nel/parse.lua

require("helper")

-- CLASS DEFINITIONS
-- A stream of text (kind of)
-- with some helping methods
Reader = class("Reader")
-- Construct a reader from
function Reader:new(text)
  assert_type("string")(text,"Arg 'text' #1: %s")
  self.text = text
end
-- Get the substring of the readers text in a bounds
function Reader:get(first,final)
  assert_type("number")(first,"Arg 'first' #1: %s")
  assert_type("number","nil")(final,"Arg 'final' #2: %s")
  return self.text:sub(first,final)
end
-- Match on the reader's text from an index
function Reader:find(pattern,init)
  assert_type("string")(pattern,"Arg 'pattern' #1: %s")
  assert_type("number","nil")(init,"Arg 'init' #2: %s")
  return self.text:find(pattern,init)
end
function Reader:match(pattern,init)
  assert_type("string")(pattern,"Arg 'pattern' #1: %s")
  assert_type("number")(init,"Arg 'init' #2: %s")
  return self.text:match(pattern,init)
end

-- A range of text being considered
-- like a cursor
Range = class("Range")
-- Construct a range of text from a reader and bounds
function Range:new(reader,first,final)
  assert_meta(Reader)(reader)
  assert_type("number","nil")(first,"Arg 'first' #1: %s")
  assert_type("number","nil")(final,"Arg 'final' #2: %s")
  self.reader = reader
  self.first = first
  self.final = final
end
function Range:text()
  return self.reader:get(self.first or 1,self.final)
end
function Range:find(pattern)
  return self.reader:find(pattern,self.first)
end
function Range:move(first,final)
  assert_type("number","nil")(first,"Arg 'first' #1: %s")
  assert_type("number","nil")(final,"Arg 'final' #2: %s")
  self.first = first
  self.final = final
  -- note that this function returns itself
  return self
end

Expression = class("Expression")
-- Construct an expression from items (or not)
function Expression:new(items)
  items = items or {}
  assert_type("table")(items)
  self.items = {}
  for item in iterate(items) do
    self:insert(item)
  end
end
function Expression:empty()
  return #self.items == 0
end
-- insert a word or sub expression into this one
function Expression:insert(...)
  -- closures for nvim highlighting
  local function insert_word(word)
    -- Whitespace might confuse bindings, remove them
    local cleaned = word:match("^%s*(.-)%s*$")
    if cleaned ~= "" then
      table.insert(self.items,cleaned)
    end
  end
  local function insert_expression(expr)
    assert_meta(expr,Expression)
    table.insert(self.items,expr)
  end
  for item in iterate({...}) do
    case_of({
      table = function(expr)
        insert_expression(expr)
      end,
      string = function(word)
        insert_word(word)
      end
    })(type(item),item)
  end
end
function Expression:string()
  local parts = {}
  for index,item in pairs(self.items) do
    parts[index] = tostring(item)
  end
  return string.format("(%s)",table.concat(parts," "))
end
function Expression:abstract(infer)
  local parts = {}
  local count = 0
  for index,item in pairs(self.items) do
    parts[index] = case_of({
      [Expression] = function(item)
        local text
        if infer then
          text = item:text()
          if not text then
            count = count + 1
            text = tostring(count)
          end
        else
          text = "..."
        end
        return Expression({text})
      end,
      string = id
    })(type_of(item),item)
  end
  return Expression(parts)
end
function Expression:text()
  -- Get the text
  local text = self.items[#self.items]
  -- Ensure that the subexpression is valid abstract
  if type(text) ~= "string" then return end
  return text
end
function Expression:locate(str,uri)
  self.location = str
  self.source = uri
  return self
end
function Expression:link(msg)
  return string.format(
    "in '%s' @%s (%s)",
    msg,
    tostring(self),
    tostring(self.location or "?"),
    tostring(self.source or "?.nel")
  )
end

Consumer = class("Consumer")
function Consumer:new(content)
  self.range = Range(Reader(content))
  self.col = 1
  self.row = 1
end
function Consumer:remaining()
  return self.range:text()
end
function Consumer:mark()

end
-- From a table of actions of patterns,
-- consume the earliest pattern (index)
-- and call the value
function Consumer:consume(t)
  -- t: {string = function...}
  assert_type("table")(t,"Arg 't' #1: %s")
  if not next(t) then 
    error("The match table cannot be empty!",2)
  end
  for index,func in pairs(t) do
    assert_type("string")(index,"Bad 't' index: %s")
    assert_type("function")(func,"Bad 't' item: %s")
  end
  local origin = self.range.first or 1
  -- Get the next earliest match
  local findex,ffinal,fpattern,ffunc,fexcess
  for pattern,new_func in pairs(t) do
    local new_index,new_final = self.range:find(pattern)
    if new_index and 
      ((not findex) or (findex > new_index))
    then
      if not new_index then return end
      findex = new_index
      ffinal = new_final
      fpattern = pattern
      ffunc = new_func
      fexcess = self.range.reader:get(
        self.range.first or 1,
        new_final - 1
      )
    end
  end
  -- Pass into the func
  if not ffunc then 
    return nil
  end
  assert(findex) assert(ffinal)
  self.range:move(ffinal+1) -- Move range to after the match
  local fmatch = self.range.reader:match(fpattern,findex)
  -- Pass back consumed result to
  local sum = self.range.reader:get(origin+1,self.range.first)
    :gsub("\r\n","\n")
    :gsub("\r","\n")
  for char in sum:gmatch(".") do
    if char == "\n" then 
      self.row = self.row + 1
      self.col = 1
    else
      self.col = self.col + 1
    end
  end
  return ffunc(fexcess,fmatch)
end

