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Within JavaScript, numbers are defined as 64bit double-precision. I have a specific use in mind for a distributed web application, which would only work if I can rely on consistent results across all browsers.

Despite the spec using the IEEE standard, I naturally have a suspicion that there may be tiny differences in implementations of the maths library or even the underlying hardware, which could cause compound errors.

Is there any source of compatibility data, or a reliable test suite to verify double precision calculations in the browser? In particular, I also need to consider mobile browsers (usually ARM based).

Clarification -

This is a question about browser compatibility. I'm trying to understand whether all browsers can be relied upon to treat numbers in a reliable, consistent and repeatable way as defined for IEEE floating point. In most languages this is a safe assumption, but it's interesting that there's a little uncertainty about this in the browser.

There's been some great advice on how to avoid floating point problems due to lack of precision and rounding errors. In most cases, if you require accuracy you should follow this advice!

For this question, I'm not trying to avoid the problem but understand it. Floating point numbers are inherently inaccurate by design, but as long as some care is taken with how builds are made that inaccuracy can be completely predictable and consistent. IEEE-754 describes this to a level of detail that only a standards body could.

I've decided to offer a small bounty if anyone can cite,

  • Genuine compatibility data relating to the implementation of IEEE numbers in mainstream browsers.
  • A test suite intended to verify the implementation within the browsers, including verifying the correct internal use of a 64 bit floating point number (53 bit mantissa).

In this question I'm not looking for alternative options, workarounds or ways to avoid the problem. Thank you for the suggestions.

share|improve this question
    
I cannot answer your question, but have you considered using Strings instead? Math may be little more difficult, but then you'll never have to worry about precision. –  Danny Kirchmeier Feb 22 '12 at 5:02
7  
@DannyKirchmeier - Math may be a little more difficult? –  nnnnnn Feb 22 '12 at 5:07
    
@DannyKirchmeier: Using strings (I assume you mean things akin to Java's BigDecimal, or C#'s decimal type) can be useful for financial calculations, but that doesn't mean you don't have to worry about precision, just that you have different worries about precision. They can't (for instance) represent one-third precisely. –  T.J. Crowder Feb 22 '12 at 5:07
1  
@nnnnnn: Yes. See the assumption at the beginning of the comment. –  T.J. Crowder Feb 22 '12 at 5:08
1  
Not an answer, so I'll just comment: A) One element in a test suite that's handy is 0.1 + 0.2, which on a conforming implementation should yield 0.30000000000000004. B) I wouldn't be surprised if there were a couple of implementations in the wild with the odd bug around an edge case. –  T.J. Crowder Feb 22 '12 at 5:11
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7 Answers

up vote 1 down vote accepted

Unfortunately the answer is no. There is at least one outstanding bug in v8 that, due to double-rounding, means it might not match IEEE 754 double precision on 32-bit Linux.

This can be tested with:

9007199254740994 + 0.99999 === 9007199254740994

I can verify that this fails (the left-hand side is 9007199254740996) on Chrome 26.0.1410.63 running on 32-bit Ubuntu. It passes on Firefox 20.0 on the same system. At the very least, this test should be added to your test suite, and maybe test262.

share|improve this answer
    
After some delay I thought it fair to finally award this answer, as the v8 bug you referenced was the key problem I found in my own research. –  leebriggs Aug 2 '13 at 18:26
add comment

This is just for fun, as you already stated and I created a new answer because this one is in a different vein. But I still feel like there are a few random passerby's who are ignoring the futility of the problem. So let's start by addressing your points:

Firstly:

Genuine compatibility data relating to the implementation of IEEE numbers in mainstream browsers.

