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mujoco

	// Copyright 2021 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 "user/user_model.h"

	#include <algorithm>
	#include <atomic>
	#include <cmath>
	#include <array>
	#include <csetjmp>
	#include <cstdint>
	#include <cstdio>
	#include <cstdlib>
	#include <cstring>
	#include <exception>
	#include <filesystem> // NOLINT(build/c++17)
	#include <functional>
	#include <mutex>
	#include <string>
	#include <string_view>
	#include <thread>
	#include <unordered_map>
	#include <utility>
	#include <vector>

	#include <mujoco/mjdata.h>
	#include <mujoco/mjmacro.h>
	#include <mujoco/mjmodel.h>
	#include <mujoco/mjspec.h>
	#include <mujoco/mjtnum.h>
	#include <mujoco/mjplugin.h>
	#include "cc/array_safety.h"
	#include "engine/engine_forward.h"
	#include "engine/engine_io.h"
	#include "engine/engine_name.h"
	#include "engine/engine_plugin.h"
	#include "engine/engine_setconst.h"
	#include "engine/engine_support.h"
	#include "engine/engine_util_errmem.h"
	#include "engine/engine_util_misc.h"
	#include "user/user_api.h"
	#include "user/user_objects.h"
	#include "user/user_util.h"

	namespace {
	namespace mju = ::mujoco::util;
	using std::string;
	using std::vector;
	constexpr int kMaxCompilerThreads = 16;



	//---------------------------------- LOCAL UTILITY FUNCTIONS ---------------------------------------

	constexpr double kFrameEps = 1e-6; // difference below which frames are considered equal

	// return true if two 3-vectors are element-wise less than kFrameEps apart
	template <typename T>
	bool IsSameVec(const T pos1[3], const T pos2[3]) {
	static_assert(std::is_floating_point_v<T>);
	return std::abs(pos1[0] - pos2[0]) < kFrameEps &&
	std::abs(pos1[1] - pos2[1]) < kFrameEps &&
	std::abs(pos1[2] - pos2[2]) < kFrameEps;
	}

	// return true if two quaternions are element-wise less than kFrameEps apart, including double-cover
	template <typename T>
	bool IsSameQuat(const T quat1[4], const T quat2[4]) {
	static_assert(std::is_floating_point_v<T>);
	bool same_quat_minus = std::abs(quat1[0] - quat2[0]) < kFrameEps &&
	std::abs(quat1[1] - quat2[1]) < kFrameEps &&
	std::abs(quat1[2] - quat2[2]) < kFrameEps &&
	std::abs(quat1[3] - quat2[3]) < kFrameEps;

	bool same_quat_plus = std::abs(quat1[0] + quat2[0]) < kFrameEps &&
	std::abs(quat1[1] + quat2[1]) < kFrameEps &&
	std::abs(quat1[2] + quat2[2]) < kFrameEps &&
	std::abs(quat1[3] + quat2[3]) < kFrameEps;

	return same_quat_minus \|\| same_quat_plus;
	}


	// compare two poses
	template <typename T>
	bool IsSamePose(const T pos1[3], const T pos2[3], const T quat1[4], const T quat2[4]) {
	// check position if given
	if (pos1 && pos2 && !IsSameVec(pos1, pos2)) {
	return false;
	}

	// check orientation if given
	if (quat1 && quat2 && !IsSameQuat(quat1, quat2)) {
	return false;
	}

	return true;
	}

	// detect null pose
	template <typename T>
	bool IsNullPose(const T pos[3], const T quat[4]) {
	T zero[3] = {0, 0, 0};
	T qunit[4] = {1, 0, 0, 0};
	return IsSamePose(pos, zero, quat, qunit);
	}

	} // namespace

	//---------------------------------- CONSTRUCTOR AND DESTRUCTOR ------------------------------------

	// constructor
	mjCModel::mjCModel() {
	mjs_defaultSpec(&spec);
	elemtype = mjOBJ_MODEL;
	spec_comment_.clear();
	spec_modelfiledir_.clear();
	spec_meshdir_.clear();
	spec_texturedir_.clear();
	spec_modelname_ = "MuJoCo Model";

	//------------------------ auto-computed statistics
	#ifndef MEMORY_SANITIZER
	// initializing as best practice, but want MSAN to catch uninitialized use
	meaninertia_auto = 0;
	meanmass_auto = 0;
	meansize_auto = 0;
	extent_auto = 0;
	center_auto[0] = center_auto[1] = center_auto[2] = 0;
	#endif

	deepcopy_ = false;
	nplugin = 0;
	Clear();

	//------------------------ master default set
	defaults_.push_back(new mjCDef(this));
	defaults_.back()->name = "main";

	// point to model from spec
	PointToLocal();

	// world body
	mjCBody* world = new mjCBody(this);
	mjuu_zerovec(world->pos, 3);
	mjuu_setvec(world->quat, 1, 0, 0, 0);
	world->mass = 0;
	mjuu_zerovec(world->inertia, 3);
	world->id = 0;
	world->parent = nullptr;
	world->weldid = 0;
	world->name = "world";
	world->classname = "main";
	def_map["main"] = Default();
	bodies_.push_back(world);

	// create mjCBase lists from children lists
	CreateObjectLists();

	// set the signature
	spec.element->signature = 0;
	}



	mjCModel::mjCModel(const mjCModel& other) {
	CreateObjectLists();
	*this = other;
	}



	mjCModel& mjCModel::operator=(const mjCModel& other) {
	deepcopy_ = true;
	if (this != &other) {
	this->spec = other.spec;
	static_cast<mjCModel_>(this) = static_cast<const mjCModel_&>(other);
	static_cast<mjSpec>(this) = static_cast<const mjSpec&>(other);

	// copy attached specs first so that we can resolve references to them
	for (const auto* s : other.specs_) {
	specs_.push_back(mj_copySpec(s));
	compiler2spec_[&s->compiler] = specs_.back();
	}

	// the world copy constructor takes care of copying the tree
	mjCBody* world = new mjCBody(*other.bodies_[0], this);
	bodies_.push_back(world);

	// update tree lists
	ResetTreeLists();
	MakeTreeLists();

	// add everything else
	*this += other;

	// add keyframes
	CopyList(keys_, other.keys_);

	// create new default tree
	mjCDef* subtree = new mjCDef(*other.defaults_[0]);
	this += subtree;

	// copy name maps
	for (int i=0; i < mjNOBJECT; i++) {
	ids[i] = other.ids[i];
	}

	// update signature after we updated everything
	spec.element->signature = Signature();
	}
	deepcopy_ = other.deepcopy_;
	return *this;
	}



	// copy vector of elements from another model to this model
	template <class T>
	void mjCModel::CopyList(std::vector<T*>& dest,
	const std::vector<T*>& source) {
	// loop over the elements from the other model
	int nsource = (int)source.size();
	for (int i = 0; i < nsource; i++) {
	T* candidate = deepcopy_ ? new T(*source[i]) : source[i];
	try {
	// try to find the referenced object in this model
	mjCModel* source_model = source[i]->model;
	candidate->model = this;
	candidate->NameSpace(source_model);
	candidate->CopyFromSpec();
	candidate->ResolveReferences(this);
	} catch (mjCError err) {
	// if not present, skip the element
	// TODO: do not skip elements that contain user errors
	if (deepcopy_) {
	candidate->model = nullptr;
	delete candidate;
	}
	continue;
	}
	// copy the element from the other model to this model
	if (deepcopy_) {
	source[i]->ForgetKeyframes();
	} else {
	candidate->AddRef();
	}
	mjSpec* origin = FindSpec(source[i]->compiler);
	dest.push_back(candidate);
	dest.back()->model = this;
	dest.back()->compiler = origin ? &origin->compiler : &spec.compiler;
	dest.back()->id = -1;
	dest.back()->CopyPlugin();
	}
	if (!dest.empty()) {
	ProcessList_(ids, dest, dest[0]->elemtype);
	}
	}



	template <class T>
	static void resetlist(std::vector<T*>& list) {
	for (auto element : list) {
	element->id = -1;
	}
	list.clear();
	}



	void mjCModel::ResetTreeLists() {
	mjCBody *world = bodies_[0];
	resetlist(bodies_);
	resetlist(joints_);
	resetlist(geoms_);
	resetlist(sites_);
	resetlist(cameras_);
	resetlist(lights_);
	resetlist(frames_);
	world->id = 0;
	bodies_.push_back(world);
	}



	// save associated state addresses in related elements
	void mjCModel::SaveDofOffsets(bool computesize) {
	int qposadr = 0;
	int dofadr = 0;
	int actadr = 0;
	int mocapadr = 0;

	for (auto joint : joints_) {
	joint->qposadr_ = qposadr;
	joint->dofadr_ = dofadr;
	qposadr += joint->nq();
	dofadr += joint->nv();
	}

	for (auto actuator : actuators_) {
	if (actuator->spec.actdim > 0) {
	actuator->actdim_ = actuator->spec.actdim;
	} else {
	actuator->actdim_ = (actuator->spec.dyntype != mjDYN_NONE);
	}
	actuator->actadr_ = actuator->actdim_ ? actadr : -1;
	actadr += actuator->actdim_;
	}

	for (mjCBody* body : bodies_) {
	if (body->spec.mocap) {
	body->mocapid = mocapadr++;
	} else {
	body->mocapid = -1;
	}
	}

	if (computesize) {
	nq = qposadr;
	nv = dofadr;
	na = actadr;
	nu = (int)actuators_.size();
	nmocap = mocapadr;
	}
	}



	template <class T>
	void mjCModel::CopyExplicitPlugin(T* obj) {
	if (!obj->plugin.active \|\| !obj->plugin_instance_name.empty() \|\| !obj->spec.plugin.element) {
	return;
	}
	mjCPlugin* origin = static_cast<mjCPlugin*>(obj->spec.plugin.element);
	mjCPlugin* candidate = deepcopy_ ? new mjCPlugin(*origin) : origin;
	candidate->id = plugins_.size();
	candidate->model = this;
	if (!deepcopy_) {
	candidate->AddRef();
	}
	plugins_.push_back(candidate);
	obj->spec.plugin.element = candidate;
	}

	template void mjCModel::CopyExplicitPlugin<mjCBody>(mjCBody* obj);
	template void mjCModel::CopyExplicitPlugin<mjCGeom>(mjCGeom* obj);
	template void mjCModel::CopyExplicitPlugin<mjCMesh>(mjCMesh* obj);
	template void mjCModel::CopyExplicitPlugin<mjCActuator>(mjCActuator* obj);
	template void mjCModel::CopyExplicitPlugin<mjCSensor>(mjCSensor* obj);



	template <class T>
	void mjCModel::CopyPlugin(const std::vector<mjCPlugin*>& source,
	const std::vector<T*>& list) {
	// store elements that reference a plugin instance
	std::unordered_map<std::string, T*> instances;
	for (const auto& element : list) {
	if (!element->plugin_instance_name.empty()) {
	instances[element->plugin_instance_name] = element;
	}
	}

	// only copy plugins that are referenced
	for (const auto& plugin : source) {
	if (plugin->name.empty() && plugin->model == this) {
	continue;
	}
	mjCPlugin* candidate = new mjCPlugin(*plugin);
	candidate->model = this;
	candidate->NameSpace(plugin->model);
	bool referenced = instances.find(candidate->name) != instances.end();
	auto same_name = [candidate](const mjCPlugin* dest) {
	return dest->name == candidate->name;
	};
	bool instance_exists = std::find_if(plugins_.begin(), plugins_.end(),
	same_name) != plugins_.end();
	if (referenced && !instance_exists) {
	plugins_.push_back(candidate);
	instances.at(candidate->name)->spec.plugin.element = candidate;
	} else {
	delete candidate;
	}
	}
	}



