File

util/array.lua @ 12480:7e9ebdc75ce4

net: isolate LuaSec-specifics For this, various accessor functions are now provided directly on the sockets, which reach down into the LuaSec implementation to obtain the information. While this may seem of little gain at first, it hides the implementation detail of the LuaSec+LuaSocket combination that the actual socket and the TLS layer are separate objects. The net gain here is that an alternative implementation does not have to emulate that specific implementation detail and "only" has to expose LuaSec-compatible data structures on the new functions.
author Jonas Schäfer <jonas@wielicki.name>
date Wed, 27 Apr 2022 17:44:14 +0200
parent 12403:42b2713ab818
child 12975:d10957394a3c
line wrap: on
line source

-- Prosody IM
-- Copyright (C) 2008-2010 Matthew Wild
-- Copyright (C) 2008-2010 Waqas Hussain
--
-- This project is MIT/X11 licensed. Please see the
-- COPYING file in the source package for more information.
--

local t_insert, t_sort, t_remove, t_concat
    = table.insert, table.sort, table.remove, table.concat;
local t_move = require "util.table".move;

local setmetatable = setmetatable;
local getmetatable = getmetatable;
local math_random = math.random;
local math_floor = math.floor;
local pairs, ipairs = pairs, ipairs;
local tostring = tostring;
local type = type;

local array = {};
local array_base = {};
local array_methods = {};
local array_mt = {
	__index = array_methods;
	__name = "array";
	__tostring = function (self) return "{"..self:concat(", ").."}"; end;
};

function array_mt:__freeze() return self; end

local function new_array(self, t, _s, _var)
	if type(t) == "function" then -- Assume iterator
		t = self.collect(t, _s, _var);
	end
	return setmetatable(t or {}, array_mt);
end

function array_mt.__add(a1, a2)
	local res = new_array();
	return res:append(a1):append(a2);
end

function array_mt.__eq(a, b)
	if getmetatable(a) ~= array_mt or getmetatable(b) ~= array_mt then
		-- Lua 5.3+ calls this if both operands are tables, even if metatables differ
		return false;
	end
	if #a == #b then
		for i = 1, #a do
			if a[i] ~= b[i] then
				return false;
			end
		end
	else
		return false;
	end
	return true;
end

function array_mt.__div(a1, func)
	local a2 = new_array();
	local o = 0;
	for i = 1, #a1 do
		local new_value = func(a1[i]);
		if new_value ~= nil then
			o = o + 1;
			a2[o] = new_value;
		end
	end
	return a2;
end

setmetatable(array, { __call = new_array });

-- Read-only methods
function array_methods:random()
	return self[math_random(1, #self)];
end

-- Return a random value excluding the one at idx
function array_methods:random_other(idx)
	local max = #self;
	return self[((math.random(1, max-1)+(idx-1))%max)+1];
end

-- These methods can be called two ways:
--   array.method(existing_array, [params [, ...]]) -- Create new array for result
--   existing_array:method([params, ...]) -- Transform existing array into result
--
function array_base.map(outa, ina, func)
	for k, v in ipairs(ina) do
		outa[k] = func(v);
	end
	return outa;
end

function array_base.filter(outa, ina, func)
	local inplace, start_length = ina == outa, #ina;
	local write = 1;
	for read = 1, start_length do
		local v = ina[read];
		if func(v) then
			outa[write] = v;
			write = write + 1;
		end
	end

	if inplace and write <= start_length then
		for i = write, start_length do
			outa[i] = nil;
		end
	end

	return outa;
end

function array_base.slice(outa, ina, i, j)
	if j == nil then
		j = -1;
	end
	if j < 0 then
		j = #ina + (j+1);
	end
	if i < 0 then
		i = #ina + (i+1);
	end
	if i < 1 then
		i = 1;
	end
	if j > #ina then
		j = #ina;
	end
	if i > j then
		for idx = 1, #outa do
			outa[idx] = nil;
		end
		return outa;
	end


	t_move(ina, i, j, 1, outa);
	if ina == outa then
		-- Clear (nil) remainder of range
		t_move(ina, #outa+1, #outa*2, 2+j-i, ina);
	end
	return outa;
end

function array_base.sort(outa, ina, ...)
	if ina ~= outa then
		outa:append(ina);
	end
	t_sort(outa, ...);
	return outa;
end

function array_base.unique(outa, ina)
	local seen = {};
	return array_base.filter(outa, ina, function (item)
		if seen[item] then
			return false;
		else
			seen[item] = true;
			return true;
		end
	end);
end

function array_base.pluck(outa, ina, key, default)
	for i = 1, #ina do
		local v = ina[i][key];
		if v == nil then
			v = default;
		end
		outa[i] = v;
	end
	return outa;
end

function array_base.reverse(outa, ina)
	local len = #ina;
	if ina == outa then
		local middle = math_floor(len/2);
		len = len + 1;
		local o; -- opposite
		for i = 1, middle do
			o = len - i;
			outa[i], outa[o] = outa[o], outa[i];
		end
	else
		local off = len + 1;
		for i = 1, len do
			outa[i] = ina[off - i];
		end
	end
	return outa;
end

--- These methods only mutate the array
function array_methods:shuffle()
	local len = #self;
	for i = 1, #self do
		local r = math_random(i, len);
		self[i], self[r] = self[r], self[i];
	end
	return self;
end

function array_methods:append(ina)
	t_move(ina, 1, #ina, #self+1, self);
	return self;
end

function array_methods:push(x)
	t_insert(self, x);
	return self;
end

array_methods.pop = t_remove;

function array_methods:concat(sep)
	return t_concat(array.map(self, tostring), sep);
end

function array_methods:length()
	return #self;
end

--- These methods always create a new array
function array.collect(f, s, var)
	local t = {};
	while true do
		var = f(s, var);
		if var == nil then break; end
		t_insert(t, var);
	end
	return setmetatable(t, array_mt);
end

---

-- Setup methods from array_base
for method, f in pairs(array_base) do
	local base_method = f;
	-- Setup global array method which makes new array
	array[method] = function (old_a, ...)
		local a = new_array();
		return base_method(a, old_a, ...);
	end
	-- Setup per-array (mutating) method
	array_methods[method] = function (self, ...)
		return base_method(self, self, ...);
	end
end

return array;