doesn't exist, and for that matter doesn't even make any sense, IEEE is just a standards body...? I am not sure if this vague on purpose or on accident, I will assume you were trying to say IEEE 754, but there in lies the rub... there are technically 2 versions of this standard IEEE 754-2008 AND IEEE 754-1985. Basically the former is newer and addresses the latter's oversights. Any sane person would assume that any maintained JavaScript implementation would update to the latest and greatest standard, but any sane person should know JavaScript better than that, and even if JavaScript wasn't crazy, there is no specification saying that the implementation has to be/stay up to date (check the ECMA spec yourself if you don't believe me, they don't even talk "versions"). To compound the matters further the IEEE Standard 754-2008 for Floating-Point Arithmetic supports two encoding formats: the decimal encoding format, and the binary encoding format. Which as would be expected are compatible with each other in the sense that you can go back and forth without loss of data, but that's assuming we have access to the binary representation of the number, which we don't (without attaching a debugger and looking at the store the old school way)

However, from what I can tell it seems it is general practice to "back" a JavaScript Number with an old fashioned double which of course means that we are at the mercy of the compiler used to actually build the browser. But even in that realm, we can't and shouldn't be assuming equality even if all the compilers were on the same version of the standard (they aren't) and even if all the compilers implemented the standard in its entirety (they don't). Here's an excerpt from this paper, which I have deemed an interesting, worthwhile and relevant-to-this-dialog read...

Many programmers like to believe that they can understand the behavior of a program and prove that it will work correctly without reference to the compiler that compiles it or the computer that runs it. In many ways, supporting this belief is a worthwhile goal for the designers of computer systems and programming languages. Unfortunately, when it comes to floating-point arithmetic, the goal is virtually impossible to achieve. The authors of the IEEE standards knew that, and they didn't attempt to achieve it. As a result, despite nearly universal conformance to (most of) the IEEE 754 standard throughout the computer industry, programmers of portable software must continue to cope with unpredictable floating-point arithmetic.

While finding that I also found this reference implementation done completely in JavaScript (note: I haven't actually verified the validity of the implementation).

All that said, let's move on to your second request:

A test suite intended to verify the implementation within the browsers, including verifying the correct internal use of a 64 bit floating point number (53 bit mantissa).

Since JavaScript is an interpreted platform you should see now that there is no way to test the set of script + compiler (VM/engine) + compiler that compiled the compiler + machine in an absolute and reliable way from the point of JavaScript. So unless you want to build a test suite that acts as a browser host and actually "peeks" into the private memory of the process to ensure a valid representation, which would be fruitless most likely anyway since the number are most likely "backed" by a double and that is going to conform as it does in the C or C++ that browser was built in. There is no absolute way to do this from JavaScript since all we have access to is the "object" and even when we view the Number in a console we are looking at a .toString version. For that matter I would posit that this is the only form that matters since it will be determined from the binary and would only become a point of failure if for the statement: n1 === n2 && n1.toString() !== n2.toString() you could find an n1, n2 that is relevant...

That said, we can test the string version and in reality it is just as good as testing the binary as long as we keep a few oddities in mind. Especially since nothing outside the JavaScript engine/VM ever touches the binary version. However this puts you at the mercy of an oddly specific, possibly very finicky and poised to be changed point of failure. Just for reference, here is an excerpt from webkit's JavaScriptCore's Number Prototype (NumberPrototype.cpp) displaying the complexity of the conversion:

    // The largest finite floating point number is 1.mantissa * 2^(0x7fe-0x3ff).
    // Since 2^N in binary is a one bit followed by N zero bits. 1 * 2^3ff requires
    // at most 1024 characters to the left of a decimal point, in base 2 (1025 if
    // we include a minus sign). For the fraction, a value with an exponent of 0
    // has up to 52 bits to the right of the decimal point. Each decrement of the
    // exponent down to a minimum of -0x3fe adds an additional digit to the length
    // of the fraction. As such the maximum fraction size is 1075 (1076 including
    // a point). We pick a buffer size such that can simply place the point in the
    // center of the buffer, and are guaranteed to have enough space in each direction
    // fo any number of digits an IEEE number may require to represent.
    typedef char RadixBuffer[2180];

    // Mapping from integers 0..35 to digit identifying this value, for radix 2..36.
    static const char* const radixDigits = "0123456789abcdefghijklmnopqrstuvwxyz";

    static char* toStringWithRadix(RadixBuffer& buffer, double number, unsigned radix)
    {
        ASSERT(isfinite(number));
        ASSERT(radix >= 2 && radix <= 36);