	// return true if the plugin is already in the list of active plugins
	static bool IsPluginActive(
	const mjpPlugin* plugin,
	const std::vector<std::pair<const mjpPlugin*, int> >& active_plugins) {
	return std::find_if(
	active_plugins.begin(), active_plugins.end(),
	[&plugin](const std::pair<const mjpPlugin*, int>& element) {
	return element.first == plugin;
	}) != active_plugins.end();
	}



	mjCModel& mjCModel::operator+=(const mjCModel& other) {
	// create global lists
	ResetTreeLists();
	MakeTreeLists();
	ProcessLists(/checkrepeat=/false);

	// copy all elements not in the tree
	if (this != &other) {
	// do not copy assets for self-attach
	// TODO: asset should be copied only when referenced
	CopyList(meshes_, other.meshes_);
	CopyList(skins_, other.skins_);
	CopyList(hfields_, other.hfields_);
	CopyList(textures_, other.textures_);
	CopyList(materials_, other.materials_);
	for (const auto& key : other.key_pending_) {
	key_pending_.push_back(key);
	}
	CopyList(numerics_, other.numerics_);
	CopyList(texts_, other.texts_);
	}
	CopyList(flexes_, other.flexes_);
	CopyList(pairs_, other.pairs_);
	CopyList(excludes_, other.excludes_);
	CopyList(tendons_, other.tendons_);
	CopyList(equalities_, other.equalities_);
	CopyList(actuators_, other.actuators_);
	CopyList(sensors_, other.sensors_);
	CopyList(tuples_, other.tuples_);

	// create new plugins and map them
	CopyPlugin(other.plugins_, bodies_);
	CopyPlugin(other.plugins_, geoms_);
	CopyPlugin(other.plugins_, meshes_);
	CopyPlugin(other.plugins_, actuators_);
	CopyPlugin(other.plugins_, sensors_);
	for (const auto& [plugin, slot] : other.active_plugins_) {
	if (!IsPluginActive(plugin, active_plugins_)) {
	active_plugins_.emplace_back(std::make_pair(plugin, slot));
	}
	}

	// resize keyframes in the parent model
	if (!keys_.empty()) {
	SaveDofOffsets(/computesize=/true);
	ComputeReference();
	for (auto* key : keys_) {
	ResizeKeyframe(key, qpos0.data(), body_pos0.data(), body_quat0.data());
	}
	nq = nv = na = nu = nmocap = 0;
	}

	// update pointers to local elements
	PointToLocal();

	// update signature after we updated the tree lists and we updated the pointers
	spec.element->signature = Signature();
	return *this;
	}



	template <class T>
	void mjCModel::RemoveFromList(std::vector<T*>& list, const mjCModel& other) {
	int nlist = (int)list.size();
	int removed = 0;
	for (int i = 0; i < nlist; i++) {
	T* element = list[i];
	element->id -= removed;
	try {
	// check if the element contains an error
	element->NameSpace(&other);
	element->CopyFromSpec();
	element->ResolveReferences(&other);
	} catch (mjCError err) {
	continue;
	}
	try {
	// check if the element references something that was removed
	element->NameSpace(this);
	element->CopyFromSpec();
	element->ResolveReferences(this);
	} catch (mjCError err) {
	ids[element->elemtype].erase(element->name);
	element->Release();
	list.erase(list.begin() + i);
	nlist--;
	i--;
	removed++;
	}
	}
	if (removed > 0 && !list.empty()) {
	// if any elements were removed, update ids using processlist
	ProcessList_(ids, list, list[0]->elemtype, /checkrepeat=/false);
	}
	}



	template <>
	void mjCModel::DeleteAll<mjCKey>(std::vector<mjCKey*>& elements) {
	for (mjCKey* element : elements) {
	element->Release();
	}
	elements.clear();
	}



	template <class T>
	void mjCModel::MarkPluginInstance(std::unordered_map<std::string, bool>& instances,
	const std::vector<T*>& list) {
	for (const auto& element : list) {
	if (!element->plugin_instance_name.empty()) {
	instances[element->plugin_instance_name] = true;
	}
	}
	}



	void mjCModel::RemovePlugins() {
	// store elements that reference a plugin instance
	std::unordered_map<std::string, bool> instances;
	MarkPluginInstance(instances, bodies_);
	MarkPluginInstance(instances, geoms_);
	MarkPluginInstance(instances, meshes_);
	MarkPluginInstance(instances, actuators_);
	MarkPluginInstance(instances, sensors_);

	// remove plugins that are not referenced
	int nlist = (int)plugins_.size();
	int removed = 0;
	for (int i = 0; i < nlist; i++) {
	if (plugins_[i]->name.empty()) {
	continue;
	}
	if (instances.find(plugins_[i]->name) == instances.end()) {
	ids[plugins_[i]->elemtype].erase(plugins_[i]->name);
	plugins_[i]->Release();
	plugins_.erase(plugins_.begin() + i);
	nlist--;
	i--;
	removed++;
	}
	}

	// if any elements were removed, update ids using processlist
	if (removed > 0 && !plugins_.empty()) {
	ProcessList_(ids, plugins_, plugins_[0]->elemtype, /checkrepeat=/false);
	}
	}



	mjCModel& mjCModel::operator-=(const mjCBody& subtree) {
	mjCModel oldmodel(*this);

	// create global lists in the old model if not compiled
	if (!oldmodel.IsCompiled()) {
	oldmodel.ProcessLists(/checkrepeat=/false);
	}

	// create global lists in this model if not compiled
	if (!IsCompiled()) {
	ProcessLists(/checkrepeat=/false);
	}

	// all keyframes are now pending and they will be resized
	StoreKeyframes(this);
	DeleteAll(keys_);

	// remove body from tree
	mjCBody* world = bodies_[0];
	*world -= subtree;

	// update global lists
	ResetTreeLists();
	MakeTreeLists();
	ProcessLists(/checkrepeat=/false);

	// check if we have to remove anything else
	RemoveFromList(pairs_, oldmodel);
	RemoveFromList(excludes_, oldmodel);
	RemoveFromList(tendons_, oldmodel);
	RemoveFromList(equalities_, oldmodel);
	RemoveFromList(actuators_, oldmodel);
	RemoveFromList(sensors_, oldmodel);
	RemovePlugins();

	// update signature before we reset the tree lists
	spec.element->signature = Signature();

	return *this;
	}



	// add default tree to this model
	mjCModel& mjCModel::operator+=(mjCDef& subtree) {
	defaults_.push_back(&subtree);
	def_map[subtree.name] = &subtree;
	subtree.model = this;

	// set parent to the main default if this is not the only default in the model
	if (!subtree.parent && &subtree != defaults_[0]) {
	subtree.parent = defaults_[0];
	defaults_[0]->child.push_back(&subtree);
	}

	for (auto def : subtree.child) {
	this += def; // triggers recursive call
	}
	return *this;
	}



	// remove default class from array
	mjCModel& mjCModel::operator-=(const mjCDef& subtree) {

	// check we aren't trying to remove the 'main' default
	if (subtree.id == 0) {
	throw mjCError(0, "cannot remove the global default ('main')");
	}

	// remove this default from parent's child list
	mjCDef* parent = subtree.parent;
	if (parent) {
	for (int i = 0; i < parent->child.size(); ++i) {
	if (parent->child[i] == &subtree) {
	parent->child.erase(parent->child.begin() + i);
	break;
	}
	}
	}

	// traverse tree to find all descendants starting from subtree.id
	std::vector<int> default_ids_to_remove;
	std::vector<int> stack;
	stack.push_back(subtree.id);
	while (!stack.empty()) {
	int id = stack.back();
	stack.pop_back();
	default_ids_to_remove.push_back(id);
	for (int i=0; i<defaults_[id]->child.size(); i++) {
	stack.push_back(defaults_[id]->child[i]->id);
	}
	}

	// remove from the tree
	std::sort(default_ids_to_remove.begin(),
	default_ids_to_remove.end(),
	std::greater<int>());

	for (int id : default_ids_to_remove) {
	delete defaults_[id];
	defaults_.erase(defaults_.begin() + id);
	}

	// reset default ids
	for (int i = 0; i < defaults_.size(); ++i) {
	defaults_[i]->id = i;
	}

	return *this;
	}



	template <class T>
	void deletefromlist(std::vector<T> list, mjsElement* element) {
	if (!list) {
	return;
	}
	for (int j = 0; j < list->size(); ++j) {
	list->at(j)->id = -1;
	if (list->at(j) == element) {
	list->erase(list->begin() + j);
	j--;
	}
	}
	}



	// recursively delete all plugins in the subtree
	void mjCModel::DeleteSubtreePlugin(mjCBody* subtree) {
	mjsPlugin* plugin = &(subtree->spec.plugin);
	if (plugin->active && plugin->name->empty()) {
	*this -= plugin->element;
	}
	for (auto* body : subtree->Bodies()) {
	DeleteSubtreePlugin(body);
	}
	}



	// remove the element from the model
	void mjCModel::operator-=(mjsElement* el) {
	if (el->elemtype == mjOBJ_BODY) {
	mjCBody* body = static_cast<mjCBody*>(el);
	this -= body;
	}

	detached_.push_back(static_cast<mjCBase*>(el));
	ResetTreeLists();

	if (el->elemtype != mjOBJ_DEFAULT) {
	if (static_cast<mjCBase*>(el)->model != this) {
	throw mjCError(nullptr, "element is not in this model");
	}
	} else {
	if (static_cast<mjCDef*>(el)->model != this) {
	throw mjCError(nullptr, "default is not in this model");
	}
	}

	switch (el->elemtype) {
	case mjOBJ_BODY:
	{
	MakeTreeLists(); // rebuild lists that were reset at the beginning of the function
	mjCBody* subtree = static_cast<mjCBody*>(el);
	DeleteSubtreePlugin(subtree);
	break;
	}

	case mjOBJ_DEFAULT:
	MakeTreeLists(); // rebuild lists that were reset at the beginning of the function
	throw mjCError(nullptr, "defaults cannot be deleted, use detach instead");
	break;

	case mjOBJ_GEOM:
	{
	mjCGeom* geom = static_cast<mjCGeom*>(el);
	if (geom->plugin.active && geom->plugin.name->empty()) {
	*this -= geom->plugin.element;
	}
	deletefromlist(&(geom->body->geoms), el);
	break;
	}

	case mjOBJ_SITE:
	deletefromlist(&(static_cast<mjCSite*>(el)->body->sites), el);
	break;

	case mjOBJ_JOINT:
	deletefromlist(&(static_cast<mjCJoint*>(el)->body->joints), el);
	break;

	case mjOBJ_LIGHT:
	deletefromlist(&(static_cast<mjCLight*>(el)->body->lights), el);
	break;

	case mjOBJ_CAMERA:
	deletefromlist(&(static_cast<mjCCamera*>(el)->body->cameras), el);
	break;

	case mjOBJ_MESH:
	{
	mjCMesh* mesh = static_cast<mjCMesh*>(el);
	if (mesh->plugin.active && mesh->plugin.name->empty()) {
	*this -= mesh->plugin.element;
	}
	deletefromlist(object_lists_[mjOBJ_MESH], el);
	break;
	}

	case mjOBJ_ACTUATOR:
	{
	mjCActuator* actuator = static_cast<mjCActuator*>(el);
	if (actuator->plugin.active && actuator->plugin.name->empty()) {
	*this -= actuator->plugin.element;
	}
	deletefromlist(object_lists_[mjOBJ_ACTUATOR], el);
	break;
	}

	case mjOBJ_SENSOR:
	{
	mjCSensor* sensor = static_cast<mjCSensor*>(el);
	if (sensor->plugin.active && sensor->plugin.name->empty()) {
	*this -= sensor->plugin.element;
	}
	deletefromlist(object_lists_[mjOBJ_SENSOR], el);
	break;
	}

	default:
	deletefromlist(object_lists_[el->elemtype], el);
	break;
	}

	ResetTreeLists(); // in case of a nested delete
	MakeTreeLists();
	ProcessLists(/checkrepeat=/false);

