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44 Commits
e376d13a93 ... 0.6.0-8995

Author SHA1 Message Date
James Eversole
8995efce15 Release 0.6.0
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Test, Build, and Release / build (push) Successful in 1m40s
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2025-01-23 16:44:14 -06:00
James Eversole
03e2f6b93e Some special characters in ids; new demos
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Test and Build / build (push) Successful in 1m44s
Details 
Adds support for several special characters in identifiers. Adds a demo
for converting values to source code and another for checking equality.
Updates the existing demo and tests to reflect new names for functions
returning booleans.
 2025-01-23 15:46:40 -06:00
James Eversole
419d66b4d1 All paths for caching cabal included :)
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Test and Build / build (push) Successful in 1m41s
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2025-01-21 17:00:20 -06:00
James Eversole
4b98afd803 Use runner 0.1.0
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Test and Build / build (push) Successful in 1m42s
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2025-01-21 16:49:15 -06:00
James Eversole
0768e11a02 Update Cabal caching path
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2025-01-21 16:48:29 -06:00
James Eversole
42fce0ae43 Drop unreachable cases of updateDepth
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2025-01-21 16:16:04 -06:00
James Eversole
51b1eb070f Add more explicit error handling for mismatched groupings 2025-01-21 16:06:10 -06:00
James Eversole
c2e5a8985a Inline pattern matching in Parser 2025-01-21 14:21:47 -06:00
James Eversole
9d7e4daa41 CI/CD for tests and builds (broken caching)
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2025-01-21 13:29:52 -06:00
James Eversole
edde0a80c9 Actually readable Level Order Traversal 2025-01-20 20:10:14 -06:00
James Eversole
35163a5d54 Allow multiline expressions 2025-01-20 19:20:29 -06:00
James Eversole
ca7f09e2ac Eliminate redundant eager calls of elimLambda 2025-01-20 16:05:06 -06:00
James Eversole
82e29440b0 Reduce duplication of elimLambda calls 2025-01-20 15:16:27 -06:00
James Eversole
ad02c8b86a General refactor for legibility 
Priming to update all source to lhs and document extensively
 2025-01-19 14:41:25 -06:00
James Eversole
a3282b794f 0.5.0 release commit 2025-01-06 09:14:04 -06:00
James Eversole
7b9a62462c Level Order Traversal demo 2025-01-03 12:00:06 -06:00
James Eversole
3eb28a2c62 Drop parseVarWithoutAssignment 
Additionally sorts gitignore and adds attempted decoding of lists back
to the REPL
 2025-01-03 10:31:35 -06:00
James Eversole
8c33e5ce66 Fix critical list evaluation bug and REPL updates 2025-01-02 19:08:14 -06:00
James Eversole
76487b15f9 Use better default output form in evaluator 2025-01-01 19:40:12 -06:00
James Eversole
18ff2d2e04 Clarify CLI options 2025-01-01 19:32:41 -06:00
James Eversole
fff29199d1 Support evaluation across multiple source files 2025-01-01 19:27:04 -06:00
James Eversole
a2c459b148 Provide "library" via tricu file directly 
Allows easier loading of other files and drops the list of Haskell
strings containing the basic tools included
 2025-01-01 18:53:56 -06:00
James Eversole
39be66a4d1 Fixes identifier lexing; support REPL file loading 2025-01-01 18:05:21 -06:00
James Eversole
bf58c9afbd Normalize CLI options and help display 2025-01-01 08:34:17 -06:00
James Eversole
7d38d99dcd Rename "compiler" functionality to Evaluator 
Allows for stdin input for evaluation when no input file is provided.
 2025-01-01 08:23:53 -06:00
James Eversole
458d3c3b10 Latest --help in README 2024-12-31 10:09:36 -06:00
James Eversole
0048fed6b4 Merge pull request 'Add "SimpleT" t output form' (#9) from feat/new-outputs into main 
Reviewed-on: #9
 2024-12-31 16:05:38 +00:00
James Eversole
476c3912a4 Merge branch 'main' into feat/new-outputs 2024-12-31 16:04:32 +00:00
James Eversole
493ef51a6a Add "SimpleT" t output form 
This new output form allows easy piping to the decode function of the
tricu executable. Includes a new test for roundtrip evaluation of map,
compilation to tree calculus terms, and decoding back to a human
readable string.
 2024-12-31 10:00:52 -06:00
James Eversole
e22ff06bfe Merge pull request 'Expands CLI support with output forms and decoding' (#7) from feat/ternary-representation into main 
Reviewed-on: #7
 2024-12-30 20:24:27 +00:00
James Eversole
5e2a4dff50 Expands CLI support with output forms and decoding 
Adds CLI options for compiling to a Tree Calculus, AST, Ternary, and
ASCII tree view. Adds CLI command for attempted decoding of a compiled
result to Number/String/List.
 2024-12-30 14:22:37 -06:00
James Eversole
8622af9ad2 Initial ternary representation options 
Both parsing and conversion from T to ternary representation supported
 2024-12-30 08:30:40 -06:00
James Eversole
fe70aa72ac Merge pull request 'Adds "compiler" and CLI argument handling' (#3) from feature/compiler-CLI into main 
Reviewed-on: #3
 2024-12-30 03:51:59 +00:00
James Eversole
2abeab9c04 Adds "compiler" and CLI argument handling 2024-12-29 21:49:57 -06:00
James Eversole
467e11edb3 Updates to tests 
Uncomments a test for comment parsing behavior and removes a test for
incomplete function definitions.
 2024-12-29 21:09:02 -06:00
James Eversole
38509724b1 Merge pull request 'Resolves issue with parsing comments' (#2) from fix/comments-0001 into main 
Reviewed-on: #2
 2024-12-30 03:03:39 +00:00
James Eversole
a8f72290a2 Resolves issue with parsing comments 2024-12-29 21:02:38 -06:00
James Eversole
b86ff6e9b8 Additional tests 2024-12-29 12:22:24 -06:00
James Eversole
a7674d4635 README updates for run/build 2024-12-29 10:41:04 -06:00
James Eversole
14fdb741dc README clarifications 2024-12-29 10:37:37 -06:00
James Eversole
60a9e3c1ee Expansion of testing suite to cover incl. library 
Expands the testing suite to verify behavior of provided library
functions. Updates the README further for clarification on important
concepts.
 2024-12-29 10:28:32 -06:00
James Eversole
c30f17367f Rename from sapling to tricu 2024-12-29 08:29:25 -06:00
James Eversole
064bed26c5 Further README clarification 2024-12-28 22:20:43 -06:00
James Eversole
ff2952010f README updates 2024-12-28 21:58:52 -06:00
25 changed files with 1256 additions and 693 deletions
Expand all files Collapse all files

86
.gitea/workflows/test-and-build.yml Normal file
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@ -0,0 +1,86 @@
name: Test, Build, and Release
on:
push:
tags:
- '*'
jobs:
test:
container:
image: docker.matri.cx/nix-runner:v0.1.0
credentials:
username: ${{ secrets.REGISTRY_USERNAME }}
password: ${{ secrets.REGISTRY_PASSWORD }}
steps:
- uses: actions/checkout@v3
with:
fetch-depth: 0
- name: Set up cache for Cabal
uses: actions/cache@v4
with:
path: |
~/.cache/cabal
~/.config/cabal
~/.local/state/cabal
key: cabal-${{ hashFiles('tricu.cabal') }}
restore-keys: |
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
run: |
nix develop --command cabal update
- name: Run test suite
run: |
nix develop --command cabal test
build:
needs: test
container:
image: docker.matri.cx/nix-runner:v0.1.0
credentials:
username: ${{ secrets.REGISTRY_USERNAME }}
password: ${{ secrets.REGISTRY_PASSWORD }}
steps:
- uses: actions/checkout@v3
with:
fetch-depth: 0
- name: Set up cache for Nix
uses: actions/cache@v4
with:
path: |
/nix/store
/nix/var/nix/cache
key: nix-${{ hashFiles('flake.lock') }}
restore-keys: |
nix-
- name: Build binary
run: |
nix build
ls -alh ./result/bin/tricu
- name: Setup go for release actoin
uses: actions/setup-go@v5
with:
go-version: '>=1.20.1'
- name: Release binary
uses: https://gitea.com/actions/release-action@main
with:
files: |-
./result/bin/tricu
api_key: '${{ secrets.RELEASE_TOKEN }}'

17
.gitignore vendored
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@ -1,14 +1,11 @@
bin/
data/Purr.sqlite
data/encryptionKey
/result
/config.dhall
/Dockerfile
/docker-stack.yml
.stack-work/
*.swp *.swp
dist* *.txt
*~ *~
.env .env
.stack-work/
/Dockerfile
/config.dhall
/result
WD WD
*.hs.txt bin/
dist*