        // Position the decimal point at the center of the string, set
        // the startOfResultString pointer to point at the decimal point.
        char* decimalPoint = buffer + sizeof(buffer) / 2;
        char* startOfResultString = decimalPoint;

        // Extract the sign.
        bool isNegative = number < 0;
        if (signbit(number))
            number = -number;
        double integerPart = floor(number);

        // We use this to test for odd values in odd radix bases.
        // Where the base is even, (e.g. 10), to determine whether a value is even we need only
        // consider the least significant digit. For example, 124 in base 10 is even, because '4'
        // is even. if the radix is odd, then the radix raised to an integer power is also odd.
        // E.g. in base 5, 124 represents (1 * 125 + 2 * 25 + 4 * 5). Since each digit in the value
        // is multiplied by an odd number, the result is even if the sum of all digits is even.
        //
        // For the integer portion of the result, we only need test whether the integer value is
        // even or odd. For each digit of the fraction added, we should invert our idea of whether
        // the number is odd if the new digit is odd.
        //
        // Also initialize digit to this value; for even radix values we only need track whether
        // the last individual digit was odd.
        bool integerPartIsOdd = integerPart <= static_cast<double>(0x1FFFFFFFFFFFFFull) && static_cast<int64_t>(integerPart) & 1;
        ASSERT(integerPartIsOdd == static_cast<bool>(fmod(integerPart, 2)));
        bool isOddInOddRadix = integerPartIsOdd;
        uint32_t digit = integerPartIsOdd;

        // Check if the value has a fractional part to convert.
        double fractionPart = number - integerPart;
        if (fractionPart) {
            // Write the decimal point now.
            *decimalPoint = '.';

            // Higher precision representation of the fractional part.
            Uint16WithFraction fraction(fractionPart);

            bool needsRoundingUp = false;
            char* endOfResultString = decimalPoint + 1;

            // Calculate the delta from the current number to the next & previous possible IEEE numbers.
            double nextNumber = nextafter(number, std::numeric_limits<double>::infinity());
            double lastNumber = nextafter(number, -std::numeric_limits<double>::infinity());
            ASSERT(isfinite(nextNumber) && !signbit(nextNumber));
            ASSERT(isfinite(lastNumber) && !signbit(lastNumber));
            double deltaNextDouble = nextNumber - number;
            double deltaLastDouble = number - lastNumber;
            ASSERT(isfinite(deltaNextDouble) && !signbit(deltaNextDouble));
            ASSERT(isfinite(deltaLastDouble) && !signbit(deltaLastDouble));

            // We track the delta from the current value to the next, to track how many digits of the
            // fraction we need to write. For example, if the value we are converting is precisely
            // 1.2345, so far we have written the digits "1.23" to a string leaving a remainder of
            // 0.45, and we want to determine whether we can round off, or whether we need to keep
            // appending digits ('4'). We can stop adding digits provided that then next possible
            // lower IEEE value is further from 1.23 than the remainder we'd be rounding off (0.45),
            // which is to say, less than 1.2255. Put another way, the delta between the prior
            // possible value and this number must be more than 2x the remainder we'd be rounding off
            // (or more simply half the delta between numbers must be greater than the remainder).
            //
            // Similarly we need track the delta to the next possible value, to dertermine whether
            // to round up. In almost all cases (other than at exponent boundaries) the deltas to
            // prior and subsequent values are identical, so we don't need track then separately.
            if (deltaNextDouble != deltaLastDouble) {
                // Since the deltas are different track them separately. Pre-multiply by 0.5.
                Uint16WithFraction halfDeltaNext(deltaNextDouble, 1);
                Uint16WithFraction halfDeltaLast(deltaLastDouble, 1);

                while (true) {
                    // examine the remainder to determine whether we should be considering rounding
                    // up or down. If remainder is precisely 0.5 rounding is to even.
                    int dComparePoint5 = fraction.comparePoint5();
                    if (dComparePoint5 > 0 || (!dComparePoint5 && (radix & 1 ? isOddInOddRadix : digit & 1))) {
                        // Check for rounding up; are we closer to the value we'd round off to than
                        // the next IEEE value would be?
                        if (fraction.sumGreaterThanOne(halfDeltaNext)) {
                            needsRoundingUp = true;
                            break;
                        }
                    } else {
                        // Check for rounding down; are we closer to the value we'd round off to than
                        // the prior IEEE value would be?
                        if (fraction < halfDeltaLast)
                            break;
                    }