	// update signature after we updated everything
	spec.element->signature = Signature();
	}



	// TODO: we should not use C-type casting with multiple C++ inheritance
	void mjCModel::CreateObjectLists() {
	for (int i = 0; i < mjNOBJECT; ++i) {
	object_lists_[i] = nullptr;
	}

	object_lists_[mjOBJ_BODY] = (std::vector<mjCBase>) &bodies_;
	object_lists_[mjOBJ_XBODY] = (std::vector<mjCBase>) &bodies_;
	object_lists_[mjOBJ_JOINT] = (std::vector<mjCBase>) &joints_;
	object_lists_[mjOBJ_GEOM] = (std::vector<mjCBase>) &geoms_;
	object_lists_[mjOBJ_SITE] = (std::vector<mjCBase>) &sites_;
	object_lists_[mjOBJ_CAMERA] = (std::vector<mjCBase>) &cameras_;
	object_lists_[mjOBJ_LIGHT] = (std::vector<mjCBase>) &lights_;
	object_lists_[mjOBJ_FLEX] = (std::vector<mjCBase>) &flexes_;
	object_lists_[mjOBJ_MESH] = (std::vector<mjCBase>) &meshes_;
	object_lists_[mjOBJ_SKIN] = (std::vector<mjCBase>) &skins_;
	object_lists_[mjOBJ_HFIELD] = (std::vector<mjCBase>) &hfields_;
	object_lists_[mjOBJ_TEXTURE] = (std::vector<mjCBase>) &textures_;
	object_lists_[mjOBJ_MATERIAL] = (std::vector<mjCBase>) &materials_;
	object_lists_[mjOBJ_PAIR] = (std::vector<mjCBase>) &pairs_;
	object_lists_[mjOBJ_EXCLUDE] = (std::vector<mjCBase>) &excludes_;
	object_lists_[mjOBJ_EQUALITY] = (std::vector<mjCBase>) &equalities_;
	object_lists_[mjOBJ_TENDON] = (std::vector<mjCBase>) &tendons_;
	object_lists_[mjOBJ_ACTUATOR] = (std::vector<mjCBase>) &actuators_;
	object_lists_[mjOBJ_SENSOR] = (std::vector<mjCBase>) &sensors_;
	object_lists_[mjOBJ_NUMERIC] = (std::vector<mjCBase>) &numerics_;
	object_lists_[mjOBJ_TEXT] = (std::vector<mjCBase>) &texts_;
	object_lists_[mjOBJ_TUPLE] = (std::vector<mjCBase>) &tuples_;
	object_lists_[mjOBJ_KEY] = (std::vector<mjCBase>) &keys_;
	object_lists_[mjOBJ_PLUGIN] = (std::vector<mjCBase>) &plugins_;
	}



	void mjCModel::PointToLocal() {
	spec.element = static_cast<mjsElement*>(this);
	spec.comment = &spec_comment_;
	spec.modelfiledir = &spec_modelfiledir_;
	spec.modelname = &spec_modelname_;
	spec.meshdir = &spec_meshdir_;
	spec.texturedir = &spec_texturedir_;
	comment = nullptr;
	modelfiledir = nullptr;
	modelname = nullptr;
	meshdir = nullptr;
	texturedir = nullptr;
	}



	void mjCModel::CopyFromSpec() {
	static_cast<mjSpec>(this) = spec;
	comment_ = spec_comment_;
	modelfiledir_ = spec_modelfiledir_;
	modelname_ = spec_modelname_;
	meshdir_ = spec_meshdir_;
	texturedir_ = spec_texturedir_;
	}



	// destructor
	mjCModel::~mjCModel() {
	// do not rebuild lists if we are in the process of deleting the model
	compiled = false;

	// delete kinematic tree and all objects allocated in it
	bodies_[0]->Release();

	// delete objects allocated in mjCModel
	for (int i=0; i < flexes_.size(); i++) flexes_[i]->Release();
	for (int i=0; i < meshes_.size(); i++) meshes_[i]->Release();
	for (int i=0; i < skins_.size(); i++) skins_[i]->Release();
	for (int i=0; i < hfields_.size(); i++) hfields_[i]->Release();
	for (int i=0; i < textures_.size(); i++) textures_[i]->Release();
	for (int i=0; i < materials_.size(); i++) materials_[i]->Release();
	for (int i=0; i < pairs_.size(); i++) pairs_[i]->Release();
	for (int i=0; i < excludes_.size(); i++) excludes_[i]->Release();
	for (int i=0; i < equalities_.size(); i++) equalities_[i]->Release();
	for (int i=0; i < tendons_.size(); i++) tendons_[i]->Release(); // also deletes wraps
	for (int i=0; i < actuators_.size(); i++) actuators_[i]->Release();
	for (int i=0; i < sensors_.size(); i++) sensors_[i]->Release();
	for (int i=0; i < numerics_.size(); i++) numerics_[i]->Release();
	for (int i=0; i < texts_.size(); i++) texts_[i]->Release();
	for (int i=0; i < tuples_.size(); i++) tuples_[i]->Release();
	for (int i=0; i < keys_.size(); i++) keys_[i]->Release();
	for (int i=0; i < defaults_.size(); i++) delete defaults_[i];
	for (int i=0; i < specs_.size(); i++) mj_deleteSpec(specs_[i]);
	for (int i=0; i < plugins_.size(); i++) plugins_[i]->Release();
	for (int i=0; i < detached_.size(); i++) detached_[i]->Release();

	// clear sizes and pointer lists created in Compile
	Clear();
	}



	// clear objects allocated by Compile
	void mjCModel::Clear() {
	// sizes set from list lengths
	nbody = 0;
	nbvh = 0;
	nbvhstatic = 0;
	nbvhdynamic = 0;
	noct = 0;
	njnt = 0;
	ngeom = 0;
	nsite = 0;
	ncam = 0;
	nlight = 0;
	nflex = 0;
	nmesh = 0;
	nskin = 0;
	nhfield = 0;
	ntex = 0;
	nmat = 0;
	npair = 0;
	nexclude = 0;
	neq = 0;
	ntendon = 0;
	nsensor = 0;
	nnumeric = 0;
	ntext = 0;

	// sizes set by Compile
	nq = 0;
	nv = 0;
	nu = 0;
	na = 0;
	nflexnode = 0;
	nflexvert = 0;
	nflexedge = 0;
	nflexelem = 0;
	nflexelemdata = 0;
	nflexelemedge = 0;
	nflexshelldata = 0;
	nflexevpair = 0;
	nflextexcoord = 0;
	nmeshvert = 0;
	nmeshnormal = 0;
	nmeshtexcoord = 0;
	nmeshface = 0;
	nmeshgraph = 0;
	nmeshpoly = 0;
	nmeshpolyvert = 0;
	nmeshpolymap = 0;
	nskinvert = 0;
	nskintexvert = 0;
	nskinface = 0;
	nskinbone = 0;
	nskinbonevert = 0;
	nhfielddata = 0;
	ntexdata = 0;
	nwrap = 0;
	nsensordata = 0;
	nnumericdata = 0;
	ntextdata = 0;
	ntupledata = 0;
	npluginattr = 0;
	nnames = 0;
	npaths = 0;
	memory = -1;
	nstack = -1;
	nemax = 0;
	nM = 0;
	nD = 0;
	nB = 0;
	nJmom = 0;
	njmax = -1;
	nconmax = -1;
	nmocap = 0;

	// internal variables
	hasImplicitPluginElem = false;
	compiled = false;
	errInfo = mjCError();
	qpos0.clear();
	}



	//------------------------ API FOR ADDING MODEL ELEMENTS -------------------------------------------

	// add object of any type
	template <class T>
	T* mjCModel::AddObject(vector<T*>& list, string type) {
	T* obj = new T(this);
	obj->id = (int)list.size();
	list.push_back(obj);
	spec.element->signature = Signature();
	return obj;
	}


	// add object of any type, with default parameter
	template <class T>
	T* mjCModel::AddObjectDefault(vector<T>& list, string type, mjCDef def) {
	T* obj = new T(this, def ? def : defaults_[0]);
	obj->id = (int)list.size();
	obj->classname = def ? def->name : "main";
	list.push_back(obj);
	spec.element->signature = Signature();
	return obj;
	}


	// add flex
	mjCFlex* mjCModel::AddFlex() {
	return AddObject(flexes_, "flex");
	}


	// add mesh
	mjCMesh* mjCModel::AddMesh(mjCDef* def) {
	return AddObjectDefault(meshes_, "mesh", def);
	}


	// add skin
	mjCSkin* mjCModel::AddSkin() {
	return AddObject(skins_, "skin");
	}


	// add hfield
	mjCHField* mjCModel::AddHField() {
	return AddObject(hfields_, "hfield");
	}


	// add texture
	mjCTexture* mjCModel::AddTexture() {
	return AddObject(textures_, "texture");
	}


	// add material
	mjCMaterial* mjCModel::AddMaterial(mjCDef* def) {
	return AddObjectDefault(materials_, "material", def);
	}


	// add geom pair to include in collisions
	mjCPair* mjCModel::AddPair(mjCDef* def) {
	return AddObjectDefault(pairs_, "pair", def);
	}


	// add body pair to exclude from collisions
	mjCBodyPair* mjCModel::AddExclude() {
	return AddObject(excludes_, "exclude");
	}


	// add constraint
	mjCEquality* mjCModel::AddEquality(mjCDef* def) {
	return AddObjectDefault(equalities_, "equality", def);
	}


	// add tendon
	mjCTendon* mjCModel::AddTendon(mjCDef* def) {
	return AddObjectDefault(tendons_, "tendon", def);
	}


	// add actuator
	mjCActuator* mjCModel::AddActuator(mjCDef* def) {
	return AddObjectDefault(actuators_, "actuator", def);
	}


	// add sensor
	mjCSensor* mjCModel::AddSensor() {
	return AddObject(sensors_, "sensor");
	}



	// add custom
	mjCNumeric* mjCModel::AddNumeric() {
	return AddObject(numerics_, "numeric");
	}


	// add text
	mjCText* mjCModel::AddText() {
	return AddObject(texts_, "text");
	}


	// add tuple
	mjCTuple* mjCModel::AddTuple() {
	return AddObject(tuples_, "tuple");
	}


	// add keyframe
	mjCKey* mjCModel::AddKey() {
	return AddObject(keys_, "key");
	}


