// Copyright 2022 DeepMind Technologies Limited // // 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 #include #include #include #include #include #include #include #include "sdf.h" #include "nut.h" namespace mujoco::plugin::sdf { namespace { static mjtNum distance(const mjtNum p[3], const mjtNum attributes[1]) { // see https://www.shadertoy.com/view/XtffzX mjtNum screw = 12; mjtNum radius2 = mju_sqrt(p[0]*p[0]+p[1]*p[1]) - attributes[0]; mjtNum sqrt12 = mju_sqrt(2.)/2.; // a triangle wave spun around Oy, offset by the angle between x and z mjtNum azimuth = mju_atan2(p[1], p[0]); mjtNum triangle = abs(Fract(p[2] * screw - azimuth / mjPI / 2.) - .5); mjtNum thread2 = (radius2 - triangle / screw) * sqrt12; // clip the top mjtNum cone2 = (p[2] - radius2) * sqrt12; // the hole is the same thing, but substracted from the whole thing mjtNum hole = Subtraction(thread2, cone2 + .5 * sqrt12); hole = Union(hole, -cone2 - .05 * sqrt12); // create the hexagonal geometry for the head mjtNum point2D[2] = {p[0], p[1]}; mjtNum res[2]; mjtNum k = 6. / mjPI / 2.; mjtNum angle = -floor((mju_atan2(point2D[1], point2D[0])) * k + .5) / k; mjtNum s[2] = {mju_sin(angle), mju_sin(angle + mjPI * .5)}; mjtNum mat[4] = {s[1], -s[0], s[0], s[1]}; mju_mulMatVec(res, mat, point2D, 2, 2); mjtNum point3D[3] = {res[0], res[1], p[2]}; mjtNum head = point3D[0] - .5; // the top is also rounded down with a cone head = Intersection(head, abs(point3D[2] + .25) - .25); head = Intersection(head, (point3D[2] + radius2 - .22) * sqrt12); return Subtraction(head, hole); } } // namespace // factory function std::optional Nut::Create( const mjModel* m, mjData* d, int instance) { if (CheckAttr("radius", m, instance)) { return Nut(m, d, instance); } else { mju_warning("Invalid parameter specification in Nut plugin"); return std::nullopt; } } // plugin constructor Nut::Nut(const mjModel* m, mjData* d, int instance) { SdfDefault defattribute; for (int i=0; i < NutAttribute::nattribute; i++) { attribute[i] = defattribute.GetDefault( NutAttribute::names[i], mj_getPluginConfig(m, instance, NutAttribute::names[i])); } } // plugin computation void Nut::Compute(const mjModel* m, mjData* d, int instance) { visualizer_.Next(); } // plugin reset void Nut::Reset() { visualizer_.Reset(); } // plugin visualization void Nut::Visualize(const mjModel* m, mjData* d, const mjvOption* opt, mjvScene* scn, int instance) { visualizer_.Visualize(m, d, opt, scn, instance); } // sdf mjtNum Nut::Distance(const mjtNum point[3]) const { return distance(point, attribute); } // gradient of sdf void Nut::Gradient(mjtNum grad[3], const mjtNum point[3]) const { mjtNum eps = 1e-8; mjtNum dist0 = distance(point, attribute); mjtNum pointX[3] = {point[0]+eps, point[1], point[2]}; mjtNum distX = distance(pointX, attribute); mjtNum pointY[3] = {point[0], point[1]+eps, point[2]}; mjtNum distY = distance(pointY, attribute); mjtNum pointZ[3] = {point[0], point[1], point[2]+eps}; mjtNum distZ = distance(pointZ, attribute); grad[0] = (distX - dist0) / eps; grad[1] = (distY - dist0) / eps; grad[2] = (distZ - dist0) / eps; } // plugin registration void Nut::RegisterPlugin() { mjpPlugin plugin; mjp_defaultPlugin(&plugin); plugin.name = "mujoco.sdf.nut"; plugin.capabilityflags |= mjPLUGIN_SDF; plugin.nattribute = NutAttribute::nattribute; plugin.attributes = NutAttribute::names; plugin.nstate = +[](const mjModel* m, int instance) { return 0; }; plugin.init = +[](const mjModel* m, mjData* d, int instance) { auto sdf_or_null = Nut::Create(m, d, instance); if (!sdf_or_null.has_value()) { return -1; } d->plugin_data[instance] = reinterpret_cast( new Nut(std::move(*sdf_or_null))); return 0; }; plugin.destroy = +[](mjData* d, int instance) { delete reinterpret_cast(d->plugin_data[instance]); d->plugin_data[instance] = 0; }; plugin.reset = +[](const mjModel* m, mjtNum* plugin_state, void* plugin_data, int instance) { auto sdf = reinterpret_cast(plugin_data); sdf->Reset(); }; plugin.visualize = +[](const mjModel* m, mjData* d, const mjvOption* opt, mjvScene* scn, int instance) { auto* sdf = reinterpret_cast(d->plugin_data[instance]); sdf->Visualize(m, d, opt, scn, instance); }; plugin.compute = +[](const mjModel* m, mjData* d, int instance, int capability_bit) { auto* sdf = reinterpret_cast(d->plugin_data[instance]); sdf->Compute(m, d, instance); }; plugin.sdf_distance = +[](const mjtNum point[3], const mjData* d, int instance) { auto* sdf = reinterpret_cast(d->plugin_data[instance]); return sdf->Distance(point); }; plugin.sdf_gradient = +[](mjtNum gradient[3], const mjtNum point[3], const mjData* d, int instance) { auto* sdf = reinterpret_cast(d->plugin_data[instance]); sdf->visualizer_.AddPoint(point); sdf->Gradient(gradient, point); }; plugin.sdf_staticdistance = +[](const mjtNum point[3], const mjtNum* attributes) { return distance(point, attributes); }; plugin.sdf_aabb = +[](mjtNum aabb[6], const mjtNum* attributes) { aabb[0] = aabb[1] = aabb[2] = 0; aabb[3] = aabb[4] = .6; aabb[5] = 1; }; plugin.sdf_attribute = +[](mjtNum attribute[], const char* name[], const char* value[]) { SdfDefault defattribute; defattribute.GetDefaults(attribute, name, value); }; mjp_registerPlugin(&plugin); } } // namespace mujoco::plugin::sdf