                    ASSERT(endOfResultString < (buffer + sizeof(buffer) - 1));
                    // Write a digit to the string.
                    fraction *= radix;
                    digit = fraction.floorAndSubtract();
                    *endOfResultString++ = radixDigits[digit];
                    // Keep track whether the portion written is currently even, if the radix is odd.
                    if (digit & 1)
                        isOddInOddRadix = !isOddInOddRadix;

                    // Shift the fractions by radix.
                    halfDeltaNext *= radix;
                    halfDeltaLast *= radix;
                }
            } else {
                // This code is identical to that above, except since deltaNextDouble != deltaLastDouble
                // we don't need to track these two values separately.
                Uint16WithFraction halfDelta(deltaNextDouble, 1);

                while (true) {
                    int dComparePoint5 = fraction.comparePoint5();
                    if (dComparePoint5 > 0 || (!dComparePoint5 && (radix & 1 ? isOddInOddRadix : digit & 1))) {
                        if (fraction.sumGreaterThanOne(halfDelta)) {
                            needsRoundingUp = true;
                            break;
                        }
                    } else if (fraction < halfDelta)
                        break;

                    ASSERT(endOfResultString < (buffer + sizeof(buffer) - 1));
                    fraction *= radix;
                    digit = fraction.floorAndSubtract();
                    if (digit & 1)
                        isOddInOddRadix = !isOddInOddRadix;
                    *endOfResultString++ = radixDigits[digit];

                    halfDelta *= radix;
                }
            }

            // Check if the fraction needs rounding off (flag set in the loop writing digits, above).
            if (needsRoundingUp) {
                // Whilst the last digit is the maximum in the current radix, remove it.
                // e.g. rounding up the last digit in "12.3999" is the same as rounding up the
                // last digit in "12.3" - both round up to "12.4".
                while (endOfResultString[-1] == radixDigits[radix - 1])
                    --endOfResultString;

                // Radix digits are sequential in ascii/unicode, except for '9' and 'a'.
                // E.g. the first 'if' case handles rounding 67.89 to 67.8a in base 16.
                // The 'else if' case handles rounding of all other digits.
                if (endOfResultString[-1] == '9')
                    endOfResultString[-1] = 'a';
                else if (endOfResultString[-1] != '.')
                    ++endOfResultString[-1];
                else {
                    // One other possibility - there may be no digits to round up in the fraction
                    // (or all may be been rounded off already), in which case we may need to
                    // round into the integer portion of the number. Remove the decimal point.
                    --endOfResultString;
                    // In order to get here there must have been a non-zero fraction, in which case
                    // there must be at least one bit of the value's mantissa not in use in the
                    // integer part of the number. As such, adding to the integer part should not
                    // be able to lose precision.
                    ASSERT((integerPart + 1) - integerPart == 1);
                    ++integerPart;
                }
            } else {
                // We only need to check for trailing zeros if the value does not get rounded up.
                while (endOfResultString[-1] == '0')
                    --endOfResultString;
            }

            *endOfResultString = '\0';
            ASSERT(endOfResultString < buffer + sizeof(buffer));
        } else
            *decimalPoint = '\0';

        BigInteger units(integerPart);

        // Always loop at least once, to emit at least '0'.
        do {
            ASSERT(buffer < startOfResultString);

            // Read a single digit and write it to the front of the string.
            // Divide by radix to remove one digit from the value.
            digit = units.divide(radix);
            *--startOfResultString = radixDigits[digit];
        } while (!!units);

        // If the number is negative, prepend '-'.
        if (isNegative)
            *--startOfResultString = '-';
        ASSERT(buffer <= startOfResultString);

        return startOfResultString;
    }

... as you can see, the number here is backed by a traditional double and the conversion is anything but simple and straightforward. So what I devised was this: since I conjecture that the only spot that these implementations will differ are their "rendering" to strings. I built a test generator that is three fold:

