teliva/lisp.lua

-- atom types:
--   nil
--   true
--   {num=3.4}
--   {char='a'}
--   {str='bc'}
--   {sym='foo'}
-- non-atom type:
--   {car={num=3.4}, cdr=nil}
--
-- should {} mean anything special? currently just '(nil)
function atom(x)
  return x == nil or x.num or x.char or x.str or x.sym
end

function car(x) return x.car end
function cdr(x) return x.cdr end
function cons(x, y) return {car=x, cdr=y} end

function iso(x, y)
  if x == nil then return y == nil end
  local done={}
  if done[x] then return done[x] == y end
  done[x] = y
  if atom(x) then
    if not atom(y) then return nil end
    for k, v in pairs(x) do
      if y[k] ~= v then return nil end
    end
    return true
  end
  for k, v in pairs(x) do
    if not iso(y[k], v) then return nil end
  end
  for k, v in pairs(y) do
    if not iso(x[k], v) then return nil end
  end
  return true
end

-- primitives; feel free to add more
-- format: lisp name = lua function that implements it
unary_functions = {
  atom=atom,
  car=car,
  cdr=cdr,
}

binary_functions = {
  cons=cons,
  iso=iso,
}

function lookup(env, s)
  if env[s] then return env[s] end
  if env.next then return lookup(env.next, s) end
end

function eval(x, env)
  function symeq(x, s)
    return x and x.sym == s
  end
  if x.sym then
    return lookup(env, x.sym)
  elseif atom(x) then
    return x
  -- otherwise x is a pair
  elseif symeq(x.car, 'quote') then
    return x.cdr
  elseif unary_functions[x.car.sym] then
    return eval_unary(x, env)
  elseif binary_functions[x.car.sym] then
    return eval_binary(x, env)
  -- special forms that don't always eval all their args
  elseif symeq(x.car, 'if') then
    return eval_if(x, env)
  elseif symeq(x.car.car, 'fn') then
    return eval_fn(x, env)
  elseif symeq(x.car.car, 'label') then
    return eval_label(x, env)
  end
end

function eval_unary(x, env)
  return unary_functions[x.car.sym](eval(x.cdr.car, env))
end

function eval_binary(x, env)
  return binary_functions[x.car.sym](eval(x.cdr.car, env),
                                     eval(x.cdr.cdr.car, env))
end

function eval_if(x, env)
  -- syntax: (if check b1 b2)
  local check = x.cdr.car
  local b1    = x.cdr.cdr.car
  local b2    = x.cdr.cdr.cdr.car
  if eval(check, env) then
    return eval(b1, env)
  else
    return eval(b2, env)
  end
end

function eval_fn(x, env)
  -- syntax: ((fn params body*) args*)
  local callee = x.car
  local args = x.cdr
  local params = callee.cdr.car
  local body = callee.cdr.cdr
  return eval_exprs(body,
                    bind_env(params, args, env))
end

function bind_env(params, args, env)
  if params == nil then return env end
  local result = {next=env}
  while true do
    result[params.car.sym] = eval(args.car, env)
    params = params.cdr
    args = args.cdr
    if params == nil then break end
  end
  return result
end

function eval_exprs(xs, env)
  local result = nil
  while xs do
    result = eval(xs.car, env)
    xs = xs.cdr
  end
  return result
end

function eval_label(x, env)
  -- syntax: ((label f (fn params body*)) args*)
  local callee = x.car
  local args = x.cdr
  local f = callee.cdr.car
  local fn = callee.cdr.cdr.car
  return eval({car=fn, cdr=args},
              bind_env({f}, {callee}, env))
end

-- testing
function num(n) return {num=n} end
function char(c) return {char=c} end
function str(s) return {str=s} end
function sym(s) return {sym=s} end
function list(...)
  -- gotcha: no element in arg can be nil; that short-circuits the ipairs below
  local result = nil
  local curr = nil
  for _, x in ipairs({...}) do
    if curr == nil then
      result = {car=x}
      curr = result
    else
      curr.cdr = {car=x}
      curr = curr.cdr
    end
  end
  return result
end