96
README.md
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@ -1,54 +1,82 @@
# sapling # tricu
## Introduction ## Introduction
sapling is a "micro-language" that I'm working on to investigate [Tree Calculus](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. [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).
It offers a minimal amount of syntax sugar: tricu offers minimal syntax sugar yet manages to provide a complete, intuitive, and familiar programming environment. There is great power in simplicity. tricu offers:
- `t` operator behaving by the rules of Tree Calculus 1. `t` operator behaving by the rules of Tree Calculus
- Function ("variable") definitions 1. Function definitions/assignments
- Lambda abstractions 1. Lambda abstractions eliminated to Tree Calculus forms
- List, Number, and String literals (WIP) 1. List, Number, and String literals
1. Parentheses for grouping function application
This is an active experimentation project by [someone who has no idea what they're doing](https://eversole.co). 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.
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.
## What does it look like? ## What does it look like?
``` ```
false = t tricu < -- Anything after `--` on a single line is a comment
_ = t tricu < id = (\a : a) -- Lambda abstraction is eliminated to tree calculus terms
true = t t tricu < head (map (\i : lconcat i " world!") [("Hello, ")])
id = (\a : a) tricu > "Hello, world!"
triage = (\a b c : t (t a b) c) tricu < id (head (map (\i : lconcat i " world!") [("Hello, ")]))
match_bool = (\ot of : triage of (\_ : ot) t) tricu > "Hello, world!"
and = match_bool id (\_ : false)
if = (\cond then else : t (t else (t t then)) t cond)
triage = (\a b c : t (t a b) c)
test = triage "leaf" (\_ : "stem") (\_ _ : "fork")
-- The REPL outputs the tree form results by default; they are elided here. tricu < -- Intensionality! We can inspect the structure of a function.
sapling < test t tricu < triage = (\a b c : t (t a b) c)
DECODE -: "leaf" tricu < test = triage "Leaf" (\z : "Stem") (\a b : "Fork")
sapling < test (t t) tricu < test (t t)
DECODE -: "stem" tricu > "Stem"
sapling < test (t t t) tricu < -- We can even write a function to convert a term back to source code
DECODE -: "fork" tricu < toSource not?
sapling < map (\i : listConcat i " is super cool!") [("He") ("She") ("Everybody")] tricu > "(t (t (t t) (t t t)) (t t (t t t)))"
DECODE -: ["He is super cool!", "She is super cool!", "Everybody is super cool!"]
``` ```
## How to use ## Installation and Use
For now, you can easily build and run this project using Nix: You can easily build and/or run this project using [Nix](https://nixos.org/download/).
1. Clone the repository: - Quick Start (REPL):
a. `git clone ssh://git.eversole.co/sapling.git` - `nix run git+https://git.eversole.co/James/tricu`
b. `git clone https://git.eversole/sapling.git` - Build executable in `./result/bin`:
1. Run the REPL: `nix run` - `nix build git+https://git.eversole.co/James/tricu`
`./result/bin/tricu --help`
```
tricu Evaluator and REPL
tricu [COMMAND] ... [OPTIONS]
tricu: Exploring Tree Calculus
Common flags:
-? --help Display help message
-V --version Print version information
tricu [repl] [OPTIONS]
Start interactive REPL
tricu eval [OPTIONS]
Evaluate tricu and return the result of the final expression.
-f --file=FILE Input file path(s) for evaluation.
Defaults to stdin.
-t --form=FORM Optional output form: (tree|fsl|ast|ternary|ascii).
Defaults to tricu-compatible `t` tree form.
tricu decode [OPTIONS]
Decode a Tree Calculus value into a string representation.
-f --file=FILE Optional input file path to attempt decoding.
Defaults to stdin.
```
## Acknowledgements ## Acknowledgements
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 sapling 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 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.

24
demos/equality.tri Normal file
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@ -0,0 +1,24 @@
false = t
true = t t
triage = (\a b c : t (t a b) c)
matchBool = (\ot of : triage
of
(\_ : ot)
(\_ _ : ot)
)
not_TC? = t (t (t t) (t t t)) (t t (t t t))
not_Lambda? = matchBool false true
areEqual? = equal not_TC not_Lambda
true_TC? = not_TC false
false_TC? = not_TC true
true_Lambda? = not_Lambda false
false_Lambda? = not_Lambda true
areTrueEqual? = equal true_TC true_Lambda
areFalseEqual? = equal false_TC false_Lambda

65
demos/levelOrderTraversal.tri Normal file
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@ -0,0 +1,65 @@
-- Level Order Traversal of a labelled binary tree
-- 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 sublists where values act as labels. We
-- require explicit notation of empty nodes. Empty nodes can be represented
-- with an empty list, `[]`, which is equivalent to a single node `t`.
--
-- Example tree inputs:
-- [("1") [("2") [("4") t t] t] [("3") [("5") t t] [("6") t t]]]]
-- Graph:
-- 1
-- / \
-- 2 3
-- / / \
-- 4 5 6
--
label = (\node : head node)
left = (\node : if (emptyList node)
[]
(if (emptyList (tail node))
[]
(head (tail node))))
right = (\node : if (emptyList node)
[]
(if (emptyList (tail node))
[]
(if (emptyList (tail (tail node)))
[]
(head (tail (tail node))))))
processLevel = y (\self queue : if (emptyList queue)
[]
(pair (map label queue) (self (filter
(\node : not (emptyList node))
(lconcat (map left queue) (map right queue))))))
levelOrderTraversal_ = (\a : processLevel (t a t))
toLineString = y (\self levels : if (emptyList levels)
""
(lconcat
(lconcat (map (\x : lconcat x " ") (head levels)) "")
(if (emptyList (tail levels)) "" (lconcat (t (t 10 t) t) (self (tail levels))))))
levelOrderToString = (\s : toLineString (levelOrderTraversal_ s))
flatten = foldl (\acc x : lconcat acc x) ""
levelOrderTraversal = (\s : lconcat (t 10 t) (flatten (levelOrderToString s)))
exampleOne = levelOrderTraversal [("1")
[("2") [("4") t t] t]
[("3") [("5") t t] [("6") t t]]]
exampleTwo = levelOrderTraversal [("1")
[("2") [("4") [("8") t t] [("9") t t]]
[("6") [("10") t t] [("12") t t]]]
[("3") [("5") [("11") t t] t] [("7") t t]]]
exampleTwo

46
demos/toSource.tri Normal file
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@ -0,0 +1,46 @@
-- 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
-- Tree Calculus (TC) terms during evaluation.
-- Triage takes four arguments: the first three represent behaviors for each
-- structural case in Tree Calculus (Leaf, Stem, and Fork).
-- 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
-- shape, making it possible to perform structure-specific operations such as
-- reconstructing the terms' source code representation.
triage = (\a b c : t (t a b) c)
-- Base case of a single Leaf
sourceLeaf = t (head "t")
-- Stem case
sourceStem = (\convert : (\a rest :
t (head "(") -- Start with a left parenthesis "(".
(t (head "t") -- Add a "t"
(t (head " ") -- Add a space.
(convert a -- Recursively convert the argument.
(t (head ")") rest)))))) -- Close with ")" and append the rest.
-- Fork case
sourceFork = (\convert : (\a b rest :
t (head "(") -- Start with a left parenthesis "(".
(t (head "t") -- Add a "t"
(t (head " ") -- Add a space.
(convert a -- Recursively convert the first arg.
(t (head " ") -- Add another space.
(convert b -- Recursively convert the second arg.
(t (head ")") rest)))))))) -- Close with ")" and append the rest.
-- Wrapper around triage
toSource_ = y (\self arg :
triage
sourceLeaf -- Triage `a` case, Leaf
(sourceStem self) -- Triage `b` case, Stem
(sourceFork self) -- Triage `c` case, Fork
arg) -- The term to be inspected
-- toSource takes a single TC term and returns a String
toSource = (\v : toSource_ v "")
exampleOne = toSource true -- OUT: "(t t)"
exampleTwo = toSource not -- OUT: "(t (t (t t) (t t t)) (t t (t t t)))"

6
flake.nix
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@ -1,5 +1,5 @@
{ {
description = "sapling"; description = "tricu";
inputs = { inputs = {
nixpkgs.url = "github:NixOS/nixpkgs"; nixpkgs.url = "github:NixOS/nixpkgs";
@ -10,7 +10,7 @@
flake-utils.lib.eachDefaultSystem (system: flake-utils.lib.eachDefaultSystem (system:
let let
pkgs = nixpkgs.legacyPackages.${system}; pkgs = nixpkgs.legacyPackages.${system};
packageName = "sapling"; packageName = "tricu";
containerPackageName = "${packageName}-container"; containerPackageName = "${packageName}-container";
customGHC = pkgs.haskellPackages.ghcWithPackages (hpkgs: with hpkgs; [ customGHC = pkgs.haskellPackages.ghcWithPackages (hpkgs: with hpkgs; [
@ -22,7 +22,7 @@
enableSharedExecutables = false; enableSharedExecutables = false;
enableSharedLibraries = false; enableSharedLibraries = false;
sapling = pkgs.haskell.lib.justStaticExecutables self.packages.${system}.default; tricu = pkgs.haskell.lib.justStaticExecutables self.packages.${system}.default;
in { in {
packages.${packageName} = packages.${packageName} =

96
lib/base.tri Normal file
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@ -0,0 +1,96 @@
false = t
_ = t
true = 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)
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
if = (\cond then else : t (t else (t t then)) t cond)
triage = (\a b c : t (t a b) c)
test = triage "Leaf" (\_ : "Stem") (\_ _ : "Fork")
matchBool = (\ot of : triage
of
(\_ : ot)
(\_ _ : ot)
)
matchList = (\oe oc : triage
oe
_
oc
)
matchPair = (\op : triage
_
_
op
)
not? = matchBool false true
and? = matchBool id (\_ : false)
emptyList? = matchList true (\_ _ : false)
head = matchList t (\head _ : head)
tail = matchList t (\_ tail : tail)
lconcat = y (\self : matchList
(\k : k)
(\h r k : pair h (self r k)))
lAnd = (triage
(\_ : false)
(\_ x : x)
(\_ _ x : x)
)
lOr = (triage
(\x : x)
(\_ _ : true)
(\_ _ _ : true)
)
map_ = y (\self :
matchList
(\_ : t)
(\head tail f : pair (f head) (self tail f)))
map = (\f l : map_ l f)
equal? = y (\self : triage
(triage
true
(\_ : false)
(\_ _ : false))
(\ax :
triage
false
(self ax)
(\_ _ : false))
(\ax ay :
triage
false
(\_ : false)
(\bx by : lAnd (self ax bx) (self ay by))))
filter_ = y (\self : matchList
(\_ : t)
(\head tail f : matchBool (t head) i (f head) (self tail 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 = (\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 = (\f x l : foldr_ x f l)

8
shell.nix
View File

@ -1,8 +0,0 @@
{ pkgs ? import <nixpkgs> {} }:
let x = pkgs.haskellPackages.ghcWithPackages (hpkgs: with hpkgs; [
megaparsec
]);
in
pkgs.mkShell {
buildInputs = [ x ];
}

