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engine_collision_box.c
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engine_collision_box.c
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// Copyright 2016 Svetoslav Kolev
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
#include <string.h>
#include <mujoco/mjmacro.h>
#include "engine/engine_collision_primitive.h"
#include "engine/engine_util_blas.h"
// hard-clamp vector to range [-limit(i), +limit(i)]
static void mju_clampVec(mjtNum* vec, const mjtNum* limit, int n)
{
int i;
// loop over active limits
for (i = 0; i < n; i++) {
if (limit[i] > 0) {
if (vec[i] < -limit[i])
vec[i] = -limit[i];
else if (vec[i] > limit[i])
vec[i] = limit[i];
}
}
}
// raw sphere : box
int mjraw_SphereBox(mjContact* con, mjtNum margin,
const mjtNum* pos1, const mjtNum* mat1, const mjtNum* size1,
const mjtNum* pos2, const mjtNum* mat2, const mjtNum* size2)
{
int i, k;
mjtNum tmp[3], center[3], clamped[3], deepest[3], nearest[3];
mjtNum pos[3];
mjtNum dist, closest;
mju_sub3(tmp, pos1, pos2);
mju_mulMatTVec3(center, mat2, tmp);
mju_copy(clamped, center, 3);
mju_clampVec(clamped, size2, 3);
mju_copy(deepest, center, 3);
mju_sub3(tmp, clamped, center);
dist = mju_normalize3(tmp);
if (dist - size1[0] > margin)
return 0;
// sphere center inside box
if (dist <= mjMINVAL) {
closest = (size2[0] + size2[1] + size2[2]) * 2;
for (i = 0; i < 6; i++)
if (closest > mju_abs((i % 2 ? 1 : -1)*size2[i / 2] - center[i / 2]))
{
closest = mju_abs((i % 2 ? 1 : -1) * size2[i / 2] - center[i / 2]);
k = i;
}
mju_zero3(nearest);
nearest[k / 2] = (k % 2 ? -1 : 1);
mju_copy3(pos, center);
mju_addToScl3(pos, nearest, (size1[0] - closest) / 2);
mju_mulMatVec3(con[0].frame, mat2, nearest);
} else {
mju_addToScl3(deepest, tmp, size1[0]);
mju_zero3(pos);
mju_addToScl3(pos, clamped, 0.5);
mju_addToScl3(pos, deepest, 0.5);
mju_mulMatVec3(con[0].frame, mat2, tmp);
}
mju_mulMatVec3(tmp, mat2, pos);
mju_add3(con[0].pos, tmp, pos2);
con[0].dist = dist - size1[0];
mju_zero3(con[0].frame + 3);
return 1;
}
// sphere : box
int mjc_SphereBox(const mjModel* m, const mjData* d, mjContact* con,
int g1, int g2, mjtNum margin)
{
mjGETINFO;
return mjraw_SphereBox(con, margin, pos1, mat1, size1, pos2, mat2, size2);
}
/* GENERAL THEORY OF OPERATION
the following code is mostly for finding (line segment)/(box) collision
after which box-sphere is called
First the closest point to the box is found.