	// add plugin instance
	mjCPlugin* mjCModel::AddPlugin() {
	return AddObject(plugins_, "plugin");
	}


	// append spec to spec
	void mjCModel::AppendSpec(mjSpec* spec, const mjsCompiler* compiler_) {
	// TODO: check if the spec is already in the list
	specs_.push_back(spec);

	if (compiler_) {
	compiler2spec_[compiler_] = spec;
	}
	}



	//------------------------ API FOR ACCESS TO MODEL ELEMENTS ---------------------------------------

	// get number of objects of specified type
	int mjCModel::NumObjects(mjtObj type) {
	if (!object_lists_[type]) {
	return 0;
	}
	return (int) object_lists_[type]->size();
	}



	// get pointer to specified object
	mjCBase* mjCModel::GetObject(mjtObj type, int id) {
	if (id < 0 \|\| id >= NumObjects(type)) {
	return nullptr;
	}
	return (*object_lists_[type])[id];
	}



	template <class T>
	static mjsElement* GetNext(std::vector<T>& list, mjsElement child) {
	if (!child) {
	if (list.empty()) {
	return nullptr;
	}
	return list[0]->spec.element;
	}

	// TODO: use id for direct indexing instead of a loop
	for (unsigned int i = 0; i < list.size()-1; i++) {
	if (list[i]->spec.element == child) {
	return list[i+1]->spec.element;
	}
	}
	return nullptr;
	}



	// next object of specified type
	mjsElement* mjCModel::NextObject(mjsElement* object, mjtObj type) {
	if (type == mjOBJ_UNKNOWN) {
	if (!object) {
	throw mjCError(nullptr, "type must be specified if no element is given");
	} else {
	type = object->elemtype;
	}
	} else if (object && object->elemtype != type) {
	throw mjCError(nullptr, "element is not of requested type");
	}

	switch (type) {
	case mjOBJ_BODY:
	if (!object) {
	return bodies_[0]->spec.element;
	} else if (object == bodies_[0]->spec.element) {
	return bodies_[0]->NextChild(NULL, type, /recursive=/true);
	} else {
	return bodies_[0]->NextChild(object, type, /recursive=/true);
	}
	case mjOBJ_SITE:
	case mjOBJ_GEOM:
	case mjOBJ_JOINT:
	case mjOBJ_CAMERA:
	case mjOBJ_LIGHT:
	case mjOBJ_FRAME:
	return bodies_[0]->NextChild(object, type, /recursive=/true);
	case mjOBJ_ACTUATOR:
	return GetNext(actuators_, object);
	case mjOBJ_SENSOR:
	return GetNext(sensors_, object);
	case mjOBJ_FLEX:
	return GetNext(flexes_, object);
	case mjOBJ_PAIR:
	return GetNext(pairs_, object);
	case mjOBJ_EXCLUDE:
	return GetNext(excludes_, object);
	case mjOBJ_EQUALITY:
	return GetNext(equalities_, object);
	case mjOBJ_TENDON:
	return GetNext(tendons_, object);
	case mjOBJ_NUMERIC:
	return GetNext(numerics_, object);
	case mjOBJ_TEXT:
	return GetNext(texts_, object);
	case mjOBJ_TUPLE:
	return GetNext(tuples_, object);
	case mjOBJ_KEY:
	return GetNext(keys_, object);
	case mjOBJ_MESH:
	return GetNext(meshes_, object);
	case mjOBJ_HFIELD:
	return GetNext(hfields_, object);
	case mjOBJ_SKIN:
	return GetNext(skins_, object);
	case mjOBJ_TEXTURE:
	return GetNext(textures_, object);
	case mjOBJ_MATERIAL:
	return GetNext(materials_, object);
	case mjOBJ_PLUGIN:
	return GetNext(plugins_, object);
	default:
	return nullptr;
	}
	}


	//------------------------ API FOR ACCESS TO PRIVATE VARIABLES -------------------------------------

	// compiled flag
	bool mjCModel::IsCompiled() const {
	return compiled;
	}



	// get reference of error object
	const mjCError& mjCModel::GetError() const {
	return errInfo;
	}



	// pointer to world body
	mjCBody* mjCModel::GetWorld() {
	return bodies_[0];
	}



	// find default class name in array
	mjCDef* mjCModel::FindDefault(string name) {
	for (int i=0; i < (int)defaults_.size(); i++) {
	if (defaults_[i]->name == name) {
	return defaults_[i];
	}
	}
	return nullptr;
	}



	// add default class to array
	mjCDef* mjCModel::AddDefault(string name, mjCDef* parent) {
	// check for repeated name
	int thisid = (int)defaults_.size();
	for (int i=0; i < thisid; i++) {
	if (defaults_[i]->name == name) {
	return 0;
	}
	}

	// create new object
	mjCDef* def = new mjCDef(parent->model);
	defaults_.push_back(def);
	def->id = thisid;

	// initialize contents
	if (parent && parent->id < thisid) {
	parent->CopyFromSpec();
	def->CopyWithoutChildren(*parent);
	parent->child.push_back(def);
	}
	def->parent = parent;
	def->name = name;
	def->child.clear();
	def_map[name] = def;

	return def;
	}



	// find object by name in given list
	template <class T>
	static T* findobject(std::string_view name, const vector<T*>& list, const mjKeyMap& ids) {
	// this can occur in the URDF parser
	if (ids.empty()) {
	for (unsigned int i=0; i < list.size(); i++) {
	if (list[i]->name == name) {
	return list[i];
	}
	}
	return nullptr;
	}

	// during model compilation
	auto id = ids.find(name);
	if (id == ids.end()) {
	return nullptr;
	}
	if (id->second > (int)list.size() - 1) {
	throw mjCError(0, "object not found");
	}
	return list[id->second];
	}



	template <class T>
	mjCBase* mjCModel::FindAsset(std::string_view name, const std::vector<T*>& list) const {
	for (unsigned int i=0; i < list.size(); i++) {
	if (list[i]->name == name) {
	return list[i];
	}
	if (list[i]->name.empty() &&
	std::filesystem::path(list[i]->spec_file_).filename().stem() == name) {
	return list[i];
	}
	}
	return nullptr;
	}

	template mjCBase* mjCModel::FindAsset<mjCTexture>(
	std::string_view name, const std::vector<mjCTexture*>& list) const;
	template mjCBase* mjCModel::FindAsset<mjCMesh>(
	std::string_view name, const std::vector<mjCMesh*>& list) const;



	// find object in global lists given string type and name
	mjCBase* mjCModel::FindObject(mjtObj type, string name) const {
	if (!object_lists_[type]) {
	return nullptr;
	}
	return findobject(name, *object_lists_[type], ids[type]);
	}



	// find body by name
	mjCBase* mjCModel::FindTree(mjCBody* body, mjtObj type, std::string name) {
	switch (type) {
	case mjOBJ_BODY:
	if (body->name == name) {
	return body;
	}
	break;
	case mjOBJ_SITE:
	for (auto site : body->sites) {
	if (site->name == name) {
	return site;
	}
	}
	break;
	case mjOBJ_GEOM:
	for (auto geom : body->geoms) {
	if (geom->name == name) {
	return geom;
	}
	}
	break;
	case mjOBJ_JOINT:
	for (auto joint : body->joints) {
	if (joint->name == name) {
	return joint;
	}
	}
	break;
	case mjOBJ_CAMERA:
	for (auto camera : body->cameras) {
	if (camera->name == name) {
	return camera;
	}
	}
	break;
	case mjOBJ_LIGHT:
	for (auto light : body->lights) {
	if (light->name == name) {
	return light;
	}
	}
	break;
	case mjOBJ_FRAME:
	for (auto frame : body->frames) {
	if (frame->name == name) {
	return frame;
	}
	}
	break;
	default:
	return nullptr;
	}

	for (auto child : body->bodies) {
	auto candidate = FindTree(child, type, name);
	if (candidate) {
	return candidate;
	}
	}

	return nullptr;
	}



	// find spec by name
	mjSpec* mjCModel::FindSpec(std::string name) const {
	for (auto spec : specs_) {
	if (mjs_getString(spec->modelname) == name) {
	return spec;
	}
	}
	return nullptr;
	}



	// find spec by mjsCompiler pointer
	mjSpec* mjCModel::FindSpec(const mjsCompiler* compiler_) {
	if (compiler_ == &spec.compiler) {
	return &spec;
	}

	if (compiler2spec_.find(compiler_) != compiler2spec_.end()) {
	return compiler2spec_[compiler_];
	}

	for (auto s : specs_) {
	mjSpec* source = static_cast<mjCModel*>(s->element)->FindSpec(compiler_);
	if (source) {
	return source;
	}
	}
	return nullptr;
	}



	//------------------------------- COMPILER PHASES --------------------------------------------------

	// make lists of objects in tree: bodies, geoms, joints, sites, cameras, lights
	void mjCModel::MakeTreeLists(mjCBody* body) {
	if (body == nullptr) {
	body = bodies_[0];
	}

	// add this body if not world
	if (body != bodies_[0]) {
	bodies_.push_back(body);
	}

	// add body's geoms, joints, sites, cameras, lights
	for (mjCGeom *geom : body->geoms) geoms_.push_back(geom);
	for (mjCJoint *joint : body->joints) joints_.push_back(joint);
	for (mjCSite *site : body->sites) sites_.push_back(site);
	for (mjCCamera *camera : body->cameras) cameras_.push_back(camera);
	for (mjCLight *light : body->lights) lights_.push_back(light);
	for (mjCFrame *frame : body->frames) frames_.push_back(frame);

	// recursive call to all child bodies
	for (mjCBody* body : body->bodies) MakeTreeLists(body);
	}


	// delete material with given name or all materials if the name is omitted
	template <class T>
	void mjCModel::DeleteMaterial(std::vector<T*>& list, std::string_view name) {
	for (T* plist : list) {
	if (name.empty() \|\| plist->get_material() == name) {
	plist->del_material();
	}
	}
	}



	// delete all textures
	template <class T>
	static void DeleteAllTextures(std::vector<T*>& list) {
	for (T* plist : list) {
	plist->del_textures();
	}
	}


	// delete all texture coordinates
	template <class T>
	static void DeleteTexcoord(std::vector<T*>& list) {
	for (T* plist : list) {
	if (plist->HasTexcoord()) {
	plist->DelTexcoord();
	}
	}
	}


	// returns a vector that stores the reference correction for each entry
	template <class T>
	static void DeleteElements(std::vector<T*>& elements,
	const std::vector<bool>& discard) {
	if (elements.empty()) {
	return;
	}

	std::vector<int> ndiscard(elements.size(), 0);

	int i = 0;
	for (int j=0; j < elements.size(); j++) {
	if (discard[j]) {
	elements[j]->Release();
	} else {
	elements[i] = elements[j];
	i++;
	}
	}

	// count cumulative discarded elements
	for (int i=0; i < elements.size()-1; i++) {
	ndiscard[i+1] = ndiscard[i] + discard[i];
	}

	// erase elements from vector
	if (i < elements.size()) {
	elements.erase(elements.begin() + i, elements.end());
	}