180
src/Eval.hs
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@ -3,118 +3,90 @@ module Eval where
import Parser import Parser
import Research import Research
import Data.Map (Map) import Data.Map (Map)
import qualified Data.Map as Map import qualified Data.Map as Map
import Data.List (foldl')
import qualified Data.Set as Set import qualified Data.Set as Set
evalSingle :: Map String T -> SaplingAST -> Map String T evalSingle :: Env -> TricuAST -> Env
evalSingle env term = case term of evalSingle env term
SFunc name [] body -> | SFunc name [] body <- term =
let lineNoLambda = eliminateLambda body let res = evalAST env body
result = evalAST env lineNoLambda in Map.insert "__result" res (Map.insert name res env)
in Map.insert name result env | SApp func arg <- term =
SLambda _ body -> let res = apply (evalAST env func) (evalAST env arg)
let result = evalAST env body in Map.insert "__result" res env
in Map.insert "__result" result env | SVar name <- term =
SApp func arg -> case Map.lookup name env of
let result = apply (evalAST env $ eliminateLambda func) (evalAST env $ eliminateLambda arg) Just v -> Map.insert "__result" v env
in Map.insert "__result" result env Nothing -> errorWithoutStackTrace $ "Variable " ++ name ++ " not defined"
SVar name -> | otherwise =
case Map.lookup name env of Map.insert "__result" (evalAST env term) env
Just value -> Map.insert "__result" value env
Nothing -> error $ "Variable " ++ name ++ " not defined"
_ ->
let result = evalAST env term
in Map.insert "__result" result env
evalSapling :: Map String T -> [SaplingAST] -> Map String T evalTricu :: Env -> [TricuAST] -> Env
evalSapling env [] = env evalTricu env [] = env
evalSapling env [lastLine] = evalTricu env [x] =
let lastLineNoLambda = eliminateLambda lastLine let updatedEnv = evalSingle env x
updatedEnv = evalSingle env lastLineNoLambda in Map.insert "__result" (result updatedEnv) updatedEnv
in Map.insert "__result" (result updatedEnv) updatedEnv evalTricu env (x:xs) =
evalSapling env (line:rest) = evalTricu (evalSingle env x) xs
let lineNoLambda = eliminateLambda line
updatedEnv = evalSingle env lineNoLambda
in evalSapling updatedEnv rest
evalAST :: Map String T -> SaplingAST -> T evalAST :: Env -> TricuAST -> T
evalAST env term = case term of evalAST env term
SVar name -> case Map.lookup name env of | SLambda _ _ <- term = evalAST env (elimLambda term)
Just value -> value | SVar name <- term = evalVar name
Nothing -> error $ "Variable " ++ name ++ " not defined" | TLeaf <- term = Leaf
TLeaf -> Leaf | TStem t <- term = Stem (evalAST env t)
TStem t -> Stem (evalAST env t) | TFork t u <- term = Fork (evalAST env t) (evalAST env u)
TFork t1 t2 -> Fork (evalAST env t1) (evalAST env t2) | SApp t u <- term = apply (evalAST env t) (evalAST env u)
SApp t1 t2 -> apply (evalAST env t1) (evalAST env t2) | SStr s <- term = ofString s
SStr str -> ofString str | SInt n <- term = ofNumber n
SInt num -> ofNumber num | SList xs <- term = ofList (map (evalAST env) xs)
SList elems -> ofList (map (evalAST Map.empty) elems) | SEmpty <- term = Leaf
SFunc name args body -> | otherwise = errorWithoutStackTrace "Unexpected AST term"
error $ "Unexpected function definition " ++ name where
++ " in evalAST; define via evalSingle." evalVar name = Map.findWithDefault
SLambda {} -> error "Internal error: SLambda found in evalAST after elimination." (errorWithoutStackTrace $ "Variable " ++ name ++ " not defined")
name env
eliminateLambda :: SaplingAST -> SaplingAST
eliminateLambda (SLambda (v:vs) body)
| null vs = lambdaToT v (eliminateLambda body)
| otherwise = eliminateLambda (SLambda [v] (SLambda vs body))
eliminateLambda (SApp f arg) = SApp (eliminateLambda f) (eliminateLambda arg)
eliminateLambda (TStem t) = TStem (eliminateLambda t)
eliminateLambda (TFork l r) = TFork (eliminateLambda l) (eliminateLambda r)
eliminateLambda (SList xs) = SList (map eliminateLambda xs)
eliminateLambda other = other
-- This is my attempt to implement the lambda calculus elimination rules defined
-- in "Typed Program Analysis without Encodings" by Barry Jay.
-- https://github.com/barry-jay-personal/typed_tree_calculus/blob/main/typed_program_analysis.pdf -- https://github.com/barry-jay-personal/typed_tree_calculus/blob/main/typed_program_analysis.pdf
lambdaToT :: String -> SaplingAST -> SaplingAST -- Chapter 4: Lambda-Abstraction
lambdaToT x (SVar y) elimLambda :: TricuAST -> TricuAST
| x == y = tI elimLambda = go
lambdaToT x (SVar y) where
| x /= y = SApp tK (SVar y) go (SLambda (v:vs) body)
lambdaToT x t | null vs = toSKI v (elimLambda body)
| not (isFree x t) = SApp tK t | otherwise = elimLambda (SLambda [v] (SLambda vs body))
lambdaToT x (SApp n u) go (SApp f g) = SApp (elimLambda f) (elimLambda g)
| not (isFree x (SApp n u)) = SApp tK (SApp (eliminateLambda n) (eliminateLambda u)) go x = x
lambdaToT x (SApp n u) = SApp (SApp tS (lambdaToT x (eliminateLambda n))) (lambdaToT x (eliminateLambda u))
lambdaToT x body
| not (isFree x body) = SApp tK body
| otherwise = SApp (SApp tS (lambdaToT x body)) TLeaf
freeVars :: SaplingAST -> Set.Set String toSKI x (SVar y)
freeVars (SVar v) = Set.singleton v | x == y = _I
freeVars (SInt _) = Set.empty | otherwise = SApp _K (SVar y)
freeVars (SStr _) = Set.empty toSKI x t@(SApp n u)
freeVars (SList xs) = foldMap freeVars xs | not (isFree x t) = SApp _K t
freeVars (SApp f arg) = freeVars f <> freeVars arg | otherwise = SApp (SApp _S (toSKI x n)) (toSKI x u)
freeVars TLeaf = Set.empty toSKI x t
freeVars (SFunc _ _ b) = freeVars b | not (isFree x t) = SApp _K t
freeVars (TStem t) = freeVars t | otherwise = SApp (SApp _S (toSKI x t)) TLeaf
freeVars (TFork l r) = freeVars l <> freeVars r
freeVars (SLambda vs b) = foldr Set.delete (freeVars b) vs
isFree :: String -> SaplingAST -> Bool _S = parseSingle "t (t (t t t)) t"
isFree x = Set.member x . freeVars _K = parseSingle "t t"
_I = parseSingle "t (t (t t)) t"
isFree x = Set.member x . freeVars
freeVars (SVar v ) = Set.singleton v
freeVars (SInt _ ) = Set.empty
freeVars (SStr _ ) = Set.empty
freeVars (SList s ) = foldMap freeVars s
freeVars (SApp f a ) = freeVars f <> freeVars a
freeVars (TLeaf ) = Set.empty
freeVars (SFunc _ _ 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
toAST :: T -> SaplingAST result :: Env -> T
toAST Leaf = TLeaf
toAST (Stem a) = TStem (toAST a)
toAST (Fork a b) = TFork (toAST a) (toAST b)
-- We need the SKI operators in an unevaluated SaplingAST tree form so that we
-- can keep the evaluation functions straightforward
tI :: SaplingAST
tI = SApp (SApp TLeaf (SApp TLeaf (SApp TLeaf TLeaf))) TLeaf
tK :: SaplingAST
tK = SApp TLeaf TLeaf
tS :: SaplingAST
tS = SApp (SApp TLeaf (SApp TLeaf (SApp (SApp TLeaf TLeaf) TLeaf))) TLeaf
result :: Map String T -> T
result r = case Map.lookup "__result" r of result r = case Map.lookup "__result" r of
Just a -> a Just a -> a
Nothing -> error "No __result field found in provided environment" Nothing -> errorWithoutStackTrace "No __result field found in provided environment"

30
src/FileEval.hs Normal file
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@ -0,0 +1,30 @@
module FileEval where
import Eval
import Parser
import Research
import System.IO
import qualified Data.Map as Map
evaluateFileResult :: FilePath -> IO T
evaluateFileResult filePath = do
contents <- readFile filePath
let asts = parseTricu contents
let finalEnv = evalTricu Map.empty asts
case Map.lookup "__result" finalEnv of
Just finalResult -> return finalResult
Nothing -> errorWithoutStackTrace "No expressions to evaluate found"
evaluateFile :: FilePath -> IO Env
evaluateFile filePath = do
contents <- readFile filePath
let asts = parseTricu contents
pure $ evalTricu Map.empty asts
evaluateFileWithContext :: Env -> FilePath -> IO Env
evaluateFileWithContext env filePath = do
contents <- readFile filePath
let asts = parseTricu contents
pure $ evalTricu env asts

