What is the equivalent of Math.Round() with MidpointRounding.AwayFromZero in Delphi?

How do I use c# similar `Math.Round` with `MidpointRounding.AwayFromZero` in Delphi?

What will be the equivalent of:

``````double d = 2.125;
Console.WriteLine(Math.Round(d, 2, MidpointRounding.AwayFromZero));
``````

Output: `2.13`

In Delphi?

• I don't think there is an out-of-the-box function that does that. There is up, down, to-wards zero and banker's rounding, but no AwayFromZero, I'm afraid. Jun 24, 2019 at 8:43

I believe the Delphi RTL's SimpleRoundTo function does essentially this, at least if the FPU rounding mode is "correct". Please read its documentation and implementation carefully, and then decide if it is good enough for your purposes.

But beware that setting the rounding mode for a single rounding operation like this is using a global change to solve a local problem. This might cause problems (multi-threading, libraries, etc.).

Bonus chatter: Had the question been about "regular" rounding (to an integer), I think I'd tried an approach like

``````function RoundMidpAway(const X: Real): Integer;
begin
Result := Trunc(X);
if Abs(Frac(X)) >= 0.5 then
Inc(Result, Sign(X));
end;
``````

Of course, it is possible to write a similar function even for the general case of n fractional digits. (But be careful to handle edge cases, overflows, floating-point issues, etc., correctly.)

Update: I believe the following does the trick (and is fast):

``````function RoundMidpAway(const X: Real): Integer; overload;
begin
Result := Trunc(X);
if Abs(Frac(X)) >= 0.5 then
Inc(Result, Sign(X));
end;

const
PowersOfTen: array[-10..10] of Real =
(
0.0000000001,
0.000000001,
0.00000001,
0.0000001,
0.000001,
0.00001,
0.0001,
0.001,
0.01,
0.1,
1,
10,
100,
1000,
10000,
100000,
1000000,
10000000,
100000000,
1000000000,
10000000000
);
var
MagnifiedValue: Real;
begin
if not InRange(ADigit, Low(PowersOfTen), High(PowersOfTen)) then
raise EInvalidArgument.Create('Invalid digit index.');
end;
``````

Of course, if you'd use this function in production code, you'd also add at least 50 unit test cases that test its correctness (to be run daily).

Update: I believe the following version is more stable:

``````function RoundMidpAway(const X: Real; ADigit: integer): Real; overload;
const
FuzzFactor = 1000;
DoubleResolution = 1E-15 * FuzzFactor;
PowersOfTen: array[-10..10] of Real =
(
0.0000000001,
0.000000001,
0.00000001,
0.0000001,
0.000001,
0.00001,
0.0001,
0.001,
0.01,
0.1,
1,
10,
100,
1000,
10000,
100000,
1000000,
10000000,
100000000,
1000000000,
10000000000
);
var
MagnifiedValue: Real;
TruncatedValue: Real;
begin

if not InRange(ADigit, Low(PowersOfTen), High(PowersOfTen)) then
raise EInvalidArgument.Create('Invalid digit index.');

TruncatedValue := Int(MagnifiedValue);
if CompareValue(Abs(Frac(MagnifiedValue)), 0.5, DoubleResolution * PowersOfTen[-ADigit]) >= EqualsValue  then
TruncatedValue := TruncatedValue + Sign(MagnifiedValue);

end;
``````

but I haven't fully tested it. (Currently it passes 900+ unit test cases, but I don't consider the test suite quite sufficient yet.)

• Might be a good idea to inline `RoundMidpAway(const X: Real): Integer;`. Jun 24, 2019 at 9:55
• `RoundMidpAway(2.135, -2)` results `2.13`. should be `2.14`
– zig
Jun 24, 2019 at 13:01
• @zig: Yeah, floating-point numbers are indeed difficult to work with, as hinted. In my defence, I suspected such issues could be present, thus my comment about extensive testing (which I intended to perform tonight). In this case, `RoundMidpAway(2.135, -2)`, yields `MagnifiedValue = 213.5` and `Abs(Frac(X)) = 0.499999999999972`, instead of the exact value `0.5`. That's the reason. I'll try to fix this. Jun 24, 2019 at 13:18
• That's how floating-point numbers work. If you store a value in a `double`, which cannot be represented exactly, you lose information that can never be recovered. It won't help to upgrade it to an `extended` later. Try `d := 2.135; e := 2.135; Writeln(extended(d) = e);`. Jun 25, 2019 at 9:04
• My later version treats floating-points the way floating-points should be treated: by assuming some epsilon uncertainties. Thus, if the fractional part is a tiny bit below 0.5, I assume that's because of numerical issues, and still regard it as >= 0.5. The `1E-15` constant is especially suitable for `double`. Jun 25, 2019 at 9:11

What you're looking for is SimpleRoundTo function in combination with SetRoundMode. As the documentations says:

SimpleRoundTo returns the nearest value that has the specified power of ten. In case `AValue` is exactly in the middle of the two nearest values that have the specified power of ten (above and below), this function returns:

• The value toward plus infinity if `AValue` is positive.

• The value toward minus infinity if `AValue` is negative and the FPU rounding mode is not set to rmUp

Note that the second parameter to the function is `TRoundToRange` which refers to exponent (power of 10) rather than number of fractional digis in .NET's Math.Round method. Therefore to round to 2 decimal places you use -2 as round-to range.

``````uses Math, RTTI;

var
LRoundingMode: TRoundingMode;
begin
for LRoundingMode := Low(TRoundingMode) to High(TRoundingMode) do
begin
SetRoundMode(LRoundingMode);
Writeln(TRttiEnumerationType.GetName(LRoundingMode));
Writeln(SimpleRoundTo(2.125, -2).ToString);
Writeln(SimpleRoundTo(-2.125, -2).ToString);
end;
end;
``````

rmNearest

2,13

-2,13

rmDown

2,13

-2,13

rmUp

2,13

-2,12

rmTruncate

2,13

-2,13

• But beware that setting the rounding mode for this is using a global change to solve a local problem. This might cause problems (multi-threading, libraries, etc.). Jun 24, 2019 at 8:52
• @AndreasRejbrand That's correct. Delphi 7 (and even newer versions) is plagued with these global state dependent routines and as pointed out in the comment and other answer, it should be used with care. Jun 24, 2019 at 9:32