luajson-1.2.1/tests/lunit-numbers.lua - nest-learning-thermostat/5.0/luajson - Git at Google

 local json = require("json")
 local lunit = require("lunit")
 local math = require("math")
 local testutil = require("testutil")
 local string = require("string")

 local encode = json.encode
 -- DECODE NOT 'local' due to requirement for testutil to access it
 decode = json.decode.getDecoder(false)

 module("lunit-numbers", lunit.testcase, package.seeall)

 function setup()
 	-- Ensure that the decoder is reset
 	_G["decode"] = json.decode.getDecoder(false)
 end

 local function assert_near(expect, received)
 	local pctDiff
 	if expect == received then
 		pctDiff = 0
 	else
 		pctDiff = math.abs(1 - expect / received)
 	end
 	local msg = ("expected '%s' but was '%s' .. '%s'%% apart"):format(expect, received, pctDiff * 100)
 	assert(pctDiff < 0.000001, msg)
 end
 local function test_simple(num)
 	assert_near(num, decode(tostring(num)))
 end
 local function test_simple_w_encode(num)
 	assert_near(num, decode(encode(num)))
 end
 local function test_scientific(num)
 	assert_near(num, decode(string.format('%e', num)))
 	assert_near(num, decode(string.format('%E', num)))
 end
 local numbers = {
 	0, 1, -1, math.pi, -math.pi
 }
 math.randomseed(0xDEADBEEF)
 -- Add sequence of numbers at low/high end of value-set
 for i = -300,300,60 do
 	numbers[#numbers + 1] = math.random() * math.pow(10, i)
 	numbers[#numbers + 1] = -math.random() * math.pow(10, i)
 end

 local function get_number_tester(f)
 	return function ()
 		for _, v in ipairs(numbers) do
 			f(v)
 		end
 	end
 end

 test_simple_numbers = get_number_tester(test_simple)
 test_simple_numbers_w_encode = get_number_tester(test_simple_w_encode)
 test_simple_numbers_scientific = get_number_tester(test_scientific)

 function test_infinite_nostrict()
 	assert_equal(math.huge, decode("Infinity"))
 	assert_equal(math.huge, decode("infinity"))
 	assert_equal(-math.huge, decode("-Infinity"))
 	assert_equal(-math.huge, decode("-infinity"))
 end

 function test_nan_nostrict()
 	local value = decode("nan")
 	assert_true(value ~= value)
 	local value = decode("NaN")
 	assert_true(value ~= value)
 end

 function test_expression()
 	assert_error(function()
 		decode("1 + 2")
 	end)
 end

 -- For strict tests, small concession must be made to allow non-array/objects as root
 local strict = json.util.merge({}, json.decode.strict, {initialObject = false})
 local strictDecoder = json.decode.getDecoder(strict)

 local numberValue = {hex = true}

 local hex = {number = numberValue}
 local hexDecoder = json.decode.getDecoder(hex)

 function test_hex()
 	if decode == hexDecoder then -- MUST SKIP FAIL UNTIL BETTER METHOD SETUP
 		return
 	end
 	assert_error(function()
 		decode("0x20")
 	end)
 end

 local hexNumbers = {
 	0xDEADBEEF,
 	0xCAFEBABE,
 	0x00000000,
 	0xFFFFFFFF,
 	0xCE,
 	0x01
 }

 function test_hex_only()
 	_G["decode"] = hexDecoder
 	for _, v in ipairs(hexNumbers) do
 		assert_equal(v, decode(("0x%x"):format(v)))
 		assert_equal(v, decode(("0X%X"):format(v)))
 		assert_equal(v, decode(("0x%X"):format(v)))
 		assert_equal(v, decode(("0X%x"):format(v)))
 	end
 end

 local decimal_hexes = {
 	"0x0.1",
 	"0x.1",
 	"0x0e+1",
 	"0x0E-1"
 }
 function test_no_decimal_hex_only()
 	for _, str in ipairs(decimal_hexes) do
 		assert_error(function()
 			hexDecoder(str)
 		end)
 	end
 end

 function test_nearly_scientific_hex_only()
 	assert_equal(0x00E1, hexDecoder("0x00e1"))
 end

 local function buildStrictDecoder(f)
 	return testutil.buildPatchedDecoder(f, strictDecoder)
 end
 local function buildFailedStrictDecoder(f)
 	return testutil.buildFailedPatchedDecoder(f, strictDecoder)
 end
 -- SETUP CHECKS FOR SEQUENCE OF DECODERS
 for k, v in pairs(_M) do
 	if k:match("^test_") and not k:match("_gen$") and not k:match("_only$") then
 		if k:match("_nostrict") then
 			_M[k .. "_strict_gen"] = buildFailedStrictDecoder(v)
 		else
 			_M[k .. "_strict_gen"] = buildStrictDecoder(v)
 		end
 		_M[k .. "_hex_gen"] = testutil.buildPatchedDecoder(v, hexDecoder)
 	end
 end
	local json = require("json")
	local lunit = require("lunit")
	local math = require("math")
	local testutil = require("testutil")
	local string = require("string")