Then a "sensible" second point is found if the angle
between the segment and the box is low enough < 45
In the comments that follow, capsule just means the capsule's line segment
It might be hard to understand all comments but you would need
a picture to see what is happening at each line of the code
*/
// raw capsule : box
int mjraw_CapsuleBox(mjContact* con, mjtNum margin,
const mjtNum* pos1, const mjtNum* mat1, const mjtNum* size1,
const mjtNum* pos2, const mjtNum* mat2, const mjtNum* size2) {
mjtNum tmp1[3], tmp2[3], tmp3[3], halfaxis[3], axis[3], dif[3];
mjtNum pos[3]; // position of capsule in box-local frame
mjtNum halflength; // half of capsule's length
mjtNum bestdist; // closest contact point distance
mjtNum bestdistmax; // init value for bestdist
mjtNum bestsegmentpos; // between -1 and 1 : which point on the segment is closest to the box
mjtNum secondpos; // distance of 2nd contact position on capsule segment from the first
mjtNum dist;
mjtNum bestboxpos; // closest contact point, position on the box's edge
mjtNum mul, e1, e2, dp, de;
// mjtNum penetration;
mjtNum ma, mb, mc, u, v, det, x1, x2, idet; // linelinedist temps
int s1, s2; // hold linelinedist info
int i, j, c1, c2; // temporary variables
int cltype = -4; // closest type
int clface; // closest face
int clcorner = 0; // closest corner (0..7 in binary)
int cledge; // closest edge axis
int axisdir; // direction of capsule axis in relation to the box
int n; // number of contacts
int ax1, ax2, ax; // axis temporaries
halflength = size1[1];
secondpos = -4; // initialize to no 2nd contact (valid values are between -1 and 1)
mju_sub3(tmp1, pos1, pos2); // bring capsule to box-local frame (center's box is at (0,0,0))
mju_mulMatTVec3(pos, mat2, tmp1); // and axis parralel to world
tmp1[0] = mat1[2]; // capsule's axis
tmp1[1] = mat1[5];
tmp1[2] = mat1[8];
mju_mulMatTVec3(axis, mat2, tmp1); // do the same for the capsule axis
mju_scl3(halfaxis, axis, halflength); // scale to get actual capsule half-axis
axisdir = 0;
if (halfaxis[0] > 0)
axisdir += 1;
if (halfaxis[1] > 0)
axisdir += 2;
if (halfaxis[2] > 0)
axisdir += 4;
// under this notion "axisdir" and "7-axisdir" point in opposite directions,
// essentially the same for a capsule
bestdistmax = margin + 2 * (size1[0] + halflength + size2[0] + size2[1] +
size2[2]); // initialize bestdist
bestdist = bestdistmax;
bestsegmentpos = 0;
mju_zero3(tmp2);
// test to see if maybe the a face of the box is closest to the capsule
for (i = -1; i <= 1; i += 2) {
mju_copy3(tmp1, pos);
mju_addToScl3(tmp1, halfaxis, i);
mju_copy3(tmp2, tmp1);
for (c1 = 0, j = 0, c2 = -1; j < 3; j++) {
if (tmp1[j] < -size2[j]) {
c1++;
c2 = j;
tmp1[j] = -size2[j];
} else if (tmp1[j] > size2[j]) {
c1++;
c2 = j;
tmp1[j] = size2[j];
}
}
if (c1 > 1)
continue;
mju_subFrom3(tmp1, tmp2);
dist = mju_dot3(tmp1, tmp1);
if (dist < bestdist) {
bestdist = dist;
bestsegmentpos = i;
cltype = -2 + i;
clface = c2;
}
}
mju_zero3(tmp2);
for (j = 0; j < 3; j++) {
for (i = 0; i < 8; i++) {
if ((i & (1 << j)) == 0) {
// trick to get a corner
tmp3[0] = ((i & 1) ? 1 : -1) * size2[0];