  1. tests the "string result" against a reference string result
  2. tests their parsed equivalents (ignoring any epsilon, I mean exact!)
  3. tests a special version of the strings that solely adjusts for the rounding "interpretation"

To accomplish this we need access to a reference build, my first thought was to use one from a native language but with that I found that the numbers produced seemed to have a higher precision than JavaScript in general leading to far more errors. So then I thought, what if I just used an implementation already inside a JavaScript engine. WebKit/JavaScriptCore seemed like a really good choice but it would have also been a lot of work to get the reference build up and running so I opted for the simplicity of .NET since it has access to "jScript" while not ideal seemed upon initial examination to produce closer results than the native counterpart. I didn't really want to code in jScript since the language is all but deprecated so I opted for C# bootstrapping jScript through a CodeDomProvider.... After a little tinkering here's what it produced: http://jsbin.com/afiqil (finally demo sauce!!!!1!), so now you can run it in all browsers and compile your own data, which upon my personal inspection it seems string rounding interpretation varies in EVERY browser I tried, however I've yet to find a major browser that handled the numbers behind the scenes (other that the stringify-ing) differently...

now for the C# sauce:

    using System;
    using System.Collections.Generic;
    using System.ComponentModel;
    using System.Data;
    using System.Drawing;
    using System.Linq;
    using System.Text;
    using System.Windows.Forms;
    using System.CodeDom.Compiler;
    using System.Reflection;

    namespace DoubleFloatJs
    {
        public partial class Form1 : Form
        {

            private static string preamble = @"

    var successes = [];
    var failures = [];

    function fpu_test_add(v1, v2) {
        return '' + (v1 + v2);  
    }

    function fpu_test_sub(v1, v2) {
        return '' + (v1 - v2);
    }

    function fpu_test_mul(v1, v2) {
        return '' + (v1 * v2);
    }

    function fpu_test_div(v1, v2) {
        return '' + (v1 / v2);
    }

    function format(name, result1, result2, result3, received, expected) {
        return '<span style=""display:inline-block;width:350px;"">' + name + '</span>' +
            '<span style=""display:inline-block;width:60px;text-align:center;font-weight:bold; color:' + (result1 ? 'green;"">OK' : 'red;"">NO') + '</span>' + 
            '<span style=""display:inline-block;width:60px;text-align:center;font-weight:bold; color:' + (result2 ? 'green;"">OK' : 'red;"">NO') + '</span>' + 
            '<span style=""display:inline-block;width:60px;text-align:center;font-weight:bold; color:' + (result3 ? 'green;"">OK' : 'red;"">NO') + '</span>' + 
            '<span style=""display:inline-block;width:200px;vertical-align:top;"">' + received + '<br />' + expected + '</span>';
    }

    function check_ignore_round(received, expected) {
        return received.length > 8 &&
            received.length == expected.length && 
            received.substr(0, received.length - 1) === expected.substr(0, expected.length - 1);
    }

    function check_parse_parity_no_epsilon(received, expected) {
        return parseFloat(received) === parseFloat(expected);
    }

    function fpu_test_result(v1, v2, textFn, received, expected) {
        var result = expected === received,
            resultNoRound = check_ignore_round(received, expected),
            resultParse = check_parse_parity_no_epsilon(received, expected),
            resDiv = document.createElement('div');

        resDiv.style.whiteSpace = 'nowrap';
        resDiv.style.fontFamily = 'Courier New, Courier, monospace';
        resDiv.style.fontSize = '0.74em';
        resDiv.style.background = result ? '#aaffaa' : '#ffaaaa';
        resDiv.style.borderBottom = 'solid 1px #696969';
        resDiv.style.padding = '2px';

        resDiv.innerHTML = format(textFn + '(' + v1 + ', ' + v2 + ')', result, resultNoRound, resultParse, received, expected);

        document.body.appendChild(resDiv);
        (result ? successes : failures).push(resDiv);
        return resDiv;
    }

