTerm = undefinedForTesting

2
test/unresolved-A.tri Normal file
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@ -0,0 +1,2 @@
!module A
main = undefinedVar

7
test/vars-A.tri Normal file
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@ -0,0 +1,7 @@
!module A
!import "./test/vars-B.tri" B
!import "./test/vars-C.tri" C
main = B.y (C.z)

2
test/vars-B.tri Normal file
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@ -0,0 +1,2 @@
!module B
y = \x : x

2
test/vars-C.tri Normal file
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@ -0,0 +1,2 @@
!module C
z = t

2
tricu.cabal
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@ -1,7 +1,7 @@
cabal-version: 1.12 cabal-version: 1.12
name: tricu name: tricu
version: 0.7.0 version: 0.12.0
description: A micro-language for exploring Tree Calculus description: A micro-language for exploring Tree Calculus
author: James Eversole author: James Eversole
maintainer: james@eversole.co maintainer: james@eversole.co