37

Which is the best efficient way to round up a number and then truncate it (remove decimal places after rounding up)?

for example if decimal is above 0.5 (that is, 0.6, 0.7, and so on), I want to round up and then truncate (case 1). Otherwise, I would like to truncate (case 2)

for example:
232.98266601563 => after rounding and truncate = 233 (case 1)
232.49445450000 => after rounding and truncate = 232 (case 2)
232.50000000000 => after rounding and truncate = 232 (case 2)
1
  • I know this is very late, but do you remember if you intended truncate also for negative numbers, IOW round halfway towards zero? My answer should do this after FPU rounding mode is adjusted accordingly.
    – Wolf
    Jun 14, 2021 at 19:43

13 Answers 13

47

There is no build-in math.round() function in Lua, but you can do the following: print(math.floor(a+0.5)).

5
  • What is a supposed to be?
    – averwhy
    Jan 31, 2020 at 18:22
  • @averwhy a is the value you want to round.
    – Nifim
    Jan 31, 2020 at 18:48
  • 5
    This returns 1 for a = 0.49999999999999994; it should return 0. Nov 7, 2020 at 12:25
  • @PedroGimeno Is that the only wrong case, or are there others? I tried 1.49999999999999988 + 0.5, which worked fine. Same for 2.49999999999999977 + 0.5. Feb 15, 2021 at 19:49
  • @RolandIllig It's the only case as far as I know. The addition of 0.49999999999999994 and 0.5 returns 1 due to rounding; for bigger numbers the rounding does not cause problems because they don't have enough significant digits as for them to affect the rounding. That number is special in that 0.5 is bigger than it. Feb 16, 2021 at 7:56
24

A trick that is useful for rounding at decimal digits other than whole integers is to pass the value through formatted ASCII text, and use the %f format string to specify the rounding desired. For example

mils = tonumber(string.format("%.3f", exact))

will round the arbitrary value in exact to a multiple of 0.001.

A similar result can be had with scaling before and after using one of math.floor() or math.ceil(), but getting the details right according to your expectations surrounding the treatment of edge cases can be tricky. Not that this isn't an issue with string.format(), but a lot of work has gone into making it produce "expected" results.

Rounding to a multiple of something other than a power of ten will still require scaling, and still has all the tricky edge cases. One approach that is simple to express and has stable behavior is to write

function round(exact, quantum)
    local quant,frac = math.modf(exact/quantum)
    return quantum * (quant + (frac > 0.5 and 1 or 0))
end

and tweak the exact condition on frac (and possibly the sign of exact) to get the edge cases you wanted.

2
  • 2
    Unfortunately string.format() rounds differently depending on the Lua version used. See my question about LuaJIT which prefers to round up while most others round down when faced with an "exact" half.
    – Caleb
    Oct 27, 2020 at 20:16
  • As for the second part, why not simply (exact + quantum*0.5) // quantum * quantum?
    – AF7
    Sep 24, 2021 at 12:43
19

To also support negative numbers, use this:

function round(x)
  return x>=0 and math.floor(x+0.5) or math.ceil(x-0.5)
end
1
  • 4
    This returns 1 for x = 0.49999999999999994 and -1 for -0.49999999999999994; it should return 0. See my answer for a version that properly rounds to nearest or even. Nov 7, 2020 at 12:21
9

If your Lua uses double precision IEC-559 (aka IEEE-754) floats, as most do, and your numbers are relatively small (the method is guaranteed to work for inputs between -251 and 251), the following efficient code will perform rounding using your FPU's current rounding mode, which is usually round to nearest, ties to even:

local function round(num)
  return num + (2^52 + 2^51) - (2^52 + 2^51)
end

(Note that the numbers in parentheses are calculated at compilation time; they don't affect runtime).

