This is in branch Rambetter-math-fix-experiments.

- Added	lengthy	comment	to describe the	choice of smallestEpsilonAllowed
in polylib.c for the new 64 bit chopping code. 	I think	that this comment
will allow us to make sure that	we have	the correct choice of epsilon.

- Tweaked comments around VEC_SMALLEST_EPSILON_AROUND_ONE and
VEC_ACCU_SMALLEST_EPSILON_AROUND_ONE (actually renamed them).


git-svn-id: svn://svn.icculus.org/gtkradiant/GtkRadiant/branches/Rambetter-math-fix-experiments@383 8a3a26a2-13c4-0310-b231-cf6edde360e5
This commit is contained in:
rambetter 2010-12-30 09:47:01 +00:00
parent 56e74492bc
commit adf336fec1
2 changed files with 22 additions and 11 deletions

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@ -38,12 +38,12 @@ typedef vec_t vec3_t[3];
typedef vec_t vec5_t[5]; typedef vec_t vec5_t[5];
typedef vec_t vec4_t[4]; typedef vec_t vec4_t[4];
// Smallest positive value such that 1.0 + VEC_SMALLEST_EPSILON != 1.0 // Smallest positive value such that 1.0 + VEC_SMALLEST_EPSILON_AROUND_ONE != 1.0.
// In the case of 32 bits (which is the case), it's 0.00000011921. // In the case of 32 bits (which is likely the case), it's 0.00000011921.
// Don't forget that your epsilons should depend on the possible range of values, // Don't forget that your epsilons should depend on the possible range of values,
// because for example 1000.0 + VEC_SMALLEST_EPSILON will almost certainly be // because for example adding VEC_SMALLEST_EPSILON_AROUND_ONE to 1024.0 will almost
// equal to 1000.0. // certainly not change its value.
#define VEC_SMALLEST_EPSILON FLT_EPSILON #define VEC_SMALLEST_EPSILON_AROUND_ONE FLT_EPSILON
#define SIDE_FRONT 0 #define SIDE_FRONT 0
#define SIDE_ON 2 #define SIDE_ON 2
@ -316,12 +316,12 @@ vec_t ray_intersect_triangle(const ray_t *ray, qboolean bCullBack, const vec3_t
typedef double vec_accu_t; typedef double vec_accu_t;
typedef vec_accu_t vec3_accu_t[3]; typedef vec_accu_t vec3_accu_t[3];
// Smallest positive value such that 1.0 + VEC_ACCU_SMALLEST_EPSILON != 1.0 // Smallest positive value such that 1.0 + VEC_ACCU_SMALLEST_EPSILON_AROUND_ONE != 1.0.
// In the case of 64 bits (which is the case), it's 0.00000000000000022204. // In the case of 64 bits (which is likely the case), it's 0.00000000000000022204.
// Don't forget that your epsilons should depend on the possible range of values, // Don't forget that your epsilons should depend on the possible range of values,
// because for example 1000.0 + VEC_ACCU_SMALLEST_EPSILON will almost certainly // because for example adding VEC_ACCU_SMALLEST_EPSILON_AROUND_ONE to 1024.0 will almost
// be equal to 1000.0. // certainly not change its value.
#define VEC_ACCU_SMALLEST_EPSILON DBL_EPSILON #define VEC_ACCU_SMALLEST_EPSILON_AROUND_ONE DBL_EPSILON
// TODO: I have a feeling it may be safer to break these function out into actual functions // TODO: I have a feeling it may be safer to break these function out into actual functions
// in order to avoid accidental loss of precision. For example, say you call // in order to avoid accidental loss of precision. For example, say you call

View file

@ -632,7 +632,18 @@ void ChopWindingInPlaceAccu(winding_accu_t **inout, vec3_t normal, vec_t dist, v
// want the resolution of vec_accu_t to have a large resolution around the epsilon. // want the resolution of vec_accu_t to have a large resolution around the epsilon.
// Some of that leftover resolution even goes away after we scale to points far away. // Some of that leftover resolution even goes away after we scale to points far away.
static const vec_accu_t smallestEpsilonAllowed = ((vec_accu_t) VEC_SMALLEST_EPSILON) * 0.5; // Here is a further discussion regarding the choice of smallestEpsilonAllowed.
// In the 32 float world (we can assume vec_t is that), the "epsilon around 1.0" is
// 0.00000011921. In the 64 bit float world (we can assume vec_accu_t is that), the
// "epsilon around 1.0" is 0.00000000000000022204. (By the way these two epsilons
// are defined as VEC_SMALLEST_EPSILON_AROUND_ONE VEC_ACCU_SMALLEST_EPSILON_AROUND_ONE
// respectively.) If you divide the first by the second, you get approximately
// 536,885,246. Dividing that number by 200,000 (a typical base winding coordinate)
// gives 2684. So in other words, if our smallestEpsilonAllowed was chosen as exactly
// VEC_SMALLEST_EPSILON_AROUND_ONE, you would be guaranteed at least 2000 "ticks" in
// 64-bit land inside of the epsilon for all numbers we're dealing with.
static const vec_accu_t smallestEpsilonAllowed = ((vec_accu_t) VEC_SMALLEST_EPSILON_AROUND_ONE) * 0.5;
if (crudeEpsilon < smallestEpsilonAllowed) fineEpsilon = smallestEpsilonAllowed; if (crudeEpsilon < smallestEpsilonAllowed) fineEpsilon = smallestEpsilonAllowed;
else fineEpsilon = (vec_accu_t) crudeEpsilon; else fineEpsilon = (vec_accu_t) crudeEpsilon;