tmp3[1] = ((i & 2) ? 1 : -1) * size2[1];
tmp3[2] = ((i & 4) ? 1 : -1) * size2[2];
tmp3[j] = 0;
// tmp3 is the starting point on the box
// tmp2 is the direction along the "j"-th axis
// pos is the capsule's center
// halfaxis is the capsule direction
// find closest point between capsule and the edge
mju_sub3(dif, tmp3, pos);
ma = size2[j] * size2[j];
mb = -size2[j] * halfaxis[j];
mc = size1[1] * size1[1];
u = -size2[j] * dif[j];
v = mju_dot3(halfaxis, dif);
det = ma * mc - mb * mb;
if (mju_abs(det) < mjMINVAL)
continue;
idet = 1 / det;
// sX : X=1 means middle of segment. X=0 or 2 one or the other end
x1 = (mc * u - mb * v) * idet;
x2 = (ma * v - mb * u) * idet;
s1 = s2 = 1;
if (x1 > 1) {
x1 = 1;
s1 = 2;
x2 = (v - mb) * (1 / mc);
} else if (x1 < -1) {
x1 = -1;
s1 = 0;
x2 = (v + mb) * (1 / mc);
}
if (x2 > 1) {
x2 = 1;
s2 = 2;
x1 = (u - mb) * (1 / ma);
if (x1 > 1)
x1 = 1, s1 = 2;
else if (x1 < -1)
x1 = -1, s1 = 0;
} else if (x2 < -1) {
x2 = -1;
s2 = 0;
x1 = (u + mb) * (1 / ma);
if (x1 > 1)
x1 = 1, s1 = 2;
else if (x1 < -1)
x1 = -1, s1 = 0;
}
mju_sub3(dif, tmp3, pos);
mju_addToScl3(dif, halfaxis, -x2);
dif[j] += size2[j] * x1;
tmp1[2] = mju_dot3(dif, dif);
c1 = s1 * 3 + s2;
// the -MINVAL might not be necessary. Fixes numerical problem when axis is numerically
// parallel to the box
if (tmp1[2] < bestdist - mjMINVAL) {
bestdist = tmp1[2];
bestsegmentpos = x2;
bestboxpos = x1;
// c1<6 means that closest point on the box is at the lower end
// or in the middle of the edge
c2 = c1 / 6;
clcorner = i + (1 << j) * c2; // which corner is the closest
cledge = j; // which axis
cltype = c1; // save clamped info
}
}
}
}
// penetration = -bestdist;
for (j = 0; j < 3; j++) {
if (j == 2) {
typedef union {
struct {
mjtNum x, y;
};
mjtNum c[2];
} d2;
d2 p, s, dd /*, c, tmp1*/;
mjtNum uu, vv, w, ee1, best /* ,e2 */, l /* , e3, e4 */;
bestdist = bestdistmax;
p.x = pos[0];
p.y = pos[1];
dd.x = halfaxis[0];
dd.y = halfaxis[1];
s.x = size2[0];
s.y = size2[1];
l = sqrt(dd.x * dd.x + dd.y * dd.y);
uu = dd.x * s.y;
vv = dd.y * s.x;
w = dd.x * p.y - dd.y * p.x;
best = -1;
ee1 = +uu - vv;
if ((ee1 < 0) == (w < 0)) {
if (best < mju_abs(ee1)) {
best = mju_abs(ee1);
c1 = 0;
}
}
ee1 = -uu - vv;
if ((ee1 < 0) == (w < 0)) {
if (best < mju_abs(ee1)) {
best = mju_abs(ee1);
c1 = 1;
}
}
ee1 = +uu + vv;
if ((ee1 < 0) == (w < 0)) {
if (best < mju_abs(ee1)) {
best = mju_abs(ee1);
c1 = 2;
}
}
ee1 = -uu + vv;
if ((ee1 < 0) == (w < 0)) {
if (best < mju_abs(ee1)) {
best = mju_abs(ee1);
c1 = 3;
}
}
// c.x = s.x * ((c1 / 2) ? -1 : 1);
// c.y = s.y * ((c1 % 2) ? -1 : 1);
ee1 = mju_abs(w) / l;
// e2 = best / l;
// printf("%g %g %g %g %g %g\n",c.x,c.y,d.x,d.y,e1,e2);
// tmp1.x = c.x - p.x;
// tmp1.y = c.y - p.y;
ee1 = dd.x * dd.x + dd.y * dd.y;
// e2 = tmp1.x * d.x + tmp1.y * d.y;
// e3 = e2 / e1;
// printf("%g %g %g %g %g %g %g \n",c.x,c.y,d.x,d.y,e1,e2,e3);
ee1 = p.x + (+s.y - p.y) / dd.y * dd.x;
// e2 = p.x + (-s.y - p.y) / d.y * d.x;
// e3 = p.y + (+s.x - p.x) / d.x * d.y;
// e4 = p.y + (-s.x - p.x) / d.x * d.y;
// printf("%g %g %g %g\n",e1,e2,e3,e4);
}
}