97
src/Lexer.hs
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@ -1,37 +1,28 @@
module Lexer where module Lexer where
import Research import Research
import Text.Megaparsec
import Text.Megaparsec.Char
import Control.Monad (void) import Control.Monad (void)
import Data.Void import Data.Void
import Text.Megaparsec
import Text.Megaparsec.Char hiding (space)
import Text.Megaparsec.Char.Lexer
import qualified Data.Set as Set import qualified Data.Set as Set
type Lexer = Parsec Void String type Lexer = Parsec Void String
data LToken
= LKeywordT
| LIdentifier String
| LIntegerLiteral Int
| LStringLiteral String
| LAssign
| LColon
| LBackslash
| LOpenParen
| LCloseParen
| LOpenBracket
| LCloseBracket
| LNewline
| LComment String
deriving (Show, Eq, Ord)
keywordT :: Lexer LToken keywordT :: Lexer LToken
keywordT = string "t" *> notFollowedBy alphaNumChar *> pure LKeywordT keywordT = string "t" *> notFollowedBy alphaNumChar *> pure LKeywordT
identifier :: Lexer LToken identifier :: Lexer LToken
identifier = do identifier = do
name <- some (letterChar <|> char '_' <|> char '-') first <- letterChar <|> char '_'
rest <- many $ letterChar
<|> digitChar
<|> char '_' <|> char '-' <|> char '?' <|> char '!'
<|> char '$' <|> char '#' <|> char '@' <|> char '%'
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)
@ -45,11 +36,8 @@ stringLiteral :: Lexer LToken
stringLiteral = do stringLiteral = do
char '"' char '"'
content <- many (noneOf ['"']) content <- many (noneOf ['"'])
if null content char '"' --"
then fail "Empty string literals are not allowed" return (LStringLiteral content)
else do
char '"' --"
return (LStringLiteral content)
assign :: Lexer LToken assign :: Lexer LToken
assign = char '=' *> pure LAssign assign = char '=' *> pure LAssign
@ -75,34 +63,39 @@ closeBracket = char ']' *> pure LCloseBracket
lnewline :: Lexer LToken lnewline :: Lexer LToken
lnewline = char '\n' *> pure LNewline lnewline = char '\n' *> pure LNewline
comment :: Lexer LToken
comment = do
string "--"
content <- many (satisfy (/= '\n'))
optional (char '\n')
pure (LComment content)
sc :: Lexer () sc :: Lexer ()
sc = skipMany (void (char ' ') <|> void (char '\t') <|> void comment) sc = space
(void $ takeWhile1P (Just "space") (\c -> c == ' ' || c == '\t'))
(skipLineComment "--")
(skipBlockComment "|-" "-|")
saplingLexer :: Lexer [LToken] tricuLexer :: Lexer [LToken]
saplingLexer = many (sc *> choice tricuLexer = do
[ try identifier sc
, try keywordT tokens <- many $ do
, try integerLiteral tok <- choice tricuLexer'
, try stringLiteral sc
, assign pure tok
, colon sc
, backslash eof
, openParen pure tokens
, closeParen where
, openBracket tricuLexer' =
, closeBracket [ try lnewline
, lnewline , try identifier
] <* sc) <* eof , try keywordT
, try integerLiteral
, try stringLiteral
, assign
, colon
, backslash
, openParen
, closeParen
, openBracket
, closeBracket
]
lexSapling :: String -> [LToken] lexTricu :: String -> [LToken]
lexSapling input = case runParser saplingLexer "" input of lexTricu input = case runParser tricuLexer "" input of
Left err -> error $ "Lexical error:\n" ++ errorBundlePretty err Left err -> errorWithoutStackTrace $ "Lexical error:\n" ++ errorBundlePretty err
Right tokens -> tokens Right tokens -> tokens

47
src/Library.hs
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@ -1,47 +0,0 @@
module Library where
import Eval
import Parser
import Research
import qualified Data.Map as Map
library :: Map.Map String T
library = evalSapling Map.empty $ parseSapling $ unlines
[ "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)"
, "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)"
, "triage = (\\a b c : t (t a b) c)"
, "pair = t"
, "matchBool = (\\ot of : triage of (\\_ : ot) (\\_ _ : ot))"
, "matchList = (\\oe oc : triage oe _ oc)"
, "matchPair = (\\op : triage _ _ op)"
, "and = matchBool id (\\z : false)"
, "if = (\\cond then else : t (t else (t t then)) t cond)"
, "test = triage \"leaf\" (\\z : \"stem\") (\\a b : \"fork\")"
, "emptyList = matchList true (\\y z : false)"
, "nonEmptyList = matchList false (\\y z : true)"
, "head = matchList t (\\hd tl : hd)"
, "tail = matchList t (\\hd tl : tl)"
, "isLeaf = (\\_ : triage true false false)"
, "listConcat = y (\\self : matchList (\\k : k) (\\h r k : pair h (self r k)))"
, "lAnd = triage (\\x : false) (\\_ x : x) (\\_ _ x : x)"
, "lOr = triage (\\x : x) (\\_ _ : true) (\\_ _ x : true)"
, "hmap = y (\\self : matchList (\\f : t) (\\hd tl f : pair (f hd) (self tl f)))"
, "map = (\\f l : hmap l f)"
, "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))))"
]

91
src/Main.hs
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@ -1,22 +1,87 @@
module Main where module Main where
import Eval import Eval (evalTricu, result)
import Lexer import FileEval
import Library import Parser (parseTricu)
import Parser import REPL
import REPL (repl)
import Research import Research
import Control.Monad (foldM)
import Control.Monad.IO.Class (liftIO)
import Text.Megaparsec (runParser)
import System.Console.CmdArgs
import qualified Data.Map as Map import qualified Data.Map as Map
import Text.Megaparsec (runParser)
data TricuArgs
= Repl
| Evaluate { file :: [FilePath], form :: EvaluatedForm }
| Decode { file :: [FilePath] }
deriving (Show, Data, Typeable)
replMode :: TricuArgs
replMode = Repl
&= help "Start interactive REPL"
&= auto
&= name "repl"
evaluateMode :: TricuArgs
evaluateMode = Evaluate
{ file = def &= help "Input file path(s) for evaluation.\n \
\ Defaults to stdin."
&= name "f" &= typ "FILE"
, form = TreeCalculus &= typ "FORM"
&= help "Optional output form: (tree|fsl|ast|ternary|ascii).\n \
\ Defaults to tricu-compatible `t` tree form."
&= name "t"
}
&= help "Evaluate tricu and return the result of the final expression."
&= explicit
&= name "eval"
decodeMode :: TricuArgs
decodeMode = Decode
{ file = def
&= help "Optional input file path to attempt decoding.\n \
\ Defaults to stdin."
&= name "f" &= typ "FILE"
}
&= help "Decode a Tree Calculus value into a string representation."
&= explicit
&= name "decode"
main :: IO () main :: IO ()
main = do main = do
putStrLn "Welcome to the Sapling Interpreter" args <- cmdArgs $ modes [replMode, evaluateMode, decodeMode]
putStrLn "You can exit at any time by typing and entering: " &= help "tricu: Exploring Tree Calculus"
putStrLn ":_exit" &= program "tricu"
repl library &= summary "tricu Evaluator and REPL"
case args of
Repl -> do
putStrLn "Welcome to the tricu REPL"
putStrLn "You can exit with `CTRL+D` or the `:_exit` command.`"
library <- liftIO $ evaluateFile "./lib/base.tri"
repl $ Map.delete "__result" library
Evaluate { file = filePaths, form = form } -> do
result <- case filePaths of
[] -> do
t <- getContents
pure $ runTricu t
(filePath:restFilePaths) -> do
initialEnv <- evaluateFile filePath
finalEnv <- foldM evaluateFileWithContext initialEnv restFilePaths
pure $ result finalEnv
let fRes = formatResult form result
putStr fRes
Decode { file = filePaths } -> do
value <- case filePaths of
[] -> getContents
(filePath:_) -> readFile filePath
library <- liftIO $ evaluateFile "./lib/base.tri"
putStrLn $ decodeResult $ result $ evalTricu library $ parseTricu value
runSapling :: String -> T runTricu :: String -> T
runSapling s = result (evalSapling Map.empty $ parseSapling s) runTricu input =
runSaplingEnv env s = result (evalSapling env $ parseSapling s) let asts = parseTricu input
finalEnv = evalTricu Map.empty asts
in result finalEnv