    function fpu_test_run(v1, v2, addRes, subRes, mulRes, divRes) {
        var i, res, 
            fnLst = [fpu_test_add, fpu_test_sub, fpu_test_mul, fpu_test_div],
            fnNam = ['add', 'sub', 'mul', 'div'];

        for (i = 0; i < fnLst.length; i++) {
            res = fnLst[i].call(null, v1, v2);
            fpu_test_result(v1, v2, fnNam[i], res, arguments[i + 2]);
        }
    }

    function setDisplay(s, f) {
        var i;
        for (i = 0; i < successes.length; i++) {
            successes[i].style.display = s;
        }
        for (i = 0; i < failures.length; i++) {
            failures[i].style.display = f;
        }
    }

    var test_header = fpu_test_result('value1', 'value2', 'func', 'received', 'expected'),
        test_header_cols = test_header.getElementsByTagName('span');

    test_header_cols[1].innerHTML = 'string';
    test_header_cols[2].innerHTML = 'rounded';
    test_header_cols[3].innerHTML = 'parsed';
    test_header.style.background = '#aaaaff';

    failures.length = successes.length = 0;

    ";

            private static string summation = @"

    var bs = document.createElement('button');
    var bf = document.createElement('button');
    var ba = document.createElement('button');

    bs.innerHTML = 'show successes (' + successes.length + ')';
    bf.innerHTML = 'show failures (' + failures.length + ')';
    ba.innerHTML = 'show all (' + (successes.length + failures.length) + ')';

    ba.style.width = bs.style.width = bf.style.width = '200px';
    ba.style.margin = bs.style.margin = bf.style.margin = '4px';
    ba.style.padding = bs.style.padding = bf.style.padding = '4px';

    bs.onclick = function() { setDisplay('block', 'none'); };
    bf.onclick = function() { setDisplay('none', 'block'); };
    ba.onclick = function() { setDisplay('block', 'block'); };

    document.body.insertBefore(bs, test_header);
    document.body.insertBefore(bf, test_header);
    document.body.insertBefore(ba, test_header);
    document.body.style.minWidth = '700px';

    ";

            private void buttonGenerate_Click(object sender, EventArgs e)
            {
                var numberOfTests = this.numericNumOfTests.Value;
                var strb = new StringBuilder(preamble);
                var rand = new Random();

                for (int i = 0; i < numberOfTests; i++)
                {
                    double v1 = rand.NextDouble();
                    double v2 = rand.NextDouble();

                    strb.Append("fpu_test_run(")
                        .Append(v1)
                        .Append(", ")
                        .Append(v2)
                        .Append(", '")
                        .Append(JsEval("" + v1 + '+' + v2))
                        .Append("', '")
                        .Append(JsEval("" + v1 + '-' + v2))
                        .Append("', '")
                        .Append(JsEval("" + v1 + '*' + v2))
                        .Append("', '")
                        .Append(JsEval("" + v1 + '/' + v2))
                        .Append("');")
                        .AppendLine();
                }

                strb.Append(summation);

                this.textboxOutput.Text = strb.ToString();
                Clipboard.SetText(this.textboxOutput.Text);
            }

            public Form1()
            {
                InitializeComponent();

                Type evalType = CodeDomProvider
                    .CreateProvider("JScript")
                    .CompileAssemblyFromSource(new CompilerParameters(), "package e{class v{public static function e(e:String):String{return eval(e);}}}")
                    .CompiledAssembly
                    .GetType("e.v");

                this.JsEval = s => (string)evalType.GetMethod("e").Invoke(null, new[] { s });
            }

            private readonly Func<string, string> JsEval;

        }
    }

or a pre-compiled version if you should choose: http://uploading.com/files/ad4a85md/DoubleFloatJs.exe/ this is an executable, download at your own risk

screen shot of test generator application

I should mention that the purpose of the program is just to produce a JavaScript file in a text box and copy it to the clipboard for convenience for pasting wherever you choose, you could easily turn this around and put it on an asp.net server and add reporting to results to ping the server and keep track in some massive database... which is what I would do to it if I desired the information..

