A Julia port of "Routines for Arbitrary Precision Floating-point Arithmetic and Fast Robust Geometric Predicates" by Jonathan Richard Shewchuk. https://www.cs.cmu.edu/~quake/robust.html
The package provides four predicates. In the functions below, all the inputs should be NTuple
s with either Float64
or Float32
coordinates; complex inputs can be used for orient2
and incircle
.
orient2(pa, pb, pc)
: Given three pointspa
,pb
, andpc
in two dimensions, returns a positive value if the points are in counter-clockwise order; a negative value if they occur in clockwise order; and zero if they are collinear. Equivalently, returns a positive value ifpc
is left of the oriented line frompa
topb
; a negative value ifpc
is right of this line; and zero if they are collinear.orient3(pa, pb, pc, pd)
: Given four pointspa
,pb
,pc
, andpd
in three dimensions, define the oriented plane on which the triangle(pa, pb, pc)
is positively oriented. Returns a positive value ifpd
is below this plane; a negative value ifpd
is above this plane; and zero if the points are coplanar.incircle(pa, pb, pc, pd)
: Given four pointspa
,pb
,pc
, andpd
in two dimensions, returns a positive value ifpd
is inside the circle throughpa
,pb
, andpc
; a negative value ifpd
is outside this circle; and zero ifpd
is on the circle.insphere(pa, pb, pc, pd, pe)
: Given five pointspa
,pb
,pc
,pd
, andpe
in three dimensions, returns a positive value ifpe
inside of the sphere throughpa
,pb
,pc
, andpd
; a negative value ifpe
is outside this sphere; and zero ifpe
is on the sphere.
We also define the functions orient2p
, orient3p
, incirclep
, and inspherep
which simply return the sign of the corresponding predicate. For example,
julia> using AdaptivePredicates
julia> pa, pb, pc = (0.2, 0.3), (0.1, -0.5), (0.7, 0.3);
julia> orient2(pa, pb, pc)
0.39999999999999997
julia> orient2p(pa, pb, pc)
1
julia> pa, pb, pc, pd, pe = (0.3f0, 0.3f0, 0.17f0), (-0.3f0, 1.71f0, 0.0f0), (0.0f0, 0.0f0, 5.0f0), (1.1f0, -0.53f0, 1.2f0), (0.5f0, 0.50f0, 0.5f0);
julia> insphere(pa, pb, pc, pd, pe)
-5.021922f0
julia> inspherep(pa, pb, pc, pd, pe)
-1
If you want to use the package, you can do
using Pkg
Pkg.add("AdaptivePredicates")
using AdaptivePredicates
All the functions from the predicates.c
file from Shewchuk's original code have been included in this package. This includes,
- All macros have been implemented as functions, e.g.
Fast_Two_Sum
andFour_Four_Sum
. - All arithmetic functions have been implemented, e.g.
grow_expansion
andscale_expansion_zeroelim
. - All the predicates have been implemented. In particular, not only have
orient2
,orient3
,incircle
, andinsphere
been implemented, but also the forms with the suffixesfast
,exact
, andslow
(andadapt
, but this is whatorient2
,orient3
,incircle
, andinsphere
use anyway).
Only the functions orient2
, orient3
, incircle
, and insphere
have been marked as public
, as well as their p
and fast
counterparts.
Shewchuk's original paper gives no analysis in the presence of underflow or overflow. The only mention of it is:
This article does not address issues of overflow and underflow, so I allow the exponent to be an integer in the range
$[-\infty, \infty]$ . (Fortunately, many applications have inputs whose exponents fall within a circumscribed range. The four predicates implemented for this article will not overflow nor underflow if their inputs have exponents in the range$[-142, 201]$ and IEEE 754 double precision arithmetic is used.)
- Richard Shewchuk, J. Adaptive Precision Floating-Point Arithmetic and Fast Robust Geometric Predicates. Discrete Comput Geom 18(3), 305–363 (1997)
Note that this range comes from the insphere
predicate. The number range is much wider for orient2
, for example, since it requires far fewer additions, subtractions, and multiplications.
Thus, for some numbers, the values returned from these predicates may be invalid due to underflow or overflow. In ranges where this is a concern, you should use ExactPredicates.jl instead. If you need the values of the predicates and not just their signs, but are outside of the range valid for AdaptivePredicates.jl, you are unfortunately out of luck.
If you need more information about how these predicates work, you should refer to Shewchuk's paper.
The original code is in the public domain and this Julia port is under the MIT License.