497
src/Parser.hs
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@ -1,255 +1,304 @@
module Parser where module Parser where
import Debug.Trace
import Lexer import Lexer
import Research hiding (toList) import Research
import Control.Exception (throw)
import Control.Monad (void)
import Control.Monad.State
import Data.List.NonEmpty (toList) import Data.List.NonEmpty (toList)
import qualified Data.Set as Set import Data.Void (Void)
import Data.Void
import Text.Megaparsec import Text.Megaparsec
import Text.Megaparsec.Char import Text.Megaparsec.Error (ParseErrorBundle, errorBundlePretty)
import Text.Megaparsec.Error (errorBundlePretty, ParseErrorBundle) import qualified Data.Set as Set
type Parser = Parsec Void [LToken] data PState = PState
{ parenDepth :: Int
, bracketDepth :: Int
} deriving (Show)
data SaplingAST type ParserM = StateT PState (Parsec Void [LToken])
= SVar String
| SInt Int
| SStr String
| SList [SaplingAST]
| SFunc String [String] SaplingAST
| SApp SaplingAST SaplingAST
| TLeaf
| TStem SaplingAST
| TFork SaplingAST SaplingAST
| SLambda [String] SaplingAST
deriving (Show, Eq, Ord)
parseSapling :: String -> [SaplingAST] satisfyM :: (LToken -> Bool) -> ParserM LToken
parseSapling input = satisfyM f = do
let nonEmptyLines = filter (not . null) (lines input) token <- lift (satisfy f)
in map parseSingle nonEmptyLines modify' (updateDepth token)
return token
parseSingle :: String -> SaplingAST updateDepth :: LToken -> PState -> PState
parseSingle input = case runParser parseExpression "" (lexSapling input) of updateDepth LOpenParen st = st { parenDepth = parenDepth st + 1 }
Left err -> error $ handleParseError err updateDepth LOpenBracket st = st { bracketDepth = bracketDepth st + 1 }
Right ast -> ast updateDepth LCloseParen st = st { parenDepth = parenDepth st - 1 }
updateDepth LCloseBracket st = st { bracketDepth = bracketDepth st - 1 }
updateDepth _ st = st
scnParser :: Parser () topLevelNewline :: ParserM ()
scnParser = skipMany (satisfy isNewline) topLevelNewline = do
st <- get
if parenDepth st == 0 && bracketDepth st == 0
then void (satisfyM (== LNewline))
else fail "Top-level exit in nested context (paren or bracket)"
parseExpression :: Parser SaplingAST parseProgram :: [LToken] -> Either (ParseErrorBundle [LToken] Void) [TricuAST]
parseExpression = choice parseProgram tokens =
[ try parseFunction runParser (evalStateT (parseProgramM <* finalizeDepth <* eof) (PState 0 0)) "" tokens
, try parseLambda
, try parseLambdaExpression parseSingleExpr :: [LToken] -> Either (ParseErrorBundle [LToken] Void) TricuAST
, try parseListLiteral parseSingleExpr tokens =
, try parseApplication runParser (evalStateT (scnParserM *> parseExpressionM <* finalizeDepth <* eof) (PState 0 0)) "" tokens
, try parseTreeTerm
, parseLiteral finalizeDepth :: ParserM ()
finalizeDepth = do
st <- get
case (parenDepth st, bracketDepth st) of
(0, 0) -> pure ()
(p, b) -> fail $ "Unmatched tokens: " ++ show (p, b)
parseTricu :: String -> [TricuAST]
parseTricu input =
case lexTricu input of
[] -> []
toks ->
case parseProgram toks of
Left err -> errorWithoutStackTrace (handleParseError err)
Right asts -> asts
parseSingle :: String -> TricuAST
parseSingle input =
case lexTricu input of
[] -> SEmpty
toks ->
case parseSingleExpr toks of
Left err -> errorWithoutStackTrace (handleParseError err)
Right ast -> ast
parseProgramM :: ParserM [TricuAST]
parseProgramM = do
skipMany topLevelNewline
exprs <- sepEndBy parseOneExpression (some topLevelNewline)
skipMany topLevelNewline
return exprs
parseOneExpression :: ParserM TricuAST
parseOneExpression = scnParserM *> parseExpressionM
scnParserM :: ParserM ()
scnParserM = skipMany $ do
t <- lookAhead anySingle
st <- get
if | (parenDepth st > 0 || bracketDepth st > 0) && case t of
LNewline -> True
_ -> False -> void $ satisfyM $ \case
LNewline -> True
_ -> False
| otherwise -> fail "In nested context or no space token" <|> empty
eofM :: ParserM ()
eofM = lift eof
parseExpressionM :: ParserM TricuAST
parseExpressionM = choice
[ try parseFunctionM
, try parseLambdaM
, try parseLambdaExpressionM
, try parseListLiteralM
, try parseApplicationM
, try parseTreeTermM
, parseLiteralM
] ]
parseFunction :: Parser SaplingAST parseFunctionM :: ParserM TricuAST
parseFunction = do parseFunctionM = do
LIdentifier name <- satisfy isIdentifier LIdentifier name <- satisfyM $ \case
args <- many (satisfy isIdentifier) LIdentifier _ -> True
satisfy (== LAssign) _ -> False
body <- parseExpression args <- many $ satisfyM $ \case
return (SFunc name (map getIdentifier args) body) LIdentifier _ -> True
_ -> False
_ <- satisfyM (== LAssign)
scnParserM
body <- parseExpressionM
pure (SFunc name (map getIdentifier args) body)
parseAtomicBase :: Parser SaplingAST parseLambdaM :: ParserM TricuAST
parseAtomicBase = choice parseLambdaM =
[ try parseVarWithoutAssignment between (satisfyM (== LOpenParen)) (satisfyM (== LCloseParen)) $ do
, parseTreeLeaf _ <- satisfyM (== LBackslash)
, parseGrouped param <- satisfyM $ \case
] LIdentifier _ -> True
parseVarWithoutAssignment :: Parser SaplingAST _ -> False
parseVarWithoutAssignment = do rest <- many $ satisfyM $ \case
LIdentifier name <- satisfy isIdentifier LIdentifier _ -> True
if (name == "t" || name == "__result") _ -> False
then fail $ "Reserved keyword: " ++ name ++ " cannot be assigned." _ <- satisfyM (== LColon)
else notFollowedBy (satisfy (== LAssign)) *> return (SVar name) scnParserM
body <- parseLambdaExpressionM
let nested = foldr (\v acc -> SLambda [getIdentifier v] acc) body rest
pure (SLambda [getIdentifier param] nested)
parseLambda :: Parser SaplingAST parseLambdaExpressionM :: ParserM TricuAST
parseLambda = between (satisfy (== LOpenParen)) (satisfy (== LCloseParen)) $ do parseLambdaExpressionM = choice
satisfy (== LBackslash) [ try parseLambdaApplicationM
param <- satisfy isIdentifier , parseAtomicLambdaM
rest <- many (satisfy isIdentifier)
satisfy (== LColon)
body <- parseLambdaExpression
let nestedLambda = foldr (\v acc -> SLambda [v] acc) body (map getIdentifier rest)
return (SLambda [getIdentifier param] nestedLambda)
parseLambdaExpression :: Parser SaplingAST
parseLambdaExpression = choice
[ try parseLambdaApplication
, parseAtomicLambda
] ]
parseAtomicLambda :: Parser SaplingAST parseAtomicLambdaM :: ParserM TricuAST
parseAtomicLambda = choice parseAtomicLambdaM = choice
[ parseVar [ parseVarM
, parseTreeLeaf , parseTreeLeafM
, parseLiteral , parseLiteralM
, parseListLiteral , parseListLiteralM
, try parseLambda , try parseLambdaM
, between (satisfy (== LOpenParen)) (satisfy (== LCloseParen)) parseLambdaExpression , between (satisfyM (== LOpenParen)) (satisfyM (== LCloseParen)) parseLambdaExpressionM
] ]
parseApplication :: Parser SaplingAST parseApplicationM :: ParserM TricuAST
parseApplication = do parseApplicationM = do
func <- parseAtomicBase func <- parseAtomicBaseM
args <- many parseAtomic scnParserM
return $ foldl (\acc arg -> SApp acc arg) func args args <- many $ do
scnParserM
arg <- parseAtomicM
return arg
return $ foldl SApp func args
parseLambdaApplication :: Parser SaplingAST parseLambdaApplicationM :: ParserM TricuAST
parseLambdaApplication = do parseLambdaApplicationM = do
func <- parseAtomicLambda func <- parseAtomicLambdaM
args <- many parseAtomicLambda scnParserM
return $ foldl (\acc arg -> SApp acc arg) func args args <- many $ do
arg <- parseAtomicLambdaM
scnParserM
pure arg
pure $ foldl SApp func args
isTreeTerm :: SaplingAST -> Bool parseAtomicBaseM :: ParserM TricuAST
isTreeTerm TLeaf = True parseAtomicBaseM = choice
isTreeTerm (TStem _) = True [ parseTreeLeafM
isTreeTerm (TFork _ _) = True , parseGroupedM
isTreeTerm _ = False ]
parseTreeLeaf :: Parser SaplingAST parseTreeLeafM :: ParserM TricuAST
parseTreeLeaf = satisfy isKeywordT *> notFollowedBy (satisfy (== LAssign)) *> pure TLeaf parseTreeLeafM = do
_ <- satisfyM $ \case
LKeywordT -> True
_ -> False
notFollowedBy $ lift $ satisfy (== LAssign)
pure TLeaf
parseTreeTermM :: ParserM TricuAST
parseTreeTermM = do
base <- parseTreeLeafOrParenthesizedM
rest <- many parseTreeLeafOrParenthesizedM
pure (foldl combine base rest)
where
combine acc next
| TLeaf <- acc = TStem next
| TStem t <- acc = TFork t next
| TFork _ _ <- acc = TFork acc next
parseTreeLeafOrParenthesizedM :: ParserM TricuAST
parseTreeLeafOrParenthesizedM = choice
[ between (satisfyM (== LOpenParen)) (satisfyM (== LCloseParen)) parseTreeTermM
, parseTreeLeafM
]
parseAtomicM :: ParserM TricuAST
parseAtomicM = choice
[ parseVarM
, parseTreeLeafM
, parseListLiteralM
, parseGroupedM
, parseLiteralM
]
parseGroupedM :: ParserM TricuAST
parseGroupedM = between (satisfyM (== LOpenParen)) (satisfyM (== LCloseParen)) $
scnParserM *> parseExpressionM <* scnParserM
parseLiteralM :: ParserM TricuAST
parseLiteralM = choice
[ parseIntLiteralM
, parseStrLiteralM
]
parseListLiteralM :: ParserM TricuAST
parseListLiteralM = do
_ <- satisfyM (== LOpenBracket)
elements <- many $ do
scnParserM
parseListItemM
scnParserM
_ <- satisfyM (== LCloseBracket)
pure (SList elements)
parseListItemM :: ParserM TricuAST
parseListItemM = choice
[ parseGroupedItemM
, parseListLiteralM
, parseSingleItemM
]
parseGroupedItemM :: ParserM TricuAST
parseGroupedItemM = do
_ <- satisfyM (== LOpenParen)
inner <- parseExpressionM
_ <- satisfyM (== LCloseParen)
pure inner
parseSingleItemM :: ParserM TricuAST
parseSingleItemM = do
token <- satisfyM $ \case
LIdentifier _ -> True
LKeywordT -> True
_ -> False
case token of
LIdentifier name -> pure (SVar name)
LKeywordT -> pure TLeaf
_ -> fail "Unexpected token in list item"
parseVarM :: ParserM TricuAST
parseVarM = do
LIdentifier name <- satisfyM $ \case
LIdentifier _ -> True
_ -> False
if name == "t" || name == "__result"
then fail ("Reserved keyword: " ++ name ++ " cannot be assigned.")
else pure (SVar name)
parseIntLiteralM :: ParserM TricuAST
parseIntLiteralM = do
LIntegerLiteral value <- satisfyM $ \case
LIntegerLiteral _ -> True
_ -> False
pure (SInt value)
parseStrLiteralM :: ParserM TricuAST
parseStrLiteralM = do
LStringLiteral value <- satisfyM $ \case
LStringLiteral _ -> True
_ -> False
pure (SStr value)
getIdentifier :: LToken -> String getIdentifier :: LToken -> String
getIdentifier (LIdentifier name) = name getIdentifier (LIdentifier name) = name
getIdentifier _ = error "Expected identifier" getIdentifier _ = errorWithoutStackTrace "Expected identifier"
parseTreeTerm :: Parser SaplingAST
parseTreeTerm = do
base <- parseTreeLeafOrParenthesized
rest <- many parseTreeLeafOrParenthesized
pure $ foldl combine base rest
where
combine acc next = case acc of
TLeaf -> TStem next
TStem t -> TFork t next
TFork _ _ -> TFork acc next
parseTreeLeafOrParenthesized :: Parser SaplingAST
parseTreeLeafOrParenthesized = choice
[ between (satisfy (== LOpenParen)) (satisfy (== LCloseParen)) parseTreeTerm
, parseTreeLeaf
]
foldTree :: [SaplingAST] -> SaplingAST
foldTree [] = TLeaf
foldTree [x] = x
foldTree (x:y:rest) = TFork x (foldTree (y:rest))
parseAtomic :: Parser SaplingAST
parseAtomic = choice
[ parseVar
, parseTreeLeaf
, parseListLiteral
, parseGrouped
, parseLiteral
]
parseGrouped :: Parser SaplingAST
parseGrouped = between (satisfy (== LOpenParen)) (satisfy (== LCloseParen)) parseExpression
parseLiteral :: Parser SaplingAST
parseLiteral = choice
[ parseIntLiteral
, parseStrLiteral
]
parens :: Parser SaplingAST -> Parser SaplingAST
parens p = do
satisfy (== LOpenParen)
result <- p
satisfy (== LCloseParen)
return result
parseListLiteral :: Parser SaplingAST
parseListLiteral = do
satisfy (== LOpenBracket)
elements <- many parseListItem
satisfy (== LCloseBracket)
return (SList elements)
parseListItem :: Parser SaplingAST
parseListItem = choice
[ parseGroupedItem
, parseListLiteral
, parseSingleItem
]
parseGroupedItem :: Parser SaplingAST
parseGroupedItem = do
satisfy (== LOpenParen)
inner <- parseExpression
satisfy (== LCloseParen)
return inner
parseSingleItem :: Parser SaplingAST
parseSingleItem = do
token <- satisfy isListItem
case token of
LIdentifier name -> return (SVar name)
LKeywordT -> return TLeaf
_ -> fail "Unexpected token in list item"
isListItem :: LToken -> Bool
isListItem (LIdentifier _) = True
isListItem LKeywordT = True
isListItem _ = False
parseVar :: Parser SaplingAST
parseVar = do
LIdentifier name <- satisfy isIdentifier
if (name == "t" || name == "__result")
then fail $ "Reserved keyword: " ++ name ++ " cannot be assigned."
else return (SVar name)
parseIntLiteral :: Parser SaplingAST
parseIntLiteral = do
LIntegerLiteral value <- satisfy isIntegerLiteral
return (SInt value)
parseStrLiteral :: Parser SaplingAST
parseStrLiteral = do
LStringLiteral value <- satisfy isStringLiteral
return (SStr value)
-- Boolean Helpers
isKeywordT (LKeywordT) = True
isKeywordT _ = False
isIdentifier (LIdentifier _) = True
isIdentifier _ = False
isIntegerLiteral (LIntegerLiteral _) = True
isIntegerLiteral _ = False
isStringLiteral (LStringLiteral _) = True
isStringLiteral _ = False
isLiteral (LIntegerLiteral _) = True
isLiteral (LStringLiteral _) = True
isLiteral _ = False
isNewline (LNewline) = True
isNewline _ = False
-- Error Handling
handleParseError :: ParseErrorBundle [LToken] Void -> String handleParseError :: ParseErrorBundle [LToken] Void -> String
handleParseError bundle = handleParseError bundle =
let errors = bundleErrors bundle let errors = bundleErrors bundle
errorList = toList errors formattedErrors = map formatError (Data.List.NonEmpty.toList errors)
formattedErrors = map showError errorList
in unlines ("Parse error(s) encountered:" : formattedErrors) in unlines ("Parse error(s) encountered:" : formattedErrors)
showError :: ParseError [LToken] Void -> String formatError :: ParseError [LToken] Void -> String
showError (TrivialError offset (Just (Tokens tokenStream)) expected) = formatError (TrivialError offset unexpected expected) =
"Parse error at offset " ++ show offset ++ ": unexpected token " let unexpectedMsg = case unexpected of
++ show tokenStream ++ ", expected one of " ++ show (Set.toList expected) Just x -> "unexpected token " ++ show x
showError (FancyError offset fancy) = Nothing -> "unexpected end of input"
"Parse error at offset " ++ show offset ++ ":\n " ++ unlines (map show (Set.toList fancy)) expectedMsg = if null expected
showError (TrivialError offset Nothing expected) = then ""
"Parse error at offset " ++ show offset ++ ": expected one of " else "expected " ++ show (Set.toList expected)
++ show (Set.toList expected) in "Parse error at offset " ++ show offset ++ ": " ++ unexpectedMsg ++
if null expectedMsg then "" else " " ++ expectedMsg
formatError (FancyError offset _) =
"Parse error at offset " ++ show offset ++ ": unexpected FancyError"