// goto skip; // allow only the closest contact
// cltype: -3 -1 : face is closest to the capsule
// cltype: 0..8 : edge is closest to the capsule
// cltype/3==0 means the lower corner is closest to the capsule (note that edges include corners)
// cltype/3==2 means the upper corner is closest to the capsule (note that edges include corners)
// cltype/3==1 means the middle of the edge is closest to the capsule
// cltype%3==0 means the lower corner is closest to the box (note that edges include corners)
// cltype%3==2 means the upper corner is closest to the box (note that edges include corners)
// cltype%3==1 means the middle of the capsule is closest to the box
// invalid type
if (cltype == -4)
return 0;
if (cltype >= 0 && cltype / 3 != 1) { // closest to a corner of the box
c1 = axisdir ^ clcorner;
// hack to find the relative orientation of capsule and corner
// there are 2 cases:
// 1: pointing to or away from the corner
// 2: oriented along a face or an edge
if (c1 == 0 || c1 == 7)
goto skip; // case 1: no chance of additional contact
if (c1 == 1 || c1 == 2 || c1 == 4) {
mul = 1;
de = 1 - bestsegmentpos;
dp = 1 + bestsegmentpos;
}
if (c1 == 3 || c1 == 5 || c1 == 6) {
mul = -1;
c1 = 7 - c1;
dp = 1 - bestsegmentpos;
de = 1 + bestsegmentpos;
}
// "de" and "dp" distance from first closest point on the capsule to both ends of it
// mul is a direction along the capsule's axis
if (c1 == 1)
ax = 0, ax1 = 1, ax2 = 2;
if (c1 == 2)
ax = 1, ax1 = 2, ax2 = 0;
if (c1 == 4)
ax = 2, ax1 = 0, ax2 = 1;
if (axis[ax]*axis[ax] > 0.5) { // second point along the edge of the box
secondpos = de; // initial position from the
e1 = 2 * size2[ax] / mju_abs(halfaxis[ax]);
if (e1 < secondpos) {
secondpos = e1; // we overshoot, move back to the other corner of the edge
}
secondpos *= mul;
} else { // second point along a face of the box
secondpos = dp;
// check for overshoot again
e1 = 2 * size2[ax1] / mju_abs(halfaxis[ax1]);
if (e1 < secondpos)
secondpos = e1;
e1 = 2 * size2[ax2] / mju_abs(halfaxis[ax2]);
if (e1 < secondpos)
secondpos = e1;
secondpos *= -mul;
}
} else if (cltype >= 0 && cltype / 3 == 1) { // we are on box's edge
// hacks to find the relative orientation of capsule and edge
// there are 2 cases:
// c1= 2^n: edge and capsule are oriented in a T configuaration (no more contacts
// c1!=2^n: oriented in a cross X configuration
c1 = axisdir ^ clcorner; // same trick
c1 &= 7 - (1 << cledge); // even more hacks
// printf("%d %d %d %d %lf %lf %lf\n",
// axisdir,clcorner,c1,cledge,halfaxis[0],halfaxis[1],halfaxis[2]);
if (c1 != 1 && c1 != 2 && c1 != 4)
goto skip;
if (cledge == 0)
ax1 = 1, ax2 = 2;
if (cledge == 1)
ax1 = 2, ax2 = 0;
if (cledge == 2)
ax1 = 0, ax2 = 1;
ax = cledge;
// Then it finds with which face the capsule has a lower angle and switches the axis names
if (mju_abs(axis[ax1]) > mju_abs(axis[ax2]))
ax1 = ax2;
ax2 = 3 - ax - ax1;
// keep track of the axis orientation (mul will tell us which direction along the capsule to
// find the second point) you can notice all other references to the axis "halfaxis" are with
// absolute value