For example, when the FPU is set to round to nearest or even, this unit test prints "All tests passed":

local function testnum(num, expected)
  if round(num) ~= expected then
    error(("Failure rounding %.17g, expected %.17g, actual %.17g")
          :format(num+0, expected+0, round(num)+0))
  end
end

local function test(num, expected)
  testnum(num, expected)
  testnum(-num, -expected)
end

test(0, 0)
test(0.2, 0)
test(0.4, 0)
-- Most rounding algorithms you find on the net, including Ola M's answer,
-- fail this one:
test(0.49999999999999994, 0)
-- Ties are rounded to the nearest even number, rather than always up:
test(0.5, 0)
test(0.5000000000000001, 1)
test(1.4999999999999998, 1)
test(1.5, 2)
test(2.5, 2)
test(3.5, 4)
test(2^51-0.5, 2^51)
test(2^51-0.75, 2^51-1)
test(2^51-1.25, 2^51-1)
test(2^51-1.5, 2^51-2)
print("All tests passed")

Here's another (less efficient, of course) algorithm that performs the same FPU rounding but works for all numbers:

local function round(num)
  local ofs = 2^52
  if math.abs(num) > ofs then
    return num
  end
  return num < 0 and num - ofs + ofs or num + ofs - ofs
end
3
  • Could you explain why the correction needs to be 2^52 + 2^51? I tried 2^53 - 2, and it worked equally well for your test cases. Of course I could do the math myself, and it would certainly be worth it, but maybe you can share the tricky details and edge cases with a larger audience here. Feb 17, 2021 at 11:51
  • 3
    @RolandIllig My test suite is not very exhaustive; it doesn't check all corner cases. Your number fails for e.g. 2.75, which gets rounded to 2.0. Adding and subtracting 2^52 to any number between 0 and 2^52-1 rounds it by pushing it to the range 2^52..2^53, where the double precision floats lose all their decimals, before adjusting back. To cover negatives, I added 2^51 in order to ensure the intermediate result is still in the range 2^52..2^53. If you push it beyond 2^53 as your number does often, you lose even numbers too; e.g. 2^53+1 can't be exactly represented in double precision. Feb 17, 2021 at 19:58
  • 2
    "you lose even numbers too" - I meant you lose odd numbers. Feb 18, 2021 at 15:47
6

Here's one to round to an arbitrary number of digits (0 if not defined):

function round(x, n)
    n = math.pow(10, n or 0)
    x = x * n
    if x >= 0 then x = math.floor(x + 0.5) else x = math.ceil(x - 0.5) end
    return x / n
end
2
  • 1
    This works for Lua, but not LuaJIT. If you let x=32.90625 and n=4 then most Luas will give you 32.9062 but LuaJIT will give you 23.0963. See my question about how to avoid this.
    – Caleb
    Oct 27, 2020 at 20:32
  • Good answer, but you should have been more careful when posting the code here. The n or 0 doesn't cover the digit number not being defined (using ... as the 2nd argument in the function and referencing it via arg[2] would have achieved that), not to mention there's a possible division by 0 situation by not proper handling the returned x / n. I could mention rare -0 occurences as well, but you get the idea: the method is good, as long as the exception cases are handled correctly. Mar 3 at 13:14
5

For bad rounding (cutting the end off):

function round(number)
  return number - (number % 1)
end

Well, if you want, you can expand this for good rounding.

function round(number)
  if (number - (number % 0.1)) - (number - (number % 1)) < 0.5 then
    number = number - (number % 1)
  else
    number = (number - (number % 1)) + 1
  end
 return number
end

print(round(3.1))
print(round(math.pi))
print(round(42))
print(round(4.5))
print(round(4.6))

Expected results:

3, 3, 42, 5, 5

3

I like the response above by RBerteig: mils = tonumber(string.format("%.3f", exact)). Expanded it to a function call and added a precision value.

function round(number, precision)
   local fmtStr = string.format('%%0.%sf',precision)
   number = string.format(fmtStr,number)
   return number
end
1
  • 1
    Unfortunately string.format() rounds differently depending on the Lua version used. See my question about LuaJIT which prefers to round up while most others round down when faced with an "exact" half.
    – Caleb
    Oct 27, 2020 at 20:26
1

Should be math.ceil(a-0.5) to correctly handle half-integer numbers

1
  • 5
    Depends on what "correctly" means. One has to carefully decide what to do about half steps, and what to do with negative values. Both add a half and floor and your subtract a half and ceil introduce a consistent bias to the case of the exact half. And both are different from add half and truncate assuming that truncation usually rounds towards zero. Implementing round to even value is more "fair" in some sense. Rounding is fraught with subtlety.
    – RBerteig
    Aug 19, 2013 at 20:35
1