	// update elements
	for (T* element : elements) {
	if (element->id > 0) {
	element->id -= ndiscard[element->id];
	}
	}
	}


	template <>
	void mjCModel::Delete<mjCGeom>(std::vector<mjCGeom*>& elements,
	const std::vector<bool>& discard) {
	// update bodies
	for (mjCBody* body : bodies_) {
	body->geoms.erase(
	std::remove_if(body->geoms.begin(), body->geoms.end(),
	[&discard](mjCGeom* geom) {
	return discard[geom->id];
	}),
	body->geoms.end());
	}

	// remove geoms from the main vector
	DeleteElements(elements, discard);
	}


	template <>
	void mjCModel::Delete<mjCMesh>(std::vector<mjCMesh*>& elements,
	const std::vector<bool>& discard) {
	DeleteElements(elements, discard);
	}


	template <>
	void mjCModel::DeleteAll<mjCMaterial>(std::vector<mjCMaterial*>& elements) {
	DeleteMaterial(geoms_);
	DeleteMaterial(skins_);
	DeleteMaterial(sites_);
	DeleteMaterial(tendons_);
	for (mjCMaterial* element : elements) {
	element->Release();
	}
	elements.clear();
	}


	template <>
	void mjCModel::DeleteAll<mjCTexture>(std::vector<mjCTexture*>& elements) {
	DeleteAllTextures(materials_);
	for (mjCTexture* element : elements) {
	element->Release();
	}
	elements.clear();
	}


	// set nuser fields
	void mjCModel::SetNuser() {
	if (nuser_body == -1) {
	nuser_body = 0;
	for (int i = 0; i < bodies_.size(); i++) {
	nuser_body = mjMAX(nuser_body, bodies_[i]->spec_userdata_.size());
	}
	}
	if (nuser_jnt == -1) {
	nuser_jnt = 0;
	for (int i = 0; i < joints_.size(); i++) {
	nuser_jnt = mjMAX(nuser_jnt, joints_[i]->spec_userdata_.size());
	}
	}
	if (nuser_geom == -1) {
	nuser_geom = 0;
	for (int i = 0; i < geoms_.size(); i++) {
	nuser_geom = mjMAX(nuser_geom, geoms_[i]->spec_userdata_.size());
	}
	}
	if (nuser_site == -1) {
	nuser_site = 0;
	for (int i = 0; i < sites_.size(); i++) {
	nuser_site = mjMAX(nuser_site, sites_[i]->spec_userdata_.size());
	}
	}
	if (nuser_cam == -1) {
	nuser_cam = 0;
	for (int i = 0; i < cameras_.size(); i++) {
	nuser_cam = mjMAX(nuser_cam, cameras_[i]->spec_userdata_.size());
	}
	}
	if (nuser_tendon == -1) {
	nuser_tendon = 0;
	for (int i = 0; i < tendons_.size(); i++) {
	nuser_tendon = mjMAX(nuser_tendon, tendons_[i]->spec_userdata_.size());
	}
	}
	if (nuser_actuator == -1) {
	nuser_actuator = 0;
	for (int i = 0; i < actuators_.size(); i++) {
	nuser_actuator = mjMAX(nuser_actuator, actuators_[i]->spec_userdata_.size());
	}
	}
	if (nuser_sensor == -1) {
	nuser_sensor = 0;
	for (int i = 0; i < sensors_.size(); i++) {
	nuser_sensor = mjMAX(nuser_sensor, sensors_[i]->spec_userdata_.size());
	}
	}
	}

	// index assets
	void mjCModel::IndexAssets(bool discard) {
	// assets referenced in geoms
	for (int i=0; i < geoms_.size(); i++) {
	mjCGeom* geom = geoms_[i];

	// find material by name
	if (!geom->get_material().empty()) {
	mjCBase* material = FindObject(mjOBJ_MATERIAL, geom->get_material());
	if (material) {
	geom->matid = material->id;
	} else {
	throw mjCError(geom, "material '%s' not found in geom %d", geom->get_material().c_str(), i);
	}
	}

	// find mesh by name
	if (!geom->get_meshname().empty()) {
	mjCBase* mesh = FindObject(mjOBJ_MESH, geom->get_meshname());
	if (mesh) {
	if (!geom->visual_) {
	((mjCMesh*)mesh)->SetNotVisual(); // reset to true by mesh->Compile()
	}
	geom->mesh = (discard && geom->visual_) ? nullptr : (mjCMesh*)mesh;
	static_cast<mjCMesh*>(mesh)->needoct_ \|= geom->spec.type == mjGEOM_SDF;
	} else {
	throw mjCError(geom, "mesh '%s' not found in geom %d", geom->get_meshname().c_str(), i);
	}
	}

	// find hfield by name
	if (!geom->get_hfieldname().empty()) {
	mjCBase* hfield = FindObject(mjOBJ_HFIELD, geom->get_hfieldname());
	if (hfield) {
	geom->hfield = (mjCHField*)hfield;
	} else {
	throw mjCError(geom, "hfield '%s' not found in geom %d", geom->get_hfieldname().c_str(), i);
	}
	}
	}

	// assets referenced in skins
	for (int i=0; i < skins_.size(); i++) {
	mjCSkin* skin = skins_[i];

	// find material by name
	if (!skin->material_.empty()) {
	mjCBase* material = FindObject(mjOBJ_MATERIAL, skin->material_);
	if (material) {
	skin->matid = material->id;
	} else {
	throw mjCError(skin, "material '%s' not found in skin %d", skin->material_.c_str(), i);
	}
	}
	}

	// materials referenced in sites
	for (int i=0; i < sites_.size(); i++) {
	mjCSite* site = sites_[i];

	// find material by name
	if (!site->material_.empty()) {
	mjCBase* material = FindObject(mjOBJ_MATERIAL, site->get_material());
	if (material) {
	site->matid = material->id;
	} else {
	throw mjCError(site, "material '%s' not found in site %d", site->material_.c_str(), i);
	}
	}
	}

	// materials referenced in tendons
	for (int i=0; i < tendons_.size(); i++) {
	mjCTendon* tendon = tendons_[i];

	// find material by name
	if (!tendon->material_.empty()) {
	mjCBase* material = FindObject(mjOBJ_MATERIAL, tendon->material_);
	if (material) {
	tendon->matid = material->id;
	} else {
	throw mjCError(tendon, "material '%s' not found in tendon %d", tendon->material_.c_str(), i);
	}
	}
	}

	// textures referenced in materials
	for (int i=0; i < materials_.size(); i++) {
	mjCMaterial* material = materials_[i];

	// find textures by name
	for (int j=0; j < mjNTEXROLE; j++) {
	if (!material->textures_[j].empty()) {
	mjCBase* texture = FindObject(mjOBJ_TEXTURE, material->textures_[j]);
	if (texture) {
	material->texid[j] = texture->id;
	} else {
	throw mjCError(material, "texture '%s' not found in material %d", material->textures_[j].c_str(), i);
	}
	}
	}
	}

	if (discard) {
	std::vector<bool> discard_mesh(meshes_.size(), false);
	std::vector<bool> discard_geom(geoms_.size(), false);

	std::transform(meshes_.begin(), meshes_.end(), discard_mesh.begin(),
	[](const mjCMesh* mesh) {
	return mesh->IsVisual();
	});
	std::transform(geoms_.begin(), geoms_.end(), discard_geom.begin(),
	[](const mjCGeom* geom) {
	return geom->IsVisual();
	});

	// update inertia in bodies
	for (auto body : bodies_) {
	if (body->spec.explicitinertial) {
	continue;
	}
	for (auto geom : body->geoms) {
	if (geom->IsVisual()) {
	if (compiler.inertiafromgeom == mjINERTIAFROMGEOM_TRUE) {
	compiler.inertiafromgeom = mjINERTIAFROMGEOM_AUTO;
	}
	body->explicitinertial = true; // for XML writer
	body->spec.explicitinertial = true;
	body->spec.mass = body->mass;
	mjuu_copyvec(body->spec.ipos, body->ipos, 3);
	mjuu_copyvec(body->spec.iquat, body->iquat, 4);
	mjuu_copyvec(body->spec.inertia, body->inertia, 3);
	break;
	}
	}
	}

	// discard visual meshes and geoms
	Delete(meshes_, discard_mesh);
	Delete(geoms_, discard_geom);
	}
	}



	// throw error if a name is missing
	void mjCModel::CheckEmptyNames(void) {
	// meshes
	for (int i=0; i < meshes_.size(); i++) {
	if (meshes_[i]->name.empty()) {
	throw mjCError(meshes_[i], "empty name in mesh");
	}
	}

	// hfields
	for (int i=0; i < hfields_.size(); i++) {
	if (hfields_[i]->name.empty()) {
	throw mjCError(hfields_[i], "empty name in height field");
	}
	}

	// textures
	for (int i=0; i < textures_.size(); i++) {
	if (textures_[i]->name.empty() && textures_[i]->type != mjTEXTURE_SKYBOX) {
	throw mjCError(textures_[i], "empty name in texture");
	}
	}

	// materials
	for (int i=0; i < materials_.size(); i++) {
	if (materials_[i]->name.empty()) {
	throw mjCError(materials_[i], "empty name in material");
	}
	}
	}



	template <typename T>
	static size_t getpathslength(std::vector<T> list) {
	size_t result = 0;
	for (const auto& element : list) {
	if (!element->File().empty()) {
	result += element->File().length() + 1;
	}
	}

	return result;
	}

	// set array sizes
	void mjCModel::SetSizes() {
	// set from object list sizes
	nbody = (int)bodies_.size();
	njnt = (int)joints_.size();
	ngeom = (int)geoms_.size();
	nsite = (int)sites_.size();
	ncam = (int)cameras_.size();
	nlight = (int)lights_.size();
	nflex = (int)flexes_.size();
	nmesh = (int)meshes_.size();
	nskin = (int)skins_.size();
	nhfield = (int)hfields_.size();
	ntex = (int)textures_.size();
	nmat = (int)materials_.size();
	npair = (int)pairs_.size();
	nexclude = (int)excludes_.size();
	neq = (int)equalities_.size();
	ntendon = (int)tendons_.size();
	nsensor = (int)sensors_.size();
	nnumeric = (int)numerics_.size();
	ntext = (int)texts_.size();
	ntuple = (int)tuples_.size();
	nkey = (int)keys_.size();
	nplugin = (int)plugins_.size();
	nq = nv = nu = na = nmocap = 0;

	// nq, nv
	for (int i=0; i < njnt; i++) {
	nq += joints_[i]->nq();
	nv += joints_[i]->nv();
	}

	// nu, na
	for (int i=0; i < actuators_.size(); i++) {
	nu++;
	na += actuators_[i]->actdim;
	}

	// nbvh, nbvhstatic, nbvhdynamic
	for (int i=0; i < nbody; i++) {
	nbvhstatic += bodies_[i]->tree.Nbvh();
	}
	for (int i=0; i < nmesh; i++) {
	nbvhstatic += meshes_[i]->tree().Nbvh();
	noct += meshes_[i]->octree().NumNodes();
	}
	for (int i=0; i < nflex; i++) {
	nbvhdynamic += flexes_[i]->tree.Nbvh();
	}
	nbvh = nbvhstatic + nbvhdynamic;

	// flex counts
	for (int i=0; i < nflex; i++) {
	nflexnode += flexes_[i]->nnode;
	nflexvert += flexes_[i]->nvert;
	nflexedge += flexes_[i]->nedge;
	nflexelem += flexes_[i]->nelem;
	nflexelemdata += flexes_[i]->nelem * (flexes_[i]->dim + 1);
	nflexelemedge += flexes_[i]->nelem * mjCFlex::kNumEdges[flexes_[i]->dim - 1];
	nflexshelldata += (int)flexes_[i]->shell.size();
	nflexevpair += (int)flexes_[i]->evpair.size()/2;
	nflextexcoord += (flexes_[i]->HasTexcoord() ? flexes_[i]->get_texcoord().size()/2 : 0);
	}