78
src/REPL.hs
View File

@ -1,42 +1,68 @@
module REPL where module REPL where
import Eval import Eval
import FileEval
import Lexer import Lexer
import Parser import Parser
import Research import Research
import Data.List (intercalate) import Control.Exception (SomeException, catch)
import qualified Data.Map as Map import Control.Monad.IO.Class (liftIO)
import Data.Char (isSpace)
import Data.List (dropWhile, dropWhileEnd, intercalate)
import System.Console.Haskeline import System.Console.Haskeline
import System.IO (hFlush, stdout)
repl :: Map.Map String T -> IO () import qualified Data.Map as Map
repl :: Env -> IO ()
repl env = runInputT defaultSettings (loop env) repl env = runInputT defaultSettings (loop env)
where where
loop :: Map.Map String T -> InputT IO () loop :: Env -> InputT IO ()
loop env = do loop env = do
minput <- getInputLine "sapling < " minput <- getInputLine "tricu < "
case minput of if
Nothing -> outputStrLn "Goodbye!" | Nothing <- minput -> outputStrLn "Exiting tricu"
Just ":_exit" -> outputStrLn "Goodbye!" | Just s <- minput, strip s == "!exit" -> outputStrLn "Exiting tricu"
Just "" -> do | Just s <- minput, strip s == "" -> do
outputStrLn "" outputStrLn ""
loop env loop env
Just input -> do | Just s <- minput, strip s == "!load" -> do
let clearEnv = Map.delete "__result" env path <- getInputLine "File path to load < "
newEnv = evalSingle clearEnv (parseSingle input) if
case Map.lookup "__result" newEnv of | Nothing <- path -> do
Just r -> do outputStrLn "No input received; stopping import."
outputStrLn $ "sapling > " ++ show r loop env
outputStrLn $ "DECODE -: " ++ decodeResult r | Just p <- path -> do
Nothing -> return () loadedEnv <- liftIO $ evaluateFileWithContext env (strip p) `catch` \e -> errorHandler env e
loop newEnv loop $ Map.delete "__result" (Map.union loadedEnv env)
| Just s <- minput -> do
if
| take 2 s == "--" -> loop env
| otherwise -> do
newEnv <- liftIO $ processInput env s `catch` errorHandler env
loop newEnv
processInput :: Env -> String -> IO Env
processInput env input = do
let asts = parseTricu input
newEnv = evalTricu env asts
if
| Just r <- Map.lookup "__result" newEnv -> do
putStrLn $ "tricu > " ++ decodeResult r
| otherwise -> return ()
return newEnv
errorHandler :: Env -> SomeException -> IO (Env)
errorHandler env e = do
putStrLn $ "Error: " ++ show e
return env
strip :: String -> String
strip = dropWhileEnd isSpace . dropWhile isSpace
decodeResult :: T -> String decodeResult :: T -> String
decodeResult tc = case toNumber tc of decodeResult tc
Right num -> show num | Right num <- toNumber tc = show num
Left _ -> case toString tc of | Right str <- toString tc = "\"" ++ str ++ "\""
Right str -> "\"" ++ str ++ "\"" | Right list <- toList tc = "[" ++ intercalate ", " (map decodeResult list) ++ "]"
Left _ -> case toList tc of | otherwise = formatResult TreeCalculus tc
Right list -> "[" ++ intercalate ", " (map decodeResult list) ++ "]"
Left _ -> ""