if (c1 & (1 << ax2)) {
mul = 1;
secondpos = 1 - bestsegmentpos;
} else {
mul = -1;
secondpos = 1 + bestsegmentpos;
}
// now we have to find out whether we point towards the opposite side or towards one of the
// sides and also find the farthest point along the capsule that is above the box
e1 = 2 * size2[ax2] / mju_abs(halfaxis[ax2]);
if (e1 < secondpos)
secondpos = e1;
if (((axisdir & (1 << ax)) != 0) == ((c1 & (1 << ax2)) != 0)) // that is insane
e2 = 1 - bestboxpos;
else
e2 = 1 + bestboxpos;
e1 = size2[ax] * e2 / mju_abs(halfaxis[ax]);
if (e1 < secondpos)
secondpos = e1;
secondpos *= mul;
} else if (cltype < 0) {
// similarly we handle the case when one capsule's end is closest to a face of the box
// and find where is the other end pointing to and clamping to the farthest point
// of the capsule that's above the box
if (clface == -1)
goto skip; // here the closest point is inside the box, no need for a second point
if (cltype == -3)
mul = 1;
else
mul = -1;
secondpos = 2;
mju_copy3(tmp1, pos);
mju_addToScl3(tmp1, halfaxis, -mul);
for (i = 0; i < 3; i++) {
if (i != clface) {
e1 = (size2[i] - tmp1[i]) / halfaxis[i] * mul;
if (e1 > 0)
if (e1 < secondpos)
secondpos = e1;
e1 = (-size2[i] - tmp1[i]) / halfaxis[i] * mul;
if (e1 > 0)
if (e1 < secondpos)
secondpos = e1;
}
}
secondpos *= mul;
}
skip:
// create sphere in original orientation at first contact point
mju_copy3(tmp1, pos);
mju_addToScl3(tmp1, halfaxis, bestsegmentpos);
mju_mulMatVec3(tmp2, mat2, tmp1);
mju_addTo3(tmp2, pos2);
// collide with
n = mjraw_SphereBox(con, margin, tmp2, mat1, size1, pos2, mat2, size2);
if (secondpos > -3) { // secondpos was modified
mju_copy3(tmp1, pos);
mju_addToScl3(tmp1, halfaxis, secondpos + bestsegmentpos); // note the summation
mju_mulMatVec3(tmp2, mat2, tmp1);
mju_addTo3(tmp2, pos2);
n += mjraw_SphereBox(con + n, margin, tmp2, mat1, size1, pos2, mat2, size2);
}
return n;
}
// capsule : box
int mjc_CapsuleBox(const mjModel* m, const mjData* d, mjContact* con,
int g1, int g2, mjtNum margin)
{
mjGETINFO
return mjraw_CapsuleBox(con, margin, pos1, mat1, size1, pos2, mat2, size2);
}
// box : box
int mjc_BoxBox(const mjModel* M, const mjData* D, mjContact* con, int g1, int g2, mjtNum margin)
{
const mjtNum* pos1 = D->geom_xpos + 3 * g1;
const mjtNum* mat1 = D->geom_xmat + 9 * g1;
const mjtNum* size1 = M->geom_size + 3 * g1;
const mjtNum* pos2 = D->geom_xpos + 3 * g2;
const mjtNum* mat2 = D->geom_xmat + 9 * g2;
const mjtNum* size2 = M->geom_size + 3 * g2;
mjtNum pos12[3], pos21[3], rot[9], rott[9], rotabs[9], rottabs[9], tmp1[3], tmp2[3], plen1[3],
plen2[3];
mjtNum rotmore[9], p[3], r[9], s[3], ss[3], lp[3], rt[9], points[mjMAXCONPAIR][3],
depth[mjMAXCONPAIR], pts[6][3], ppts2[4][2], pu[4][3], axi[3][3];
mjtNum linesu[4][6], lines[4][6], clnorm[3], rnorm[3];
mjtNum penetration, c1, c2, c3, a, b, c, d, lx, ly, hz, l, x, y, u, v, llx, lly, innorm, margin2;
int i0, i1, i2;
mjtNum f0, f1, f2;
int i, j, q, code, q1, q2, clcorner, n, m, k;
int cle1, cle2, in, ax1, ax2, pax1, pax2, clface, nl, nf;
n = 0;
code = -1;
margin2 = margin * margin;