	// mesh counts
	for (int i=0; i < nmesh; i++) {
	nmeshvert += meshes_[i]->nvert();
	nmeshnormal += meshes_[i]->nnormal();
	nmeshface += meshes_[i]->nface();
	nmeshtexcoord += (meshes_[i]->HasTexcoord() ? meshes_[i]->ntexcoord() : 0);
	nmeshgraph += meshes_[i]->szgraph();
	nmeshpoly += meshes_[i]->npolygon();
	nmeshpolyvert += meshes_[i]->npolygonvert();
	nmeshpolymap += meshes_[i]->npolygonmap();
	}

	// skin counts
	for (int i=0; i < nskin; i++) {
	nskinvert += skins_[i]->get_vert().size()/3;
	nskintexvert += skins_[i]->get_texcoord().size()/2;
	nskinface += skins_[i]->get_face().size()/3;
	nskinbone += skins_[i]->bodyid.size();
	for (int j=0; j < skins_[i]->bodyid.size(); j++) {
	nskinbonevert += skins_[i]->get_vertid()[j].size();
	}
	}

	// nhfielddata
	for (int i=0; i < nhfield; i++)nhfielddata += hfields_[i]->nrow * hfields_[i]->ncol;

	// ntexdata
	for (int i=0; i < ntex; i++)ntexdata += textures_[i]->nchannel * textures_[i]->width * textures_[i]->height;

	// nwrap
	for (int i=0; i < ntendon; i++)nwrap += (int)tendons_[i]->path.size();

	// nsensordata
	for (int i=0; i < nsensor; i++)nsensordata += sensors_[i]->dim;

	// nnumericdata
	for (int i=0; i < nnumeric; i++)nnumericdata += numerics_[i]->size;

	// ntextdata
	for (int i=0; i < ntext; i++)ntextdata += (int)texts_[i]->data_.size() + 1;

	// ntupledata
	for (int i=0; i < ntuple; i++)ntupledata += (int)tuples_[i]->objtype_.size();

	// npluginattr
	for (int i=0; i < nplugin; i++)npluginattr += (int)plugins_[i]->flattened_attributes.size();

	// nnames
	nnames = (int)modelname_.size() + 1;
	for (int i=0; i < nbody; i++) nnames += (int)bodies_[i]->name.length() + 1;
	for (int i=0; i < njnt; i++) nnames += (int)joints_[i]->name.length() + 1;
	for (int i=0; i < ngeom; i++) nnames += (int)geoms_[i]->name.length() + 1;
	for (int i=0; i < nsite; i++) nnames += (int)sites_[i]->name.length() + 1;
	for (int i=0; i < ncam; i++) nnames += (int)cameras_[i]->name.length() + 1;
	for (int i=0; i < nlight; i++) nnames += (int)lights_[i]->name.length() + 1;
	for (int i=0; i < nflex; i++) nnames += (int)flexes_[i]->name.length() + 1;
	for (int i=0; i < nmesh; i++) nnames += (int)meshes_[i]->name.length() + 1;
	for (int i=0; i < nskin; i++) nnames += (int)skins_[i]->name.length() + 1;
	for (int i=0; i < nhfield; i++) nnames += (int)hfields_[i]->name.length() + 1;
	for (int i=0; i < ntex; i++) nnames += (int)textures_[i]->name.length() + 1;
	for (int i=0; i < nmat; i++) nnames += (int)materials_[i]->name.length() + 1;
	for (int i=0; i < npair; i++) nnames += (int)pairs_[i]->name.length() + 1;
	for (int i=0; i < nexclude; i++) nnames += (int)excludes_[i]->name.length() + 1;
	for (int i=0; i < neq; i++) nnames += (int)equalities_[i]->name.length() + 1;
	for (int i=0; i < ntendon; i++) nnames += (int)tendons_[i]->name.length() + 1;
	for (int i=0; i < nu; i++) nnames += (int)actuators_[i]->name.length() + 1;
	for (int i=0; i < nsensor; i++) nnames += (int)sensors_[i]->name.length() + 1;
	for (int i=0; i < nnumeric; i++) nnames += (int)numerics_[i]->name.length() + 1;
	for (int i=0; i < ntext; i++) nnames += (int)texts_[i]->name.length() + 1;
	for (int i=0; i < ntuple; i++) nnames += (int)tuples_[i]->name.length() + 1;
	for (int i=0; i < nkey; i++) nnames += (int)keys_[i]->name.length() + 1;
	for (int i=0; i < nplugin; i++) nnames += (int)plugins_[i]->name.length() + 1;

	// npaths
	npaths = 0;
	npaths += getpathslength(hfields_);
	npaths += getpathslength(meshes_);
	npaths += getpathslength(skins_);
	npaths += getpathslength(textures_);
	if (npaths == 0) {
	npaths = 1;
	}

	// nemax
	for (int i=0; i < neq; i++) {
	if (equalities_[i]->type == mjEQ_CONNECT) {
	nemax += 3;
	} else if (equalities_[i]->type == mjEQ_WELD) {
	nemax += 7;
	} else {
	nemax += 1;
	}
	}
	}



	// automatic stiffness and damping computation
	void mjCModel::AutoSpringDamper(mjModel* m) {
	// process all joints
	for (int n=0; n < m->njnt; n++) {
	// get joint dof address and number of dimensions
	int adr = m->jnt_dofadr[n];
	int ndim = mjCJoint::nv((mjtJoint)m->jnt_type[n]);

	// get timeconst and dampratio from joint specification
	mjtNum timeconst = (mjtNum)joints_[n]->springdamper[0];
	mjtNum dampratio = (mjtNum)joints_[n]->springdamper[1];

	// skip joint if either parameter is non-positive
	if (timeconst <= 0 \|\| dampratio <= 0) {
	continue;
	}

	// get average inertia (dof_invweight0 in free joint is different for tran and rot)
	mjtNum inertia = 0;
	for (int i=0; i < ndim; i++) {
	inertia += m->dof_invweight0[adr+i];
	}
	inertia = ((mjtNum)ndim) / std::max(mjMINVAL, inertia);

	// compute stiffness and damping (same as solref computation)
	mjtNum stiffness = inertia / std::max(mjMINVAL, timeconsttimeconstdampratio*dampratio);
	mjtNum damping = 2 * inertia / std::max(mjMINVAL, timeconst);

	// save stiffness and damping in the private mjsJoints
	joints_[n]->stiffness = stiffness;
	joints_[n]->damping = damping;

	// assign
	m->jnt_stiffness[n] = stiffness;
	for (int i=0; i < ndim; i++) {
	m->dof_damping[adr+i] = damping;
	}
	}
	}



	// arguments for lengthrange thread function
	struct _LRThreadArg {
	mjModel* m;
	mjData* data;
	int start;
	int num;
	const mjLROpt* LRopt;
	char* error;
	int error_sz;
	};
	typedef struct _LRThreadArg LRThreadArg;


	// thread function for lengthrange computation
	void* LRfunc(void* arg) {
	LRThreadArg* larg = (LRThreadArg*)arg;

	for (int i=larg->start; i < larg->start+larg->num; i++) {
	if (i < larg->m->nu) {
	if (!mj_setLengthRange(larg->m, larg->data, i, larg->LRopt, larg->error, larg->error_sz)) {
	return nullptr;
	}
	}
	}

	return nullptr;
	}


	// compute actuator lengthrange
	void mjCModel::LengthRange(mjModel* m, mjData* data) {
	// save options and modify
	mjOption saveopt = m->opt;
	m->opt.disableflags = mjDSBL_FRICTIONLOSS \| mjDSBL_CONTACT \| mjDSBL_PASSIVE \|
	mjDSBL_GRAVITY \| mjDSBL_ACTUATION;
	if (compiler.LRopt.timestep > 0) {
	m->opt.timestep = compiler.LRopt.timestep;
	}

	// number of threads available
	int hardware_threads = std::thread::hardware_concurrency();
	const int nthread = mjMAX(1, mjMIN(kMaxCompilerThreads, hardware_threads/2));

	// count actuators that need computation
	int cnt = 0;
	for (int i=0; i < m->nu; i++) {
	// skip depending on mode and type
	int ismuscle = (m->actuator_gaintype[i] == mjGAIN_MUSCLE \|\|
	m->actuator_biastype[i] == mjBIAS_MUSCLE);
	int isuser = (m->actuator_gaintype[i] == mjGAIN_USER \|\|
	m->actuator_biastype[i] == mjBIAS_USER);
	if ((compiler.LRopt.mode == mjLRMODE_NONE) \|\|
	(compiler.LRopt.mode == mjLRMODE_MUSCLE && !ismuscle) \|\|
	(compiler.LRopt.mode == mjLRMODE_MUSCLEUSER && !ismuscle && !isuser)) {
	continue;
	}

	// use existing length range if available
	if (compiler.LRopt.useexisting &&
	(m->actuator_lengthrange[2i] < m->actuator_lengthrange[2i+1])) {
	continue;
	}

	// count
	cnt++;
	}

	// single thread
	if (!compiler.usethread \|\| cnt < 2 \|\| nthread < 2) {
	char err[200];
	for (int i=0; i < m->nu; i++) {
	if (!mj_setLengthRange(m, data, i, &compiler.LRopt, err, 200)) {
	throw mjCError(0, "%s", err);
	}
	}
	}

	// multiple threads
	else {
	// allocate mjData for each thread
	char err[kMaxCompilerThreads][200];
	mjData* pdata[kMaxCompilerThreads] = {data};
	for (int i=1; i < nthread; i++) {
	pdata[i] = mj_makeData(m);
	}

	// number of actuators per thread
	int num = m->nu / nthread;
	while (num*nthread < m->nu) {
	num++;
	}

	// prepare thread function arguments, clear errors
	LRThreadArg arg[kMaxCompilerThreads];
	for (int i=0; i < nthread; i++) {
	LRThreadArg temp = {m, pdata[i], i*num, num, &compiler.LRopt, err[i], 200};
	arg[i] = temp;
	err[i][0] = 0;
	}

	// launch threads
	std::thread th[kMaxCompilerThreads];
	for (int i=0; i < nthread; i++) {
	th[i] = std::thread(LRfunc, arg+i);
	}

	// wait for threads to finish
	for (int i=0; i < nthread; i++) {
	th[i].join();
	}

	// free mjData allocated here
	for (int i=1; i < nthread; i++) {
	mj_deleteData(pdata[i]);
	}

	// report first error
	for (int i=0; i < nthread; i++) {
	if (err[i][0]) {
	throw mjCError(0, "%s", err[i]);
	}
	}
	}

	// restore options
	m->opt = saveopt;
	}


	// Add items to a generic list. This enables the names and paths to be stored.
	// input - string to add
	// adr - current address in the list
	// output_adr_field - the field where the address should be stored (name_meshadr)
	// output_buffer - the field where the data should be stored (i.e. names or paths)
	static int addtolist(const std::string& input, int adr, int* output_adr_field, char* output_buffer) {
	*output_adr_field = adr;