138
src/Research.hs
View File

@ -1,13 +1,57 @@
module Research where module Research where
import Data.List (intercalate)
import Control.Monad.State import Control.Monad.State
import qualified Data.Map as Map import Data.List (intercalate)
import Data.Map (Map) import Data.Map (Map)
import Data.Text (Text, replace)
import System.Console.CmdArgs (Data, Typeable)
import qualified Data.Map as Map
import qualified Data.Text as T
-- Tree Calculus Types
data T = Leaf | Stem T | Fork T T data T = Leaf | Stem T | Fork T T
deriving (Show, Eq, Ord) deriving (Show, Eq, Ord)
-- Abstract Syntax Tree for tricu
data TricuAST
= SVar String
| SInt Int
| SStr String
| SList [TricuAST]
| SFunc String [String] TricuAST
| SApp TricuAST TricuAST
| TLeaf
| TStem TricuAST
| TFork TricuAST TricuAST
| SLambda [String] TricuAST
| SEmpty
deriving (Show, Eq, Ord)
-- Lexer Tokens
data LToken
= LKeywordT
| LIdentifier String
| LIntegerLiteral Int
| LStringLiteral String
| LAssign
| LColon
| LBackslash
| LOpenParen
| LCloseParen
| LOpenBracket
| LCloseBracket
| LNewline
deriving (Show, Eq, Ord)
-- Output formats
data EvaluatedForm = TreeCalculus | FSL | AST | Ternary | Ascii
deriving (Show, Data, Typeable)
-- Environment containing previously evaluated TC terms
type Env = Map.Map String T
-- Tree Calculus Reduction
apply :: T -> T -> T apply :: T -> T -> T
apply Leaf b = Stem b apply Leaf b = Stem b
apply (Stem a) b = Fork a b apply (Stem a) b = Fork a b
@ -17,29 +61,6 @@ apply (Fork (Fork a1 a2) a3) Leaf = a1
apply (Fork (Fork a1 a2) a3) (Stem u) = apply a2 u apply (Fork (Fork a1 a2) a3) (Stem u) = apply a2 u
apply (Fork (Fork a1 a2) a3) (Fork u v) = apply (apply a3 u) v apply (Fork (Fork a1 a2) a3) (Fork u v) = apply (apply a3 u) v
reduce :: T -> T
reduce expr =
let next = step expr
in if next == expr then expr else reduce next
step :: T -> T
step (Fork left right) = reduce (apply (reduce left) (reduce right))
step (Stem inner) = Stem (reduce inner)
step t = t
-- SKI Combinators
_S :: T
_S = Fork (Stem (Fork Leaf Leaf)) Leaf
_K :: T
_K = Stem Leaf
-- Identity
-- We use the "point-free" style which drops a redundant node
-- Full _I form (SKK): Fork (Stem (Stem Leaf)) (Stem Leaf)
_I :: T
_I = Fork (Stem (Stem Leaf)) Leaf
-- Booleans -- Booleans
_false :: T _false :: T
_false = Leaf _false = Leaf
@ -87,7 +108,31 @@ toList (Fork x rest) = case toList rest of
Left err -> Left err Left err -> Left err
toList _ = Left "Invalid Tree Calculus list" toList _ = Left "Invalid Tree Calculus list"
-- Utility -- Outputs
formatResult :: EvaluatedForm -> T -> String
formatResult TreeCalculus = toSimpleT . show
formatResult FSL = show
formatResult AST = show . toAST
formatResult Ternary = toTernaryString
formatResult Ascii = toAscii
toSimpleT :: String -> String
toSimpleT s = T.unpack
$ replace "Fork" "t"
$ replace "Stem" "t"
$ replace "Leaf" "t"
$ (T.pack s)
toTernaryString :: T -> String
toTernaryString Leaf = "0"
toTernaryString (Stem t) = "1" ++ toTernaryString t
toTernaryString (Fork t1 t2) = "2" ++ toTernaryString t1 ++ toTernaryString t2
toAST :: T -> TricuAST
toAST Leaf = TLeaf
toAST (Stem a) = TStem (toAST a)
toAST (Fork a b) = TFork (toAST a) (toAST b)
toAscii :: T -> String toAscii :: T -> String
toAscii tree = go tree "" True toAscii tree = go tree "" True
where where
@ -102,41 +147,4 @@ 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
rules :: IO () -- Utility
rules = putStr $ header
++ (unlines $ tcRules)
++ (unlines $ haskellRules)
++ footer
where
tcRules :: [String]
tcRules =
[ "| |"
, "| ┌--------- | Tree Calculus | ---------┐ |"
, "| | 1. t t a b -> a | |"
, "| | 2. t (t a) b c -> a c (b c)| |"
, "| | 3a. t (t a b) c t -> a | |"
, "| | 3b. t (t a b) c (t u) -> b u | |"
, "| | 3c. t (t a b) c (t u v) -> c u v | |"
, "| └-------------------------------------┘ |"
, "| |"
]
haskellRules :: [String]
haskellRules =
[ "| ┌------------------------------ | Haskell | --------------------------------┐ |"
, "| | | |"
, "| | data T = Leaf | Stem T | Fork TT | |"
, "| | | |"
, "| | apply :: T -> T -> T | |"
, "| | apply Leaf b = Stem b | |"
, "| | apply (Stem a) b = Fork a b | |"
, "| | apply (Fork Leaf a) _ = a | |"
, "| | apply (Fork (Stem a1) a2) b = apply (apply a1 b) (apply a2 b) | |"
, "| | apply (Fork (Fork a1 a2) a3) Leaf = a1 | |"
, "| | apply (Fork (Fork a1 a2) a3) (Stem u) = apply a2 u | |"
, "| | apply (Fork (Fork a1 a2) a3) (Fork u v) = apply (apply a3 u) v | |"
, "| └---------------------------------------------------------------------------┘ |"
]
header :: String
header = "┌-------------------- | Rules for evaluating Tree Calculus | -------------------┐\n"
footer :: String
footer = "└-------------------- | Rules for evaluating Tree Calculus | -------------------┘\n"