mju_sub3(tmp1, pos2, pos1);
mju_mulMatTVec3(pos21, mat1, tmp1);
mju_sub3(tmp1, pos1, pos2);
mju_mulMatTVec3(pos12, mat2, tmp1);
mju_mulMatTMat3(rot, mat1, mat2);
mju_transpose(rott, rot, 3, 3);
for (i = 0; i < 9; i++)
rotabs[i] = mju_abs(rot[i]);
for (i = 0; i < 9; i++)
rottabs[i] = mju_abs(rott[i]);
mju_mulMatVec3(plen2, rotabs, size2);
mju_mulMatTVec3(plen1, rotabs, size1);
for (i = 0, penetration = margin; i < 3; i++)
penetration += size1[i] * 3 + size2[i] * 3;
for (i = 0; i < 3; i++) {
c1 = -mju_abs(pos21[i]) + size1[i] + plen2[i];
c2 = -mju_abs(pos12[i]) + size2[i] + plen1[i];
if (c1 < -margin || c2 < -margin)
return 0;
if (c1 < penetration) {
penetration = c1;
code = i + 3 * (pos21[i] < 0) + 0;
}
if (c2 < penetration) {
penetration = c2;
code = i + 3 * (pos12[i] < 0) + 6;
}
// printf("%24.16e %24.16e %d %24.16e %d \n",c1,c2,i,penetration,code);
}
for (i = 0; i < 3; i++) {
for (j = 0; j < 3; j++) {
mju_zero3(tmp2);
if (i == 0) {
tmp2[1] = -rott[3 * j + 2];
tmp2[2] = +rott[3 * j + 1];
} else if (i == 1) {
tmp2[0] = +rott[3 * j + 2];
tmp2[2] = -rott[3 * j + 0];
} else if (i == 2) {
tmp2[0] = -rott[3 * j + 1];
tmp2[1] = +rott[3 * j + 0];
}
c1 = mju_normalize3(tmp2);
if (c1 < mjMINVAL)
continue;
c2 = mju_dot3(pos21, tmp2);
c3 = 0;
for (k = 0; k < 3; k++)
if (k != i)
c3 += size1[k] * mju_abs(tmp2[k]);
for (k = 0; k < 3; k++)
if (k != j)
c3 += size2[k] * rotabs[3 * i + 3 - k - j] / c1;
c3 -= mju_abs(c2);
if (c3 < -margin)
return 0;
if (c3 < penetration * (1 - 1e-12))
{
penetration = c3;
for (k = cle1 = 0; k < 3; k++)
if (k != i)
if ((tmp2[k] > 0) ^ (c2 < 0))
cle1 += 1 << k;
for (k = cle2 = 0; k < 3; k++)
if (k != j)
if ((rot[3 * i + 3 - k - j] > 0) ^ (c2 < 0) ^ ((k - j + 3) % 3 == 1))
cle2 += 1 << k;
code = 12 + i * 3 + j;
mju_copy3(clnorm, tmp2);
in = c2 < 0;
}
// printf("%24.16e %d %24.16e %d\n",c3,12+i*3+j,penetration,code);
}
}
// return 0;
// printf("%d\n",code);
if (code == -1)
return 0; // shouldn't happen
if (code >= 12)
goto edgeedge;
q1 = code % 6;
q2 = code / 6;
// printf("%d %d\n",q1,q2);
mju_zero(rotmore, 9);
if (q1 == 0)
rotmore[2] = -1, rotmore[4] = +1, rotmore[6] = +1;
else if (q1 == 1)
rotmore[0] = +1, rotmore[5] = -1, rotmore[7] = +1;
else if (q1 == 2)
rotmore[0] = +1, rotmore[4] = +1, rotmore[8] = +1;
else if (q1 == 3)
rotmore[2] = +1, rotmore[4] = +1, rotmore[6] = -1;
else if (q1 == 4)
rotmore[0] = +1, rotmore[5] = +1, rotmore[7] = -1;
else if (q1 == 5)
rotmore[0] = -1, rotmore[4] = +1, rotmore[8] = -1;
i0 = 0;
i1 = 1;
i2 = 2;
f0 = f1 = f2 = 1;
if (q1 == 0) {
i0 = 2;
f0 = -1;
i2 = 0;
} else if (q1 == 1) {
i1 = 2;
f1 = -1;
i2 = 1;
} else if (q1 == 2) {
} else if (q1 == 3) {
i0 = 2;
i2 = 0;
f2 = -1;
} else if (q1 == 4) {
i1 = 2;
i2 = 1;
f2 = -1;
} else if (q1 == 5) {
f0 = -1;
f2 = -1;
}
#define rotaxis(vecres, vecin) \
{ \
vecres[0]=vecin[i0]*f0; \
vecres[1]=vecin[i1]*f1; \
vecres[2]=vecin[i2]*f2; \
}
#define rotmatx(matres, matin) \
{ \
mju_scl3(matres+0, matin+i0*3, f0); \
mju_scl3(matres+3, matin+i1*3, f1); \
mju_scl3(matres+6, matin+i2*3, f2); \
}
if (q2) {
mju_mulMatMatT3(r, rotmore, rot);