function p(x)
  p2(x)
  print()
end

function p2(x)
  if x == nil then
    io.write('nil')
  elseif x == true then
    io.write('true')
  elseif x.num then
    io.write(x.num)
  elseif x.char then
    io.write("\\"..x.char)
  elseif x.str then
    io.write('"'..x.str..'"')
  elseif x.sym then
    io.write(x.sym)
  elseif x.cdr == nil then
    io.write('(')
    p2(x.car)
    io.write(')')
  elseif atom(x.cdr) then
    io.write('(')
    p2(x.car)
    io.write(' . ')
    p2(x.cdr)
    io.write(')')
  else
    io.write('(')
    while true do
      p2(x.car)
      x = x.cdr
      if x == nil then break end
      if atom(x) then
        io.write(' . ')
        p2(x)
        break
      end
      io.write(' ')
    end
    io.write(')')
  end
end

x = {num=3.4}
p(x)

p(cons(x, nil))
p(list(x))

p(iso(cons(x, nil), cons(x, nil)))
p(iso(list(x), list(x)))
p(iso(list(x, x), list(x)))
p(iso(list(x, x), list(x, x)))
p(iso(x, cons(x, nil)))

p     (list(sym("cons"), num(42), num(1)))
p(eval(list(sym("cons"), num(42), num(1)), {}))

-- ((fn () 42)) => 42
-- can't use list here because of the gotcha above
assert(iso(eval(cons(cons(sym('fn'), cons(nil, cons(num(42))))), {}), num(42)))
-- ((fn (a) (cons a 1)) 42) => '(42 . 1)
assert(iso(eval(cons(cons(sym('fn'), cons(cons(sym('a')), cons(cons(sym('cons'), cons(sym('a'), cons(num(1))))))), cons(num(42)))), cons(num(42), num(1))))
incomplete lisp interpreter app I'm not sure what I'm doing here just yet. This is just an experiment of the editing experience. The .tlv app doesn't actually do anything yet. 2022-01-27 16:30:50 +00:00			`-- atom types:`
			`-- nil`
			`-- true`
			`-- {num=3.4}`
			`-- {char='a'}`
			`-- {str='bc'}`
			`-- {sym='foo'}`
			`-- non-atom type:`
			`-- {car={num=3.4}, cdr=nil}`
			`--`
			`-- should {} mean anything special? currently just '(nil)`
			`function atom(x)`
			`return x == nil or x.num or x.char or x.str or x.sym`
			`end`

			`function car(x) return x.car end`
			`function cdr(x) return x.cdr end`
			`function cons(x, y) return {car=x, cdr=y} end`

			`function iso(x, y)`
			`if x == nil then return y == nil end`
			`local done={}`
			`if done[x] then return done[x] == y end`
			`done[x] = y`
			`if atom(x) then`
			`if not atom(y) then return nil end`
			`for k, v in pairs(x) do`
			`if y[k] ~= v then return nil end`
			`end`
			`return true`
			`end`
			`for k, v in pairs(x) do`
			`if not iso(y[k], v) then return nil end`
			`end`
			`for k, v in pairs(y) do`
			`if not iso(x[k], v) then return nil end`
			`end`
			`return true`
			`end`

			`-- primitives; feel free to add more`
			`-- format: lisp name = lua function that implements it`
			`unary_functions = {`
			`atom=atom,`
			`car=car,`
			`cdr=cdr,`
			`}`

			`binary_functions = {`
			`cons=cons,`
			`iso=iso,`
			`}`

			`function lookup(env, s)`
			`if env[s] then return env[s] end`
			`if env.next then return lookup(env.next, s) end`
			`end`

			`function eval(x, env)`
			`function symeq(x, s)`
			`return x and x.sym == s`
			`end`
			`if x.sym then`
			`return lookup(env, x.sym)`
			`elseif atom(x) then`
			`return x`
			`-- otherwise x is a pair`
			`elseif symeq(x.car, 'quote') then`
			`return x.cdr`
			`elseif unary_functions[x.car.sym] then`
			`return eval_unary(x, env)`
			`elseif binary_functions[x.car.sym] then`
			`return eval_binary(x, env)`
			`-- special forms that don't always eval all their args`
			`elseif symeq(x.car, 'if') then`
			`return eval_if(x, env)`
			`elseif symeq(x.car.car, 'fn') then`
			`return eval_fn(x, env)`
			`elseif symeq(x.car.car, 'label') then`
			`return eval_label(x, env)`
			`end`
			`end`

			`function eval_unary(x, env)`
			`return unary_functions[x.car.sym](eval(x.cdr.car, env))`
			`end`