...and, ...I'm, ...spent I hope this helps you -ck

share|improve this answer
1  
Very good! I would like to take all the points every awarded to everyone who ever said "in jQuery you can...." and give them all to you. This is a research question, the bounty is going to go to whoever provides the best data towards a conclusion. We'll see where that is at the end of the bounty, but for the moment I commend this response for up votes. –  leebriggs Mar 7 '12 at 20:46
    
Part of this question came from solving the same sort of problem in C where it was sometimes necessary to verify the fpu compiler options at run time. As you say, much easier with binary access, but there are still some options. Try in the console (1e154 * 1e154) / 1e154, then again as (1e155 * 1e155) / 1e155. That was one of my first trivial checks to see if any browsers were using 80-bit precision. –  leebriggs Mar 7 '12 at 20:57
add comment

General rule of thumb is that when number precision is important and you only have access to floating point precision numbers, all of your calculations should be done as integer math to best ensure validity (where you're assured 15 digits of assuredly valid data). And yes there are a bunch of general numeric idiosyncrasies in JavaScript but they are more associated with the lack of precision within floating point numbers and not with UA implementations of the standard. Look around for the pitfalls of floating point math, they're numerous and treacherous.

I feel as I should elaborate a little, for instance I wrote a program (in JavaScript) that used basic calculus to determine the area of polygon with dimensions given in meters or feet. Instead of doing the calculations as is, the program converted everything to micrometers and did its calculations there as everything would be more integral.

hope this helps -ck


In response to your clarification, comments and concerns

I'm not going to repeat my comments below in their entirety, however the short answer is no one will ever be able to say that EVERY IMPLEMENTATION is 100% on 100% of devices. Period. I can say and others will tell you the same, is that on the current major browsers I have not seen nor heard of any browser specific detrimental bug involving floating point numbers. But your question itself is kind of a double edged sword since you want to "rely" upon "unreliable" results, or simply that you want all the browsers to be "consistently inconsistent" - in other words instead of trying make sure a lion will play fetch, your time would be better spent looking for a dog, meaning: you can rely 110% on integer math AND the results of said math, the same goes for string math which has already been suggested to you...

good luck -ck

share|improve this answer
    
I'm afraid it doesn't help me, but the advice is valid for others when precision is a problem. –  leebriggs Feb 22 '12 at 8:00
    
For me, floating point is the correct choice. My problem concerns consistency and whether all browsers treat floating point numbers in a reliable manner. –  leebriggs Feb 22 '12 at 8:10
    
@leebriggs since there is an almost endless number of UAs out there it is all but impossible to say that this is consistent across all of them. what i will say it the implementation is very consistent across all the major browsers currently in use. As a matter if fact in all my time I can't say that I've run into a UA specific floating point number bug. -ck –  ckozl Feb 22 '12 at 9:59
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@leebriggs and then test them on each major stepping stone of each applicable architecture (different processors etc..) since math runs pretty close to the metal...and only then could you be 100% and only for a few months until a new browser/architecture comes out. As I said before IF you need 100% certainty there are better ways to do it then maintaining crazy browser compatibility list. So, the short answer is no one will ever know. The long answer I already gave you, and if I were you I would just forge ahead and stop worrying about something that you're not even sure is broken –  ckozl Mar 2 '12 at 13:27
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@cris It might well come to a few enquiries out to the browser teams, but starting here first. I'm starting with the presumption that some browsers would fail, but have little insight as to whether that would be 10%, 1%, 0.1% or 0.01%. –  leebriggs Mar 6 '12 at 12:33
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Summarizing everything below, you can expect compliance on the majority of systems save for a few IE's glitches, but ought to use a sanity check as a precaution (proposition is included).

To validate a system, you can use float-related tests from test262. They are located at http://test262.ecmascript.org/json/ch<2-digit # of spec chapter>.json; test code can be extracted with (python 2.6+):

ch="05";  #substitute chapter #
import urllib,json,base64
j=json.load(urllib.urlopen("http://test262.ecmascript.org/json/ch%s.json"%ch))
tt=j['testsCollection']['tests']
f=open('ch%s.js'%ch,'w')
for t in tt:
  print >>f
  print >>f,base64.b64decode(t['code'])
f.close()

Another opportunity is IEEE 754 compliance tests in C.