// mju_mulMatVec3(p,rotmore,pos12);
// mju_mulMatVec3(tmp1,rotmore,size2);
rotaxis(p, pos12);
rotaxis(tmp1, size2);
mju_copy3(s, size1);
} else {
// mju_mulMatMat(r,rotmore,rot,3,3,3);
rotmatx(r, rot);
// mju_mulMatVec3(p,rotmore,pos21);
// mju_mulMatVec3(tmp1,rotmore,size1);
rotaxis(p, pos21);
rotaxis(tmp1, size1);
mju_copy3(s, size2);
}
mju_transpose(rt, r, 3, 3);
for (i = 0; i < 3; i++)
ss[i] = mju_abs(tmp1[i]);
lx = ss[0];
ly = ss[1];
hz = ss[2];
p[2] -= hz;
mju_copy3(lp, p);
for (clcorner = 0, i = 0; i < 3; i++)
if (r[6 + i] < 0)
clcorner += 1 << i;
mju_addToScl3(lp, rt + 0, s[0] * ((clcorner & 1) ? 1 : -1));
mju_addToScl3(lp, rt + 3, s[1] * ((clcorner & 2) ? 1 : -1));
mju_addToScl3(lp, rt + 6, s[2] * ((clcorner & 4) ? 1 : -1));
m = k = 0;
mju_copy3(pts[m++], lp);
for (i = 0; i < 3; i++)
if (mju_abs(r[6 + i]) < 0.5)
mju_scl3(pts[m++], rt + 3 * i, s[i] * ((clcorner & (1 << i)) ? -2 : 2));
mju_add3(pts[3], pts[0], pts[1]);
mju_add3(pts[4], pts[0], pts[2]);
mju_add3(pts[5], pts[3], pts[2]);
if (m > 1)
{
mju_copy3(lines[k] + 0, pts[0]);
mju_copy3(lines[k++] + 3, pts[1]);
}
if (m > 2)
{
mju_copy3(lines[k] + 0, pts[0]);
mju_copy3(lines[k++] + 3, pts[2]);
mju_copy3(lines[k] + 0, pts[3]);
mju_copy3(lines[k++] + 3, pts[2]);
mju_copy3(lines[k] + 0, pts[4]);
mju_copy3(lines[k++] + 3, pts[1]);
}
for (i = 0; i < k; i++) {
for (q = 0; q < 2; q++) {
a = lines[i][0 + q];
b = lines[i][3 + q];
c = lines[i][1 - q];
d = lines[i][4 - q];
if (mju_abs(b) > mjMINVAL) {
for (j = -1; j <= 1; j += 2) {
l = ss[q] * j;
c1 = (l - a) * (1 / b);
if (c1 < 0 || c1 > 1)
continue;
c2 = c + d * c1;
if (mju_abs(c2) > ss[1 - q])
continue;
mju_copy3(points[n], lines[i]);
mju_addToScl3(points[n++], lines[i] + 3, c1);
}
}
}
}
a = pts[1][0];
b = pts[2][0];
c = pts[1][1];
d = pts[2][1];
c1 = a * d - b * c;
if (m > 2) {
for (i = 0; i < 4; i++) {
llx = i / 2 ? lx : -lx;
lly = i % 2 ? ly : -ly;
x = llx - pts[0][0];
y = lly - pts[0][1];
u = (x * d - y * b) * (1 / c1);
v = (y * a - x * c) * (1 / c1);
if (u <= 0 || v <= 0 || u >= 1 || v >= 1)
continue;
points[n][0] = llx;
points[n][1] = lly;
points[n][2] = (pts[0][2] + u * pts[1][2] + v * pts[2][2]);
n++;
}
}
for (i = 0; i < (1 << (m - 1)); i++) {
mju_copy3(tmp1, pts[i == 0 ? 0 : i + 2]);
if (i)
if (tmp1[0] <= -lx || tmp1[0] >= lx)
continue;
if (i)
if (tmp1[1] <= -ly || tmp1[1] >= ly)
continue;
mju_copy3(points[n++], tmp1);
}
m = n;
n = 0;
for (i = 0; i < m; i++)
{
if (points[i][2] > margin)
continue;
mju_copy3(points[n], points[i]);
depth[n] = points[n][2];
points[n][2] *= 0.5;
n++;
}
mju_mulMatMatT3(r, q2 ? mat2 : mat1, rotmore);
mju_copy3(p, q2 ? pos2 : pos1);
tmp2[0] = (q2 ? -1 : 1) * r[2];
tmp2[1] = (q2 ? -1 : 1) * r[5];
tmp2[2] = (q2 ? -1 : 1) * r[8];
mju_copy3(con[0].frame, tmp2);
mju_zero3(con[0].frame + 3);
for (i = 0; i < n; i++)
{
con[i].dist = points[i][2];
points[i][2] += hz;
mju_mulMatVec3(tmp2, r, points[i]);
mju_add3(con[i].pos, tmp2, p);
if (i)
mju_copy(con[i].frame, con[0].frame, 6);
}
// printf("Path1: %d\n",n);
return n;
edgeedge:
code -= 12;
q1 = code / 3;
q2 = code % 3;
if (q2 == 0)
ax1 = 1, ax2 = 2;
if (q2 == 1)