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123 lines
6.5 KiB
Plaintext
123 lines
6.5 KiB
Plaintext
[section:float_comparison Floating-point Comparison]
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[import ../../example/float_comparison_example.cpp]
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Comparison of floating-point values has always been a source of endless difficulty and confusion.
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Unlike integral values that are exact, all floating-point operations
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will potentially produce an inexact result that will be rounded to the nearest
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available binary representation. Even apparently inocuous operations such as assigning
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0.1 to a double produces an inexact result (as this decimal number has no
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exact binary representation).
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Floating-point computations also involve rounding so that some 'computational noise' is added,
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and hence results are also not exact (although repeatable, at least under identical platforms and compile options).
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Sadly, this conflicts with the expectation of most users, as many articles and innumerable cries for help show all too well.
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Some background reading is:
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* Knuth D.E. The art of computer programming, vol II, section 4.2, especially Floating-Point Comparison 4.2.2, pages 198-220.
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* [@http://docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html David Goldberg, "What Every Computer Scientist Should Know About Floating-Point Arithmetic"]
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* [@http://adtmag.com/articles/2000/03/16/comparing-floatshow-to-determine-if-floating-quantities-are-close-enough-once-a-tolerance-has-been-r.aspx
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Alberto Squassabia, Comparing floats listing]
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* [@https://code.google.com/p/googletest/wiki/AdvancedGuide#Floating-Point_Comparison Google Floating-Point_Comparison guide]
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* [@boost:/libs/test/doc/html/boost_test/users_guide/testing_tools/testing_floating_points.html Boost.Test Floating-Point_Comparison]
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Boost provides a number of ways to compare floating-point values to see if they are tolerably close enough to each other,
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but first we must decide what kind of comparison we require:
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* Absolute difference/error: the absolute difference between two values ['a] and ['b] is simply `fabs(a-b)`.
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This is the only meaningful comparison to make if we know that the result may have cancellation error (see below).
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* The edit distance between the two values: i.e. how many (binary) floating-point values are between two values ['a] and ['b]?
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This is provided by the function __float_distance, but is probably only useful when you know that the distance should be very small.
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This function is somewhat difficult to compute, and doesn't scale to values that are very far apart. In other words, use with care.
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* The relative distance/error between two values. This is quick and easy to compute, and is generally the method of choice when
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checking that your results are "tolerably close" to one another. However, it is not as exact as the edit distance when dealing
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with small differences, and due to the way floating-point values are encoded can "wobble" by a factor of 2 compared to the "true"
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edit distance. This is the method documented below: if `float_distance` is a surgeon's scalpel, then `relative_difference` is more
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like a Swiss army knife: both have important but different use cases.
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[h5:fp_relative Relative Comparison of Floating-point Values]
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`#include <boost/math/special_functions/relative_difference.hpp>`
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template <class T, class U>
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``__sf_result`` relative_difference(T a, U b);
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template <class T, class U>
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``__sf_result`` epsilon_difference(T a, U b);
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The function `relative_difference` returns the relative distance/error ['E] between two values as defined by:
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[pre E = fabs((a - b) / min(a,b))]
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The function `epsilon_difference` is a convenience function that returns `relative_difference(a, b) / eps` where
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`eps` is the machine epsilon for the result type.
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The following special cases are handled as follows:
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* If either of ['a] or ['b] is a NaN, then returns the largest representable value for T: for example for type `double`, this
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is `std::numeric_limits<double>::max()` which is the same as `DBL_MAX` or `1.7976931348623157e+308`.
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* If ['a] and ['b] differ in sign then returns the largest representable value for T.
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* If both ['a] and ['b] are both infinities (of the same sign), then returns zero.
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* If just one of ['a] and ['b] is an infinity, then returns the largest representable value for T.
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* If both ['a] and ['b] are zero then returns zero.
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* If just one of ['a] or ['b] is a zero or a denormalized value, then it is treated as if it were the
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smallest (non-denormalized) value representable in T for the purposes of the above calculation.
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These rules were primarily designed to assist with our own test suite, they are designed to be robust enough
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that the function can in most cases be used blindly, including in cases where the expected result is actually
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too small to represent in type T and underflows to zero.
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[h5 Examples]
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[compare_floats_using]
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[compare_floats_example_1]
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[compare_floats_example_2]
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[compare_floats_example_3]
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[compare_floats_example_4]
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[compare_floats_example_5]
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[compare_floats_example_6]
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All the above examples are contained in [@../../example/float_comparison_example.cpp float_comparison_example.cpp].
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[h5:small Handling Absolute Errors]
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Imagine we're testing the following function:
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double myspecial(double x)
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{
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return sin(x) - sin(4 * x);
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}
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This function has multiple roots, some of which are quite predicable in that both
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`sin(x)` and `sin(4x)` are zero together. Others occur because the values returned
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from those two functions precisely cancel out. At such points the relative difference
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between the true value of the function and the actual value returned may be ['arbitrarily
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large] due to [@http://en.wikipedia.org/wiki/Loss_of_significance cancellation error].
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In such a case, testing the function above by requiring that the values returned by
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`relative_error` or `epsilon_error` are below some threshold is pointless: the best
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we can do is to verify that the ['absolute difference] between the true
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and calculated values is below some threshold.
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Of course, determining what that threshold should be is often tricky,
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but a good starting point would be machine epsilon multiplied by the largest
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of the values being summed. In the example above, the largest value returned
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by `sin(whatever)` is 1, so simply using machine epsilon as the target for
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maximum absolute difference might be a good start (though in practice we may need
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a slightly higher value - some trial and error will be necessary).
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[endsect] [/section:float_comparison Floating-point comparison]
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[/
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Copyright 2015 John Maddock and Paul A. Bristow.
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Distributed under the Boost Software License, Version 1.0.
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(See accompanying file LICENSE_1_0.txt or copy at
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http://www.boost.org/LICENSE_1_0.txt).
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]
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