	// copy input
	memcpy(output_buffer+adr, input.c_str(), input.size());
	adr += (int)input.size();

	// append 0
	output_buffer[adr] = 0;
	adr++;

	return adr;
	}

	// process names from one list: concatenate, compute addresses
	template <class T>
	static int namelist(vector<T>& list, int adr, int name_adr, char* names, int* map) {
	// compute hash map addresses
	int map_size = mjLOAD_MULTIPLE*list.size();
	for (unsigned int i=0; i < list.size(); i++) {
	// ignore empty strings
	if (list[i]->name.empty()) {
	continue;
	}

	uint64_t j = mj_hashString(list[i]->name.c_str(), map_size);

	// find first empty slot using linear probing
	for (; map[j] != -1; j=(j+1) % map_size) {}
	map[j] = i;
	}

	for (unsigned int i=0; i < list.size(); i++) {
	adr = addtolist(list[i]->name, adr, &name_adr[i], names);
	}

	return adr;
	}


	// copy names, compute name addresses
	void mjCModel::CopyNames(mjModel* m) {
	// start with model name
	int adr = (int)modelname_.size()+1;
	int* map_adr = m->names_map;
	mju_strncpy(m->names, modelname_.c_str(), m->nnames);
	memset(m->names_map, -1, sizeof(int) * m->nnames_map);

	// process all lists
	adr = namelist(bodies_, adr, m->name_bodyadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*bodies_.size();

	adr = namelist(joints_, adr, m->name_jntadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*joints_.size();

	adr = namelist(geoms_, adr, m->name_geomadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*geoms_.size();

	adr = namelist(sites_, adr, m->name_siteadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*sites_.size();

	adr = namelist(cameras_, adr, m->name_camadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*cameras_.size();

	adr = namelist(lights_, adr, m->name_lightadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*lights_.size();

	adr = namelist(flexes_, adr, m->name_flexadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*flexes_.size();

	adr = namelist(meshes_, adr, m->name_meshadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*meshes_.size();

	adr = namelist(skins_, adr, m->name_skinadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*skins_.size();

	adr = namelist(hfields_, adr, m->name_hfieldadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*hfields_.size();

	adr = namelist(textures_, adr, m->name_texadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*textures_.size();

	adr = namelist(materials_, adr, m->name_matadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*materials_.size();

	adr = namelist(pairs_, adr, m->name_pairadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*pairs_.size();

	adr = namelist(excludes_, adr, m->name_excludeadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*excludes_.size();

	adr = namelist(equalities_, adr, m->name_eqadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*equalities_.size();

	adr = namelist(tendons_, adr, m->name_tendonadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*tendons_.size();

	adr = namelist(actuators_, adr, m->name_actuatoradr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*actuators_.size();

	adr = namelist(sensors_, adr, m->name_sensoradr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*sensors_.size();

	adr = namelist(numerics_, adr, m->name_numericadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*numerics_.size();

	adr = namelist(texts_, adr, m->name_textadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*texts_.size();

	adr = namelist(tuples_, adr, m->name_tupleadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*tuples_.size();

	adr = namelist(keys_, adr, m->name_keyadr, m->names, map_adr);
	map_adr += mjLOAD_MULTIPLE*keys_.size();

	adr = namelist(plugins_, adr, m->name_pluginadr, m->names, map_adr);

	// check size, SHOULD NOT OCCUR
	if (adr != nnames) {
	throw mjCError(0, "size mismatch in %s: expected %d, got %d", "names", nnames, adr);
	}
	}

	// process paths from one list: concatenate, compute addresses
	template <class T>
	static int pathlist(vector<T>& list, int adr, int path_adr, char* paths) {
	for (unsigned int i = 0; i < list.size(); ++i) {
	path_adr[i] = -1;
	if (!list[i] \|\| list[i]->File().empty()) {
	continue;
	}
	adr = addtolist(list[i]->File(), adr, &path_adr[i], paths);
	}

	return adr;
	}

	void mjCModel::CopyPaths(mjModel* m) {
	// start with 0 address, unlike m->names m->paths might be empty
	size_t adr = 0;
	m->paths[0] = 0;
	adr = pathlist(hfields_, adr, m->hfield_pathadr, m->paths);
	adr = pathlist(meshes_, adr, m->mesh_pathadr, m->paths);
	adr = pathlist(skins_, adr, m->skin_pathadr, m->paths);
	adr = pathlist(textures_, adr, m->tex_pathadr, m->paths);
	}



	// copy objects inside kinematic tree
	void mjCModel::CopyTree(mjModel* m) {
	int jntadr = 0; // addresses in global arrays
	int dofadr = 0;
	int qposadr = 0;
	int bvh_adr = 0;

	// main loop over bodies
	for (int i=0; i < nbody; i++) {
	// get body and parent pointers
	mjCBody* pb = bodies_[i];
	mjCBody* par = pb->parent;

	// set body fields
	m->body_parentid[i] = pb->parent ? pb->parent->id : 0;
	m->body_weldid[i] = pb->weldid;
	m->body_mocapid[i] = pb->mocapid;
	m->body_jntnum[i] = (int)pb->joints.size();
	m->body_jntadr[i] = (!pb->joints.empty() ? jntadr : -1);
	m->body_dofnum[i] = pb->dofnum;
	m->body_dofadr[i] = (pb->dofnum ? dofadr : -1);
	m->body_geomnum[i] = (int)pb->geoms.size();
	m->body_geomadr[i] = (!pb->geoms.empty() ? pb->geoms[0]->id : -1);
	mjuu_copyvec(m->body_pos+3*i, pb->pos, 3);
	mjuu_copyvec(m->body_quat+4*i, pb->quat, 4);
	mjuu_copyvec(m->body_ipos+3*i, pb->ipos, 3);
	mjuu_copyvec(m->body_iquat+4*i, pb->iquat, 4);
	m->body_mass[i] = (mjtNum)pb->mass;
	mjuu_copyvec(m->body_inertia+3*i, pb->inertia, 3);
	m->body_gravcomp[i] = pb->gravcomp;
	mjuu_copyvec(m->body_user+nuser_body*i, pb->get_userdata().data(), nuser_body);

	m->body_contype[i] = pb->contype;
	m->body_conaffinity[i] = pb->conaffinity;
	m->body_margin[i] = (mjtNum)pb->margin;

	// bounding volume hierarchy
	m->body_bvhadr[i] = pb->tree.Nbvh() ? bvh_adr : -1;
	m->body_bvhnum[i] = pb->tree.Nbvh();
	if (pb->tree.Nbvh()) {
	memcpy(m->bvh_aabb + 6bvh_adr, pb->tree.Bvh().data(), 6pb->tree.Nbvh()*sizeof(mjtNum));
	memcpy(m->bvh_child + 2bvh_adr, pb->tree.Child().data(), 2pb->tree.Nbvh()*sizeof(int));
	memcpy(m->bvh_depth + bvh_adr, pb->tree.Level().data(), pb->tree.Nbvh()*sizeof(int));
	for (int i=0; i < pb->tree.Nbvh(); i++) {
	m->bvh_nodeid[i + bvh_adr] = pb->tree.Nodeidptr(i) ? *(pb->tree.Nodeidptr(i)) : -1;
	}
	}
	bvh_adr += pb->tree.Nbvh();

	// count free joints
	int cntfree = 0;
	for (int j=0; j < (int)pb->joints.size(); j++) {
	cntfree += (pb->joints[j]->type == mjJNT_FREE);
	}

	// check validity of free joint
	if (cntfree > 1 \|\| (cntfree == 1 && pb->joints.size() > 1)) {
	throw mjCError(pb, "free joint can only appear by itself");
	}
	if (cntfree && par && par->name != "world") {
	throw mjCError(pb, "free joint can only be used on top level");
	}

	// rootid: self if world or child of world, otherwise parent's rootid
	if (i == 0 \|\| (par && par->name == "world")) {
	m->body_rootid[i] = i;
	} else {
	m->body_rootid[i] = m->body_rootid[par->id];
	}

	// init lastdof from parent
	pb->lastdof = par ? par->lastdof : -1;

	// set sameframe
	mjtSameFrame sameframe;
	mjtNum* nullnum = static_cast<mjtNum*>(nullptr);
	if (IsNullPose(m->body_ipos+3i, m->body_iquat+4i)) {
	sameframe = mjSAMEFRAME_BODY;
	} else if (IsNullPose(nullnum, m->body_iquat+4*i)) {
	sameframe = mjSAMEFRAME_BODYROT;
	} else {
	sameframe = mjSAMEFRAME_NONE;
	}
	m->body_sameframe[i] = sameframe;

	// init simple: sameframe, and (self-root, or parent is fixed child of world)
	int parentid = m->body_parentid[i];
	m->body_simple[i] = (sameframe == mjSAMEFRAME_BODY &&
	(m->body_rootid[i] == i \|\|
	(m->body_parentid[parentid] == 0 &&
	m->body_dofnum[parentid] == 0)));

	// a parent body is never simple (unless world)
	if (m->body_parentid[i] > 0) {
	m->body_simple[m->body_parentid[i]] = 0;
	}

	// loop over joints for this body
	int rotfound = 0;
	for (int j=0; j < (int)pb->joints.size(); j++) {
	// get pointer and id
	mjCJoint* pj = pb->joints[j];
	int jid = pj->id;

	// set joint fields
	pj->qposadr_ = qposadr;
	pj->dofadr_ = dofadr;
	m->jnt_type[jid] = pj->type;
	m->jnt_group[jid] = pj->group;
	m->jnt_limited[jid] = (mjtByte)pj->is_limited();
	m->jnt_actfrclimited[jid] = (mjtByte)pj->is_actfrclimited();
	m->jnt_actgravcomp[jid] = pj->actgravcomp;
	m->jnt_qposadr[jid] = qposadr;
	m->jnt_dofadr[jid] = dofadr;
	m->jnt_bodyid[jid] = pj->body->id;
	mjuu_copyvec(m->jnt_pos+3*jid, pj->pos, 3);
	mjuu_copyvec(m->jnt_axis+3*jid, pj->axis, 3);
	m->jnt_stiffness[jid] = (mjtNum)pj->stiffness;
	mjuu_copyvec(m->jnt_range+2*jid, pj->range, 2);
	mjuu_copyvec(m->jnt_actfrcrange+2*jid, pj->actfrcrange, 2);
	mjuu_copyvec(m->jnt_solref+mjNREF*jid, pj->solref_limit, mjNREF);
	mjuu_copyvec(m->jnt_solimp+mjNIMP*jid, pj->solimp_limit, mjNIMP);
	m->jnt_margin[jid] = (mjtNum)pj->margin;
	mjuu_copyvec(m->jnt_user+nuser_jnt*jid, pj->get_userdata().data(), nuser_jnt);

	// not simple if: rotation already found, or pos not zero, or mis-aligned axis
	bool axis_aligned = ((std::abs(pj->axis[0]) > mjEPS) +
	(std::abs(pj->axis[1]) > mjEPS) +
	(std::abs(pj->axis[2]) > mjEPS)) == 1;
	if (rotfound \|\| !IsNullPose(m->jnt_pos+3*jid, nullnum) \|\|
	((pj->type == mjJNT_HINGE \|\| pj->type == mjJNT_SLIDE) && !axis_aligned)) {
	m->body_simple[i] = 0;
	}

	// mark rotation
	if (pj->type == mjJNT_BALL \|\| pj->type == mjJNT_HINGE) {
	rotfound = 1;
	}