			`function eval_binary(x, env)`
			`return binary_functions[x.car.sym](eval(x.cdr.car, env),`
			`eval(x.cdr.cdr.car, env))`
			`end`

			`function eval_if(x, env)`
			`-- syntax: (if check b1 b2)`
			`local check = x.cdr.car`
			`local b1 = x.cdr.cdr.car`
			`local b2 = x.cdr.cdr.cdr.car`
			`if eval(check, env) then`
			`return eval(b1, env)`
			`else`
			`return eval(b2, env)`
			`end`
			`end`

			`function eval_fn(x, env)`
			`-- syntax: ((fn params body) args)`
			`local callee = x.car`
			`local args = x.cdr`
			`local params = callee.cdr.car`
			`local body = callee.cdr.cdr`
			`return eval_exprs(body,`
			`bind_env(params, args, env))`
			`end`

			`function bind_env(params, args, env)`
			`if params == nil then return env end`
			`local result = {next=env}`
			`while true do`
			`result[params.car.sym] = eval(args.car, env)`
			`params = params.cdr`
			`args = args.cdr`
			`if params == nil then break end`
			`end`
			`return result`
			`end`

			`function eval_exprs(xs, env)`
			`local result = nil`
			`while xs do`
			`result = eval(xs.car, env)`
			`xs = xs.cdr`
			`end`
			`return result`
			`end`

			`function eval_label(x, env)`
			`-- syntax: ((label f (fn params body)) args)`
			`local callee = x.car`
			`local args = x.cdr`
			`local f = callee.cdr.car`
			`local fn = callee.cdr.cdr.car`
			`return eval({car=fn, cdr=args},`
			`bind_env({f}, {callee}, env))`
			`end`

			`-- testing`
			`function num(n) return {num=n} end`
			`function char(c) return {char=c} end`
			`function str(s) return {str=s} end`
			`function sym(s) return {sym=s} end`
			`function list(...)`
			`-- gotcha: no element in arg can be nil; that short-circuits the ipairs below`
			`local result = nil`
			`local curr = nil`
			`for _, x in ipairs({...}) do`
			`if curr == nil then`
			`result = {car=x}`
			`curr = result`
			`else`
			`curr.cdr = {car=x}`
			`curr = curr.cdr`
			`end`
			`end`
			`return result`
			`end`

			`function p(x)`
			`p2(x)`
			`print()`
			`end`

			`function p2(x)`
			`if x == nil then`
			`io.write('nil')`
			`elseif x == true then`
			`io.write('true')`
			`elseif x.num then`
			`io.write(x.num)`
			`elseif x.char then`
			`io.write("\\"..x.char)`
			`elseif x.str then`
			`io.write('"'..x.str..'"')`
			`elseif x.sym then`
			`io.write(x.sym)`
			`elseif x.cdr == nil then`
			`io.write('(')`
			`p2(x.car)`
			`io.write(')')`
			`elseif atom(x.cdr) then`
			`io.write('(')`
			`p2(x.car)`
			`io.write(' . ')`
			`p2(x.cdr)`
			`io.write(')')`
			`else`
			`io.write('(')`
			`while true do`
			`p2(x.car)`
			`x = x.cdr`
			`if x == nil then break end`
			`if atom(x) then`
			`io.write(' . ')`
			`p2(x)`
			`break`
			`end`
			`io.write(' ')`
			`end`
			`io.write(')')`
			`end`
			`end`

			`x = {num=3.4}`
			`p(x)`

			`p(cons(x, nil))`
			`p(list(x))`

			`p(iso(cons(x, nil), cons(x, nil)))`
			`p(iso(list(x), list(x)))`
			`p(iso(list(x, x), list(x)))`
			`p(iso(list(x, x), list(x, x)))`
			`p(iso(x, cons(x, nil)))`

			`p (list(sym("cons"), num(42), num(1)))`
			`p(eval(list(sym("cons"), num(42), num(1)), {}))`

			`-- ((fn () 42)) => 42`
			`-- can't use list here because of the gotcha above`
			`assert(iso(eval(cons(cons(sym('fn'), cons(nil, cons(num(42))))), {}), num(42)))`
			`-- ((fn (a) (cons a 1)) 42) => '(42 . 1)`
			`assert(iso(eval(cons(cons(sym('fn'), cons(cons(sym('a')), cons(cons(sym('cons'), cons(sym('a'), cons(num(1))))))), cons(num(42)))), cons(num(42), num(1))))`