Binding = class("Binding")
-- Construct from a neli string to infer a binding
-- note that you must wrap this definition in "(<def>)"!
function Binding:new(expression,callback)
  assert_meta(Expression)(expression,"Arg 'expression' #1: %s")
  if type_of(callback) == "function" then
    self.callback = callback
  else
    self.value = callback
  end
  self.template = expression:abstract(true)
end
function Binding:string()
  return string.format("Binding %s: %s",self.template,tostring(self.value or self.callback))
end
function Binding:call(s,e,c)
  assert_meta(Scope)(s)
  assert_meta(Chain)(c)
  return self.value or self.callback(s,e,c)
end
function Binding:check(expression)
  assert_meta(Expression)(expression,"Arg 'expression' #1: %s")
  local candid = expression:abstract()
  local data = {}
  local index
  local loop = true
  if #candid.items ~= #self.template.items then
    return false
  end
  while loop do
    local old = index
    index,template_item = next(self.template.items,old)
    index,candid_item = next(candid.items,old)
    local result = case_of({
      [Expression] = function()
        -- item is not an expression, cannot bind
        if type_of(candid_item) ~= Expression then 
          loop = false
        else 
          data[template_item:text()] = expression.items[index]
        end
      end,
      string = function()
        -- words don't match, cannot bind
        if candid_item ~= template_item then 
          loop = false 
        end
      end,
      ["nil"] = function()
        -- base case where both expressions terminate together
        if not candid_item then 
          return data
        end
      end
    })(type_of(template_item))
    if result then return result end
  end
end

Chain = class("Chain")
function Chain:new(data)
  assert_type("string")(data,"Arg 'data' #1: %s")
  self.data = data
end
function Chain:from(previous)
  assert_meta(Chain)(previous,"Arg 'previous' #1: %s")
  previous.next = self
  self.previous = previous 
  return self
end
function Chain:string()
  return string.format("Chain:%s",table.concat(self:flatten(),", "))
end
function Chain:flatten(tab)
  tab = tab or {}
  if self.next then
    self.next:flatten(tab)
  end
  table.insert(tab,self.data)
  return tab
end

-- The scope of a neli expression under evaluation
-- without exact faith to traditional language scopes
Scope = class("Scope")
function Scope:new(bindings)
  self.bindings = {}
  for binding in iterate(bindings or {}) do
    self:insert(binding)
  end
end
function Scope:string()
  return string.format("Scope: {\n\t%s\n}",table.concat(map(self.bindings,tostring),"\n\t"))
end
function Scope:insert(binding)
  assert_meta(Binding)(binding,"Arg 'binding' #1: %s")
  for competitor in iterate(self.bindings) do
    if competitor:check(binding.template) then
      nerror("Conflicting sibling bindings in scope.")
    end
  end
  table.insert(self.bindings,binding)
end
function Scope:run(expression,chain,original)
  original = original or self
  assert_meta(Expression)(expression,"Arg 'expression' #1: %s")
  assert_meta(Chain)(chain,"Arg 'chain' #2: %s")
    -- Could be multiple bindings so make a table
  local binds = {}
  for binding in iterate(self.bindings) do
    local bind = binding:check(expression)
    -- Insert into table
    if bind then binds[binding] = bind end
  end
  local binding,bind = next(binds)
  -- Check for multiple
  if not bind then
    if self.parent then
      return self.parent:run(expression,chain,self)
    else
      local extra = ""
      if #expression.items == 1 then
        local item = expression.items[1]
        if type_of(item) == Expression then
          extra = extra .. "\nNote: This expression is formed (just bracketed) of another single expression. Maybe too many brackets were used here?"
        else
          extra = extra .. "\n\tNote: This is a 'text' expression, it has no subexpressions. It is most likely that an expected object definition was not bound to the scope or there is a typo."
        end
      end
      error(
        string.format(
          "nel: No binding for '%s' in scope.",
          tostring(expression:abstract()),
          extra
        ),3
      )
    end
  -- Should never happen!
  elseif next(binds,binding) then
    local candidates = {}
    for binding,bind in pairs(binds) do
      table.insert(candidates,tostring(binding.template))
    end
    error(
      string.format(
        "nel: Ambiguous bindings in scope for '%s': %s",
        tostring(expression:abstract()),
        table.concat(candidates)
      )
    ,2)
  else
    return binding:call(
      original,
      bind,
      chain
    )
  end  
end
return _G