Relevant sections from test262 (ones that compare floating point numbers) are as follows:

{
"S11": "5.1.A4: T1-T8",
"S15": {
    "7": "3: 2.A1 & 3.A1",
    "8": {
        "1": "1-8: A1",
        "2": {
            "4": "A4 & A5",
            "5": "A: 3,6,7,10-13,15,17-19",
            "7": "A6 & A7",
            "13": "A24",
            "16": "A6 & A7",
            "17": "A6",
            "18": "A6"
        }
    }
},
"S8": "5.A2: 1 & 2"
}

this list and the concatenated source of all the relevant test files (as of 3/9/2012, no files from the harness) can be found here: http://pastebin.com/U6nX6sKL

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Thank you, that's really useful. In particular, I'll be poking around inside some parts of test262. –  leebriggs Mar 9 '12 at 9:49
    
this will probably be definitive when and if test262 is ever finished, but as of right now the test is incomplete and does very little in the realm of floating point precision consistency validation, here are all the sections (as of 3/9/2012) that compare floating point numbers included in the test and their source pastebin.com/U6nX6sKL as you can see the only consistency validation is in the realm of trigonometric functions along with Math.pow and Math.sqrt checks... I'll edit the relevant sections into the community answer above –  ckozl Mar 9 '12 at 15:53
    
How are you gonna test "precision consistency"? You cannot check the rounding of every possible result on the number axis in a reasonable time. A few math fns look fine for me as a sanity check. They do validate the precision and rounding mode used - assuming the same ones are used in all other cases. –  ivan_pozdeev Mar 9 '12 at 21:48
    
@ivan_pozdeev there are only 2 tests in ALL of test262 (that I am aware of) that have anything to do with precision, and NEITHER check anything about the "rounding" mode, they are: [ 8.5_A2.1 - Number type represented as the double precision 64-bit format IEEE 754 AND 8.5_A2.2 - Number type represented as the extended precision 64-bit format IEEE 754 ]. Furthermore who said anything about "reasonable time" test262 can take 30 minutes to run on a slow machine and no one ever said anything about doing this "online" only compiling data has ever been mentioned, so if you happen... –  ckozl Mar 12 '12 at 12:47
    
ch15/15.8/15.8.2/15.8.2.16/S15.8.2.16_A7.js, calculated sin values are compared with reference ones. If precision is low, large discrepancy will occur (I just checked this in C). If rounding mode is different, the last meaningful digit wouldn't match. ch15/15.8/15.8.2/15.8.2.16/S15.8.2.16_A6.js, sin is checked to be periodic up to 100 periods. If net rounding error is greater than the reference 3e-12 , we'll see it too. –  ivan_pozdeev Mar 12 '12 at 23:29
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"I have a specific use in mind for a distributed web application, which would only work if I can rely on consistent results across all browsers."

Then the answer is no. You can not relay on a specification to tell you that a browser correctly handles floats. Chrome updates every 6 weeks, so even if you have the specifications Chrome could change there behavior in the next release.

You have to relay on feature testing that test your assumptions before each time before you calculations is run.

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Maybe you should use a library for your calculations. For example bignumber has a good handling of floating point numbers. Here you should be save from environment changes because it uses it's own storage format.

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This is a problem since ages in computing. And if you ask old programmers who matured from assembly language, they will tell you that you store important numbers in a different format and do manipulations on them in similar way too.

For example, a currency value can be saved as integer by multiplying the float value by 100 (to keep the 2 decimal places intact). You can then safely do calculations and when you have to display the final result, divide there by 100. Depending upon how many decimal places you have to keep secure and safe, you may have to select a different number other than 100. Store things in a long value and be care-free about such problems ever.

This is what gives me satisfactory results across platforms so far. I just keep myself away from the floating point arithmetic nuances this way

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I'm really not sure how I could have made it any clearer in the question that this wasn't a suitable answer. I went searching for an old programmer who matured from assembly language and found one in the mirror. –  leebriggs Mar 15 '12 at 15:37
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