	local encode = json.encode
	-- DECODE NOT 'local' due to requirement for testutil to access it
	decode = json.decode.getDecoder(false)

	module("lunit-numbers", lunit.testcase, package.seeall)

	function setup()
	-- Ensure that the decoder is reset
	_G["decode"] = json.decode.getDecoder(false)
	end

	local function assert_near(expect, received)
	local pctDiff
	if expect == received then
	pctDiff = 0
	else
	pctDiff = math.abs(1 - expect / received)
	end
	local msg = ("expected '%s' but was '%s' .. '%s'%% apart"):format(expect, received, pctDiff * 100)
	assert(pctDiff < 0.000001, msg)
	end
	local function test_simple(num)
	assert_near(num, decode(tostring(num)))
	end
	local function test_simple_w_encode(num)
	assert_near(num, decode(encode(num)))
	end
	local function test_scientific(num)
	assert_near(num, decode(string.format('%e', num)))
	assert_near(num, decode(string.format('%E', num)))
	end
	local numbers = {
	0, 1, -1, math.pi, -math.pi
	}
	math.randomseed(0xDEADBEEF)
	-- Add sequence of numbers at low/high end of value-set
	for i = -300,300,60 do
	numbers[#numbers + 1] = math.random() * math.pow(10, i)
	numbers[#numbers + 1] = -math.random() * math.pow(10, i)
	end

	local function get_number_tester(f)
	return function ()
	for _, v in ipairs(numbers) do
	f(v)
	end
	end
	end

	test_simple_numbers = get_number_tester(test_simple)
	test_simple_numbers_w_encode = get_number_tester(test_simple_w_encode)
	test_simple_numbers_scientific = get_number_tester(test_scientific)

	function test_infinite_nostrict()
	assert_equal(math.huge, decode("Infinity"))
	assert_equal(math.huge, decode("infinity"))
	assert_equal(-math.huge, decode("-Infinity"))
	assert_equal(-math.huge, decode("-infinity"))
	end

	function test_nan_nostrict()
	local value = decode("nan")
	assert_true(value ~= value)
	local value = decode("NaN")
	assert_true(value ~= value)
	end

	function test_expression()
	assert_error(function()
	decode("1 + 2")
	end)
	end

	-- For strict tests, small concession must be made to allow non-array/objects as root
	local strict = json.util.merge({}, json.decode.strict, {initialObject = false})
	local strictDecoder = json.decode.getDecoder(strict)

	local numberValue = {hex = true}

	local hex = {number = numberValue}
	local hexDecoder = json.decode.getDecoder(hex)

	function test_hex()
	if decode == hexDecoder then -- MUST SKIP FAIL UNTIL BETTER METHOD SETUP
	return
	end
	assert_error(function()
	decode("0x20")
	end)
	end

	local hexNumbers = {
	0xDEADBEEF,
	0xCAFEBABE,
	0x00000000,
	0xFFFFFFFF,
	0xCE,
	0x01
	}

	function test_hex_only()
	_G["decode"] = hexDecoder
	for _, v in ipairs(hexNumbers) do
	assert_equal(v, decode(("0x%x"):format(v)))
	assert_equal(v, decode(("0X%X"):format(v)))
	assert_equal(v, decode(("0x%X"):format(v)))
	assert_equal(v, decode(("0X%x"):format(v)))
	end
	end

	local decimal_hexes = {
	"0x0.1",
	"0x.1",
	"0x0e+1",
	"0x0E-1"
	}
	function test_no_decimal_hex_only()
	for _, str in ipairs(decimal_hexes) do
	assert_error(function()
	hexDecoder(str)
	end)
	end
	end

	function test_nearly_scientific_hex_only()
	assert_equal(0x00E1, hexDecoder("0x00e1"))
	end

	local function buildStrictDecoder(f)
	return testutil.buildPatchedDecoder(f, strictDecoder)
	end
	local function buildFailedStrictDecoder(f)
	return testutil.buildFailedPatchedDecoder(f, strictDecoder)
	end
	-- SETUP CHECKS FOR SEQUENCE OF DECODERS
	for k, v in pairs(_M) do
	if k:match("^test_") and not k:match("_gen$") and not k:match("_only$") then
	if k:match("_nostrict") then
	_M[k .. "_strict_gen"] = buildFailedStrictDecoder(v)
	else
	_M[k .. "_strict_gen"] = buildStrictDecoder(v)
	end
	_M[k .. "_hex_gen"] = testutil.buildPatchedDecoder(v, hexDecoder)
	end
	end