Here is a flexible function to round to different number of places. I tested it with negative numbers, big numbers, small numbers, and all manner of edge cases, and it is useful and reliable:

function Round(num, dp)
    --[[
    round a number to so-many decimal of places, which can be negative, 
    e.g. -1 places rounds to 10's,  
    
    examples
        173.2562 rounded to 0 dps is 173.0
        173.2562 rounded to 2 dps is 173.26
        173.2562 rounded to -1 dps is 170.0
    ]]--
    local mult = 10^(dp or 0)
    return math.floor(num * mult + 0.5)/mult
end
1
  • API docs: (1) the divergence between dpand dps can be confusing and (2) halfway rounding is done away from zero for positive inputs and towards zero for negative ones (I think that this should be included... (or reimplemented?))
    – Wolf
    Jun 14, 2021 at 9:51
0

For rounding to a given amount of decimals (which can also be negative), I'd suggest the following solution that is combined from the findings already presented as answers, especially the inspiring one given by Pedro Gimeno. I tested a few corner cases I'm interested in but cannot claim that this makes this function 100% reliable:

function round(number, decimals)
  local scale = 10^decimals
  local c = 2^52 + 2^51
  return ((number * scale + c ) - c) / scale
end

These cases illustrate the round-halfway-to-even property (which should be the default on most machines):

assert(round(0.5, 0) == 0)
assert(round(-0.5, 0) == 0)
assert(round(1.5, 0) == 2)
assert(round(-1.5, 0) == -2)
assert(round(0.05, 1) == 0)
assert(round(-0.05, 1) == 0)
assert(round(0.15, 1) == 0.2)
assert(round(-0.15, 1) == -0.2)

I'm aware that my answer doesn't handle the third case of the actual question, but in favor of being IEEE-754 compliant, my approach makes sense. So I'd expect that the results depend on the current rounding mode set in the FPU with FE_TONEAREST being the default. And that's why it seems high likely that after setting FE_TOWARDZERO (however you can do that in Lua) this solution would return exactly the results that were asked for in the question.

0

Try using math.ceil(number + 0.5) This is according to this Wikipedia page. If I'm correct, this is only rounding positive integers. you need to do math.floor(number - 0.5) for negatives.

1
  • This is basically another version of @toma91 's answer. I did not see it before I posted.
    – Alvin-He
    Aug 27, 2021 at 5:25
0

If it's useful to anyone, i've hash-ed out a generic version of LUA's logic, but this time for truncate() :

**emphasized text pre-apologize for not knowing lua-syntax, so this is in AWK/lua mixture, but hopefully it should be intuitive enough

-- due to lua-magic alrdy in 2^(52-to-53) zone,
-- has to use a more coarse-grained delta than
-- true IEEE754 double machineepsilon of 2^-52
function trunc_lua(x,s) {
    return \
      ((x*(s=(-1)^(x<-x)) \
           - 2^-1 + 2^-50 \  -- can also be written as
                          \  --    2^-50-5^0/2
           -  _LUAMAGIC  \   -- if u like symmetric 
                         \   --    code for fun
           +  _LUAMAGIC \
      )  *(s) };

It's essentially the same concept as rounding, but force-processing all inputs in positive-value zone, with a -1*(0.5-delta) offset. The smallest delta i could attain is 2^-52 ~ 2.222e-16.

The lua-magic values must come after all those pre-processing steps, else precision-loss may occur. And finally, restore original sign of input.

The 2 "multiplies" are simply low-overhead sign-flipping. sign-flips 4 times for originally negative values (2 manual flips and round-trip to end of mantissa), while any x >= 0, including that of -0.0, only flips twice. All tertiary function calling, float division, and integer modulus is avoided, with only 1 conditional check for x<0.

usage notes :

  • (1) doesn't perform checks on input for invalid or malicious payload,
  • (2) doesn't use quickly check for zero,
  • (3) doesn't check for extreme inputs that may render this logic moot, and
  • (4) doesn't attempt to pretty format the value
0

if not exist math.round

function math.round(x, n)
    return tonumber(string.format("%." .. n .. "f", x))
end

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