279
test/Spec.hs
View File

@ -1,11 +1,14 @@
module Main where module Main where
import Eval import Eval
import FileEval
import Lexer import Lexer
import Library
import Parser import Parser
import REPL
import Research import Research
import Control.Exception (evaluate, try, SomeException) import Control.Exception (evaluate, try, SomeException)
import Control.Monad.IO.Class (liftIO)
import Test.Tasty import Test.Tasty
import Test.Tasty.HUnit import Test.Tasty.HUnit
import Test.Tasty.QuickCheck import Test.Tasty.QuickCheck
@ -17,17 +20,17 @@ import qualified Data.Set as Set
main :: IO () main :: IO ()
main = defaultMain tests main = defaultMain tests
runSapling :: String -> String runTricu :: String -> String
runSapling s = show $ result (evalSapling Map.empty $ parseSapling s) runTricu s = show $ result (evalTricu Map.empty $ parseTricu s)
tests :: TestTree tests :: TestTree
tests = testGroup "Sapling Tests" tests = testGroup "Tricu Tests"
[ lexerTests [ lexerTests
, parserTests , parserTests
, integrationTests
, evaluationTests , evaluationTests
, lambdaEvalTests , lambdaEvalTests
, propertyTests , libraryTests
, fileEvaluationTests
] ]
lexerTests :: TestTree lexerTests :: TestTree
@ -35,47 +38,42 @@ lexerTests = 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 saplingLexer "" 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 saplingLexer "" 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 saplingLexer "" 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 saplingLexer "" input @?= expect runParser tricuLexer "" input @?= expect
, testCase "Lex invalid token" $ do , testCase "Lex invalid token" $ do
let input = "$invalid" let input = "&invalid"
case runParser saplingLexer "" 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 saplingLexer "" 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 saplingLexer "" "__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 parserTests :: TestTree
parserTests = testGroup "Parser Tests" parserTests = testGroup "Parser Tests"
[ --testCase "Error when parsing incomplete definitions" $ do [ testCase "Error when assigning a value to T" $ do
-- let input = lexSapling "x = " let tokens = lexTricu "t = x"
-- case (runParser parseExpression "" input) of case parseSingleExpr tokens of
-- Left _ -> return () Left _ -> return ()
-- Right _ -> assertFailure "Expected failure on invalid input"
testCase "Error when assigning a value to T" $ do
let input = lexSapling "t = x"
case (runParser parseExpression "" input) of
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)"
@ -142,19 +140,15 @@ parserTests = testGroup "Parser Tests"
, 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 = [SFunc "x" [] (SLambda ["a"] (SVar "a")),SApp (SVar "x") TLeaf]
parseSapling input @?= expect parseTricu input @?= expect
] , testCase "Comments 1" $ do
let input = "(t) (t) -- (t)"
integrationTests :: TestTree expect = [SApp TLeaf TLeaf]
integrationTests = testGroup "Integration Tests" parseTricu input @?= expect
[ testCase "Combine lexer and parser" $ do , testCase "Comments 2" $ do
let input = "x = t t t" let input = "(t) -- (t) -- (t)"
expect = SFunc "x" [] (SApp (SApp TLeaf TLeaf) TLeaf) expect = [TLeaf]
parseSingle input @?= expect parseTricu input @?= expect
, testCase "Complex Tree Calculus expression" $ do
let input = "t (t t t) t"
expect = SApp (SApp TLeaf (SApp (SApp TLeaf TLeaf) TLeaf)) TLeaf
parseSingle input @?= expect
] ]
evaluationTests :: TestTree evaluationTests :: TestTree
@ -182,16 +176,16 @@ evaluationTests = testGroup "Evaluation Tests"
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 = evalSapling Map.empty (parseSapling 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 = evalSapling Map.empty (parseSapling 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 = evalSapling Map.empty (parseSapling 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\""
@ -211,110 +205,207 @@ evaluationTests = testGroup "Evaluation Tests"
\ z = y\n \ \ z = y\n \
\ variablewithamuchlongername = z\n \ \ variablewithamuchlongername = z\n \
\ variablewithamuchlongername" \ variablewithamuchlongername"
env = evalSapling Map.empty (parseSapling input) env = evalTricu Map.empty (parseTricu input)
(result env) @?= (Stem (Stem Leaf)) (result env) @?= (Stem (Stem Leaf))
, testCase "Evaluate variable shadowing" $ do , testCase "Evaluate variable shadowing" $ do
let input = "x = t t\nx = t\nx" let input = "x = t t\nx = t\nx"
env = evalSapling Map.empty (parseSapling input) env = evalTricu Map.empty (parseTricu input)
(result env) @?= Leaf (result env) @?= Leaf
, 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
env = evalSapling Map.empty (parseSapling input) env = evalTricu Map.empty (parseTricu input)
result env @?= Fork (Fork (Stem Leaf) (Fork Leaf Leaf)) Leaf result env @?= Fork (Fork (Stem Leaf) (Fork Leaf Leaf)) Leaf
, testCase "Constant function matches" $ do
let input = "k = (\\a b : a)\nk (t t) t"
env = evalSapling Map.empty (parseSapling input)
result env @?= Stem Leaf
, testCase "Boolean AND_ TF" $ do
let input = "and (t t) (t)"
env = evalSapling library (parseSapling input)
result env @?= Leaf
, testCase "Boolean AND_ FT" $ do
let input = "and (t) (t t)"
env = evalSapling library (parseSapling input)
result env @?= Leaf
, testCase "Boolean AND_ FF" $ do
let input = "and (t) (t)"
env = evalSapling library (parseSapling input)
result env @?= Leaf
, testCase "Boolean AND_ TT" $ do
let input = "and (t t) (t t)"
env = evalSapling library (parseSapling input)
result env @?= Stem Leaf
, testCase "Verifying Equality" $ do
let input = "equal (t t t) (t t t)"
env = evalSapling library (parseSapling input)
result env @?= Stem Leaf
] ]
lambdaEvalTests :: TestTree lambdaEvalTests :: TestTree
lambdaEvalTests = testGroup "Lambda Evaluation Tests" lambdaEvalTests = 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"
runSapling 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)"
runSapling 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"
runSapling 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)"
runSapling 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"
runSapling 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"
runSapling 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)"
runSapling 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)"
runSapling 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)"
runSapling 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"
runSapling 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)"
runSapling 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)"
runSapling 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"
runSapling 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)"
runSapling 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"
runSapling 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"
runSapling 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\""
runSapling 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"
runSapling 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)]"
runSapling input @?= "Fork Leaf (Fork (Stem Leaf) Leaf)" runTricu input @?= "Fork Leaf (Fork (Stem Leaf) Leaf)"
] ]
propertyTests :: TestTree libraryTests :: TestTree
propertyTests = testGroup "Property Tests" libraryTests = testGroup "Library Tests"
[ testProperty "Lexing and parsing round-trip" $ \input -> [ testCase "K combinator 1" $ do
case runParser saplingLexer "" input of library <- evaluateFile "./lib/base.tri"
Left _ -> property True let input = "k (t) (t t)"
Right tokens -> case runParser parseExpression "" tokens of env = evalTricu library (parseTricu input)
Left _ -> property True result env @?= Leaf
Right ast -> parseSingle input === ast , testCase "K combinator 2" $ do
library <- evaluateFile "./lib/base.tri"
let input = "k (t t) (t)"
env = evalTricu library (parseTricu input)
result env @?= Stem Leaf
, testCase "K combinator 3" $ do
library <- evaluateFile "./lib/base.tri"
let input = "k (t t t) (t)"
env = evalTricu library (parseTricu input)
result env @?= Fork Leaf Leaf
, testCase "S combinator" $ do
library <- evaluateFile "./lib/base.tri"
let input = "s (t) (t) (t)"
env = evalTricu library (parseTricu input)
result env @?= Fork Leaf (Stem Leaf)
, testCase "SKK == I (fully expanded)" $ do
library <- evaluateFile "./lib/base.tri"
let input = "s k k"
env = evalTricu library (parseTricu input)
result env @?= Fork (Stem (Stem Leaf)) (Stem Leaf)
, testCase "I combinator" $ do
library <- evaluateFile "./lib/base.tri"
let input = "i not?"
env = evalTricu library (parseTricu input)
result env @?= Fork (Fork (Stem Leaf) (Fork Leaf Leaf)) (Fork Leaf (Fork Leaf Leaf))
, testCase "Triage test Leaf" $ do
library <- evaluateFile "./lib/base.tri"
let input = "test t"
env = decodeResult $ result $ evalTricu library (parseTricu input)
env @?= "\"Leaf\""
, testCase "Triage test (Stem Leaf)" $ do
library <- evaluateFile "./lib/base.tri"
let input = "test (t t)"
env = decodeResult $ result $ evalTricu library (parseTricu input)
env @?= "\"Stem\""
, testCase "Triage test (Fork Leaf Leaf)" $ do
library <- evaluateFile "./lib/base.tri"
let input = "test (t t t)"
env = decodeResult $ result $ evalTricu library (parseTricu input)
env @?= "\"Fork\""
, testCase "Boolean NOT: true" $ do
library <- evaluateFile "./lib/base.tri"
let input = "not? true"
env = result $ evalTricu library (parseTricu input)
env @?= Leaf
, testCase "Boolean NOT: false" $ do
library <- evaluateFile "./lib/base.tri"
let input = "not? false"
env = result $ evalTricu library (parseTricu input)
env @?= Stem Leaf
, testCase "Boolean AND TF" $ do
library <- evaluateFile "./lib/base.tri"
let input = "and? (t t) (t)"
env = evalTricu library (parseTricu input)
result env @?= Leaf
, testCase "Boolean AND FT" $ do
library <- evaluateFile "./lib/base.tri"
let input = "and? (t) (t t)"
env = evalTricu library (parseTricu input)
result env @?= Leaf
, testCase "Boolean AND FF" $ do
library <- evaluateFile "./lib/base.tri"
let input = "and? (t) (t)"
env = evalTricu library (parseTricu input)
result env @?= Leaf
, testCase "Boolean AND TT" $ do
library <- evaluateFile "./lib/base.tri"
let input = "and? (t t) (t t)"
env = evalTricu library (parseTricu input)
result env @?= Stem Leaf
, testCase "List head" $ do
library <- evaluateFile "./lib/base.tri"
let input = "head [(t) (t t) (t t t)]"
env = evalTricu library (parseTricu input)
result env @?= Leaf
, testCase "List tail" $ do
library <- evaluateFile "./lib/base.tri"
let input = "head (tail (tail [(t) (t t) (t t t)]))"
env = evalTricu library (parseTricu input)
result env @?= Fork Leaf Leaf
, testCase "List map" $ do
library <- evaluateFile "./lib/base.tri"
let input = "head (tail (map (\\a : (t t t)) [(t) (t) (t)]))"
env = evalTricu library (parseTricu input)
result env @?= Fork Leaf Leaf
, testCase "Empty list check" $ do
library <- evaluateFile "./lib/base.tri"
let input = "emptyList? []"
env = evalTricu library (parseTricu input)
result env @?= Stem Leaf
, testCase "Non-empty list check" $ do
library <- evaluateFile "./lib/base.tri"
let input = "not? (emptyList? [(1) (2) (3)])"
env = evalTricu library (parseTricu input)
result env @?= Stem Leaf
, testCase "Concatenate strings" $ do
library <- evaluateFile "./lib/base.tri"
let input = "lconcat \"Hello, \" \"world!\""
env = decodeResult $ result $ evalTricu library (parseTricu input)
env @?= "\"Hello, world!\""
, testCase "Verifying Equality" $ do
library <- evaluateFile "./lib/base.tri"
let input = "equal? (t t t) (t t t)"
env = evalTricu library (parseTricu input)
result env @?= Stem Leaf
]
fileEvaluationTests :: TestTree
fileEvaluationTests = testGroup "Evaluation tests"
[ testCase "Forks" $ do
res <- liftIO $ evaluateFileResult "./test/fork.tri"
res @?= Fork Leaf Leaf
, testCase "File ends with comment" $ do
res <- liftIO $ evaluateFileResult "./test/comments-1.tri"
res @?= Fork (Stem Leaf) Leaf
, testCase "Mapping and Equality" $ do
res <- liftIO $ evaluateFileResult "./test/map.tri"
res @?= Stem Leaf
, testCase "Eval and decoding string" $ do
library <- liftIO $ evaluateFile "./lib/base.tri"
res <- liftIO $ evaluateFileWithContext library "./test/string.tri"
decodeResult (result res) @?= "\"String test!\""
] ]

1
test/ascii.tri Normal file
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@ -0,0 +1 @@
t (t (t (t (t t) (t t t)) t) t t) t

1
test/assignment.tri Normal file
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@ -0,0 +1 @@
x = t (t t) t

9
test/comments-1.tri Normal file
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@ -0,0 +1,9 @@
-- This is a tricu comment!
-- t (t t) (t (t t t))
-- t (t t t) (t t)
-- x = (\a : a)
t (t t) t -- Fork (Stem Leaf) Leaf
-- t t
-- x
-- x = (\a : a)
-- t

1
test/fork.tri Normal file
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@ -0,0 +1 @@
t t t

24
test/map.tri Normal file
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@ -0,0 +1,24 @@
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!")]
equal x [("Successfully concatenated two strings!")]

1
test/string.tri Normal file
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@ -0,0 +1 @@
head (map (\i : lconcat "String " i) [("test!")])

31
sapling.cabal → tricu.cabal
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@ -1,7 +1,7 @@
cabal-version: 1.12 cabal-version: 1.12
name: sapling name: tricu
version: 0.4.0 version: 0.7.0
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
@ -12,41 +12,45 @@ build-type: Simple
extra-source-files: extra-source-files:
README.md README.md
executable sapling executable tricu
main-is: Main.hs main-is: Main.hs
hs-source-dirs: hs-source-dirs:
src src
default-extensions: default-extensions:
ConstraintKinds DeriveDataTypeable
DataKinds LambdaCase
DeriveGeneric MultiWayIf
FlexibleContexts
FlexibleInstances
GeneralizedNewtypeDeriving
OverloadedStrings OverloadedStrings
ScopedTypeVariables
ghc-options: -threaded -rtsopts -with-rtsopts=-N -optl-pthread -fPIC ghc-options: -threaded -rtsopts -with-rtsopts=-N -optl-pthread -fPIC
build-depends: build-depends:
base >=4.7 base >=4.7
, cmdargs
, containers , containers
, haskeline , haskeline
, megaparsec , megaparsec
, mtl , mtl
, text
other-modules: other-modules:
Eval Eval
FileEval
Lexer Lexer
Library
Parser Parser
REPL REPL
Research Research
default-language: Haskell2010 default-language: Haskell2010
test-suite sapling-tests test-suite tricu-tests
type: exitcode-stdio-1.0 type: exitcode-stdio-1.0
main-is: Spec.hs main-is: Spec.hs
hs-source-dirs: test, src hs-source-dirs: test, src
default-extensions:
DeriveDataTypeable
LambdaCase
MultiWayIf
OverloadedStrings
build-depends: build-depends:
base base
, cmdargs
, containers , containers
, haskeline , haskeline
, megaparsec , megaparsec
@ -54,11 +58,12 @@ test-suite sapling-tests
, tasty , tasty
, tasty-hunit , tasty-hunit
, tasty-quickcheck , tasty-quickcheck
, text
default-language: Haskell2010 default-language: Haskell2010
other-modules: other-modules:
Eval Eval
FileEval
Lexer Lexer
Library
Parser Parser
REPL REPL
Research Research