*Audience*: LEWG, SG6; WG14

S. Davis Herring <>

Los Alamos National Laboratory

February 9, 2018

The simple problem of computing a value between two other values is surprisingly subtle in general. This paper proposes library functions to compute the midpoint between two integer, floating-point, or pointer values, as well as a more general routine that interpolates (or extrapolates) between two floating-point values.

These utilities are a pure library extension. With the exception of the pointer versions, they would be valuable and straightforward to implement in C (perhaps via type-generic macros); it would be appropriate to consult with WG14 about including them in the C standard library.

Computing the (integer) midpoint of two integer values via

`(a+b)/2`

can cause overflow for signed or unsigned integers as well as for floating-point values. Java’s binary search implementation had this integer overflow bug for nearly a decade, and Mozilla had the same issue in its JavaScript implementation.

The standard alternative

`a+(b-a)/2`

works for unsigned integers (even if `b<a`

). On a typical two’s complement implementation where conversion from unsigned to signed preserves bit patterns, the library can provide the simple implementation

```
Integer midpoint(Integer a, Integer b) {
using U = make_unsigned_t<Integer>;
return Integer(U(a)+(U(b)-U(a))/2);
}
```

that works for signed or unsigned `Integer`

. Note that when `b==a+1`

or `b==a-1`

(without overflow), the result is *a* because of truncating division. This can be exploited to round half-integers up or down by supplying `a>=b`

or `a<=b`

respectively. (The simple `(a+b)/2`

always truncates half-integers towards 0, yielding `min(a,b)`

when they differ by 1.)

When a binary search over an array is implemented using pointers, the array size must not exceed `PTRDIFF_MAX`

to avoid undefined behavior ([expr.add]/5). The library can also provide a function template

```
template<class T>
T* midpoint(T *a, T *b);
```

which is straightforward on common architectures but, it seems, **cannot be implemented** portably and efficiently in C++. As with integers, when the midpoint lies between two pointer values the one closer to `a`

is chosen; for the usual case of `a<b`

, this is compatible with the usual half-open ranges by selecting `a`

when `[a,b)`

is `[a,a+1)`

.

Each of the midpoint formulas above can cause overflow for floating-point types; the latter can also produce results that are not correctly rounded (by rounding in the subtraction and the addition). A third choice

`a/2+b/2`

prevents overflow but is not correctly rounded for subnormal inputs (due to rounding each separately). The library can easily provide overloads of `midpoint`

for floating-point types that is correctly rounded for all inputs by switching between these strategies:

```
Float midpoint(Float a, Float b)
{return isnormal(a) && isnormal(b) ? a/2+b/2 : (a+b)/2;}
```

The name `mean`

is superior for the floating-point case, but for the other types (and the common application to binary search) the name `midpoint`

used above is more appropriate. It would be possible to use both names (despite the possible confusion with the use of `mean`

in [rand.dist]), but as it aims to replace the simple expression `a+(b-a)/2`

regardless of type, a single name seems best.

Both obvious approaches used in published implementations of floating-point linear interpolation have issues:

`a+t*(b-a)`

does not in general reproduce*b*when`t==1`

, and can overflow if*a*and*b*have the largest exponent and opposite signs.`t*b+(1-t)*a`

is not monotonic in general (unless`a*b<=0`

).

Lacking an obvious, efficient means of obtaining a correctly rounded overall result, the goal is instead to guarantee the basic properties of

*exactness*:`linear(a,b,0)==a && linear(a,b,1)==b`

*monotonicity*:`(linear(a,b,t2)-linear(a,b,t1)) * (t2-t1) * (b-a) >= 0`

*boundedness*:`t<0 || t>1 || isfinite(linear(a,b,t))`

*consistency*:`linear(a,a,t)==a`

given that each argument `isfinite`

(for monotonicity, *t1* and *t2* may also be infinite if `a!=b`

and `t1!=t2`

). These properties are useful in proofs of correctness of algorithms based on `linear`

. When interpolating, consistency follows from the other properties, but it and monotonicity apply even when extrapolating.

To demonstrate the feasibility of satisfying these properties, a simple implementation that provides all of them is given here:

```
Float linear(Float a, Float b, Float t) {
// Exact, monotonic, bounded, and (for a=b=0) consistent:
if(a*b <= 0) return t*b + (1-t)*a;
if(t==1) return b; // exact
// Exact at t=0, monotonic except near t=1, bounded, and consistent:
const Float x = a + t*(b-a);
return t>1 == b>a ? max(b,x) : min(b,x); // monotonic near t=1
}
```

Putting `b`

first in the `min`

/`max`

prefers it to another equal value (i.e., `-0.`

vs. `+0.`

), which avoids returning `-0.`

for `t==1`

but `+0.`

for other nearby values of *t*.

Whether it uses this implementation or not, the library can provide a function satisfying these mathematical properties.

The common (if abstruse) name `lerp`

is avoided because it might suggest a restriction to *t* on [0,1].

Add to the end of the synopsis in [numeric.ops.overview]:

```
// 29.8.14, least common multiple
template<class M, class N>
constexpr common_type_t<M,N> lcm(M m, N n);
```

` `

`A midpoint(A a, A b); // A arithmetic`

` `

`template<class T>`

` `

`T* midpoint(T* a, T* b);`

`}`

Add a new subsection after [numeric.ops.lcm]:

`A midpoint(A a, A b);`

*Returns:*Half the sum of`a`

and`b`

. No overflow occurs. If`A`

is an integer type and the sum is odd, the result is rounded towards`a`

. If`A`

is a floating-point type, at most one inexact operation occurs.*Remarks:*An overload exists for each of`char`

and all arithmetic types except`bool`

being`A`

.

```
template<class T>
T* midpoint(T* a, T* b);
```

*Requires:*`a`

and`b`

point to, respectively, elements`x[`

*i*`]`

and`x[`

*j*`]`

of the same array object`x`

[*Footnote:*An object that is not an array element is considered to belong to a single-element array for this purpose; see [expr.unary.op]. A pointer past the last element of an array x of n elements is considered to be equivalent to a pointer to a hypothetical element x[n] for this purpose; see [basic.compound]. —*end footnote*].*Returns:*A pointer to`x[`

*i*+(*j*-*i*)/2`]`

, where the result of the division is truncated towards zero.

Add to the synopsis in [cmath.syn]:

`long double fmal(long double x, long double y, long double z);`

`// 29.9.4, linear interpolation`

`F linear(F a, F b, F t); // F floating-point`

`// 29.9.4, classification / comparison functions`

Add a new subsection after [c.math.hypot3]:

`F linear(F a, F b, F t);`

*Returns:**a*+*t*(*b*-*a*). If each argument`isfinite`

, the result satisfies these conditions:`t<0 || t>1 || isfinite(linear(a,b,t))`

`linear(a,b,0)==a && linear(a,b,1)==b`

`linear(a,a,t)==a`

`(linear(a,b,t2)-linear(a,b,t1)) * (t2-t1) * (b-a) >= 0`

`!isnan(t1) && !isnan(t2) && t1!=t2 && a!=b`

.*Remarks:*An overload exists for each floating-point type being`F`

.