	// set qpos0 and qpos_spring, check type
	switch (pj->type) {
	case mjJNT_FREE:
	mjuu_copyvec(m->qpos0+qposadr, pb->pos, 3);
	mjuu_copyvec(m->qpos0+qposadr+3, pb->quat, 4);
	mjuu_copyvec(m->qpos_spring+qposadr, m->qpos0+qposadr, 7);
	break;

	case mjJNT_BALL:
	m->qpos0[qposadr] = 1;
	m->qpos0[qposadr+1] = 0;
	m->qpos0[qposadr+2] = 0;
	m->qpos0[qposadr+3] = 0;
	mjuu_copyvec(m->qpos_spring+qposadr, m->qpos0+qposadr, 4);
	break;

	case mjJNT_SLIDE:
	case mjJNT_HINGE:
	m->qpos0[qposadr] = (mjtNum)pj->ref;
	m->qpos_spring[qposadr] = (mjtNum)pj->springref;
	break;

	default:
	throw mjCError(pj, "unknown joint type");
	}

	// set dof fields for this joint
	for (int j1=0; j1 < pj->nv(); j1++) {
	// set attributes
	m->dof_bodyid[dofadr] = pb->id;
	m->dof_jntid[dofadr] = jid;
	mjuu_copyvec(m->dof_solref+mjNREF*dofadr, pj->solref_friction, mjNREF);
	mjuu_copyvec(m->dof_solimp+mjNIMP*dofadr, pj->solimp_friction, mjNIMP);
	m->dof_frictionloss[dofadr] = (mjtNum)pj->frictionloss;
	m->dof_armature[dofadr] = (mjtNum)pj->armature;
	m->dof_damping[dofadr] = (mjtNum)pj->damping;

	// set dof_parentid, update body.lastdof
	m->dof_parentid[dofadr] = pb->lastdof;
	pb->lastdof = dofadr;

	// advance dof counter
	dofadr++;
	}

	// advance joint and qpos counters
	jntadr++;
	qposadr += pj->nq();
	}

	// simple body with sliders and no rotational dofs: promote to simple level 2
	if (m->body_simple[i] && m->body_dofnum[i]) {
	m->body_simple[i] = 2;
	for (int j=0; j < (int)pb->joints.size(); j++) {
	if (pb->joints[j]->type != mjJNT_SLIDE) {
	m->body_simple[i] = 1;
	break;
	}
	}
	}

	// loop over geoms for this body
	for (int j=0; j < (int)pb->geoms.size(); j++) {
	// get pointer and id
	mjCGeom* pg = pb->geoms[j];
	int gid = pg->id;

	// set geom fields
	m->geom_type[gid] = pg->type;
	m->geom_contype[gid] = pg->contype;
	m->geom_conaffinity[gid] = pg->conaffinity;
	m->geom_condim[gid] = pg->condim;
	m->geom_bodyid[gid] = pg->body->id;
	if (pg->mesh) {
	m->geom_dataid[gid] = pg->mesh->id;
	} else if (pg->hfield) {
	m->geom_dataid[gid] = pg->hfield->id;
	} else {
	m->geom_dataid[gid] = -1;
	}
	m->geom_matid[gid] = pg->matid;
	m->geom_group[gid] = pg->group;
	m->geom_priority[gid] = pg->priority;
	mjuu_copyvec(m->geom_size+3*gid, pg->size, 3);
	mjuu_copyvec(m->geom_aabb+6*gid, pg->aabb, 6);
	mjuu_copyvec(m->geom_pos+3*gid, pg->pos, 3);
	mjuu_copyvec(m->geom_quat+4*gid, pg->quat, 4);
	mjuu_copyvec(m->geom_friction+3*gid, pg->friction, 3);
	m->geom_solmix[gid] = (mjtNum)pg->solmix;
	mjuu_copyvec(m->geom_solref+mjNREF*gid, pg->solref, mjNREF);
	mjuu_copyvec(m->geom_solimp+mjNIMP*gid, pg->solimp, mjNIMP);
	m->geom_margin[gid] = (mjtNum)pg->margin;
	m->geom_gap[gid] = (mjtNum)pg->gap;
	mjuu_copyvec(m->geom_fluid+mjNFLUID*gid, pg->fluid, mjNFLUID);
	mjuu_copyvec(m->geom_user+nuser_geom*gid, pg->get_userdata().data(), nuser_geom);
	mjuu_copyvec(m->geom_rgba+4*gid, pg->rgba, 4);

	// determine sameframe
	double* nulldouble = static_cast<double*>(nullptr);
	if (IsNullPose(m->geom_pos+3gid, m->geom_quat+4gid)) {
	sameframe = mjSAMEFRAME_BODY;
	} else if (IsNullPose(nullnum, m->geom_quat+4*gid)) {
	sameframe = mjSAMEFRAME_BODYROT;
	} else if (IsSamePose(pg->pos, pb->ipos, pg->quat, pb->iquat)) {
	sameframe = mjSAMEFRAME_INERTIA;
	} else if (IsSamePose(nulldouble, nulldouble, pg->quat, pb->iquat)) {
	sameframe = mjSAMEFRAME_INERTIAROT;
	} else {
	sameframe = mjSAMEFRAME_NONE;
	}
	m->geom_sameframe[gid] = sameframe;

	// compute rbound
	m->geom_rbound[gid] = (mjtNum)pg->GetRBound();
	}

	// loop over sites for this body
	for (int j=0; j < (int)pb->sites.size(); j++) {
	// get pointer and id
	mjCSite* ps = pb->sites[j];
	int sid = ps->id;

	// set site fields
	m->site_type[sid] = ps->type;
	m->site_bodyid[sid] = ps->body->id;
	m->site_matid[sid] = ps->matid;
	m->site_group[sid] = ps->group;
	mjuu_copyvec(m->site_size+3*sid, ps->size, 3);
	mjuu_copyvec(m->site_pos+3*sid, ps->pos, 3);
	mjuu_copyvec(m->site_quat+4*sid, ps->quat, 4);
	mjuu_copyvec(m->site_user+nuser_site*sid, ps->userdata_.data(), nuser_site);
	mjuu_copyvec(m->site_rgba+4*sid, ps->rgba, 4);

	// determine sameframe
	double* nulldouble = static_cast<double*>(nullptr);
	if (IsNullPose(m->site_pos+3sid, m->site_quat+4sid)) {
	sameframe = mjSAMEFRAME_BODY;
	} else if (IsNullPose(nullnum, m->site_quat+4*sid)) {
	sameframe = mjSAMEFRAME_BODYROT;
	} else if (IsSamePose(ps->pos, pb->ipos, ps->quat, pb->iquat)) {
	sameframe = mjSAMEFRAME_INERTIA;
	} else if (IsSamePose(nulldouble, nulldouble, ps->quat, pb->iquat)) {
	sameframe = mjSAMEFRAME_INERTIAROT;
	} else {
	sameframe = mjSAMEFRAME_NONE;
	}
	m->site_sameframe[sid] = sameframe;
	}

	// loop over cameras for this body
	for (int j=0; j < (int)pb->cameras.size(); j++) {
	// get pointer and id
	mjCCamera* pc = pb->cameras[j];
	int cid = pc->id;

	// set camera fields
	m->cam_bodyid[cid] = pc->body->id;
	m->cam_mode[cid] = pc->mode;
	m->cam_targetbodyid[cid] = pc->targetbodyid;
	mjuu_copyvec(m->cam_pos+3*cid, pc->pos, 3);
	mjuu_copyvec(m->cam_quat+4*cid, pc->quat, 4);
	m->cam_orthographic[cid] = pc->orthographic;
	m->cam_fovy[cid] = (mjtNum)pc->fovy;
	m->cam_ipd[cid] = (mjtNum)pc->ipd;
	mjuu_copyvec(m->cam_resolution+2*cid, pc->resolution, 2);
	mjuu_copyvec(m->cam_sensorsize+2*cid, pc->sensor_size, 2);
	mjuu_copyvec(m->cam_intrinsic+4*cid, pc->intrinsic, 4);
	mjuu_copyvec(m->cam_user+nuser_cam*cid, pc->get_userdata().data(), nuser_cam);
	}

	// loop over lights for this body
	for (int j=0; j < (int)pb->lights.size(); j++) {
	// get pointer and id
	mjCLight* pl = pb->lights[j];
	int lid = pl->id;

	// set light fields
	m->light_bodyid[lid] = pl->body->id;
	m->light_mode[lid] = (int)pl->mode;
	m->light_targetbodyid[lid] = pl->targetbodyid;
	m->light_type[lid] = pl->type;
	m->light_texid[lid] = pl->texid;
	m->light_castshadow[lid] = (mjtByte)pl->castshadow;
	m->light_active[lid] = (mjtByte)pl->active;
	mjuu_copyvec(m->light_pos+3*lid, pl->pos, 3);
	mjuu_copyvec(m->light_dir+3*lid, pl->dir, 3);
	m->light_bulbradius[lid] = pl->bulbradius;
	m->light_intensity[lid] = pl->intensity;
	m->light_range[lid] = pl->range;
	mjuu_copyvec(m->light_attenuation+3*lid, pl->attenuation, 3);
	m->light_cutoff[lid] = pl->cutoff;
	m->light_exponent[lid] = pl->exponent;
	mjuu_copyvec(m->light_ambient+3*lid, pl->ambient, 3);
	mjuu_copyvec(m->light_diffuse+3*lid, pl->diffuse, 3);
	mjuu_copyvec(m->light_specular+3*lid, pl->specular, 3);
	}
	}

	// check number of dof's constructed, SHOULD NOT OCCUR
	if (nv != dofadr) {
	throw mjCError(0, "unexpected number of DOFs");
	}

	// count kinematic trees under world body, compute dof_treeid
	int ntree = 0;
	for (int i=0; i < nv; i++) {
	if (m->dof_parentid[i] == -1) {
	ntree++;
	}
	m->dof_treeid[i] = ntree - 1;
	}
	m->ntree = ntree;

	// compute body_treeid
	for (int i=0; i < nbody; i++) {
	int weldid = m->body_weldid[i];
	if (m->body_dofnum[weldid]) {
	m->body_treeid[i] = m->dof_treeid[m->body_dofadr[weldid]];
	} else {
	m->body_treeid[i] = -1;
	}
	}

	// count bodies with gravity compensation, compute ngravcomp
	int ngravcomp = 0;
	for (int i=0; i < nbody; i++) {
	ngravcomp += (m->body_gravcomp[i] > 0);
	}
	m->ngravcomp = ngravcomp;

	// compute nM and dof_Madr
	nM = 0;
	for (int i=0; i < nv; i++) {
	// set address of this dof
	m->dof_Madr[i] = nM;

	// count ancestor dofs including self
	int j = i;
	while (j >= 0) {
	nM++;
	j = m->dof_parentid[j];
	}
	}
	m->nM = nM;

	// compute nD
	nD = 2 * nM - nv;
	m->nD = nD;

	// compute subtreedofs in backward pass over bodies
	for (int i = nbody - 1; i > 0; i--) {
	// add body dofs to self count
	bodies_[i]->subtreedofs += bodies_[i]->dofnum;

	// add to parent count
	if (bodies_[i]->parent) {
	bodies_[i]->parent->subtreedofs += bodies_[i]->subtreedofs;
	}
	}

	// make sure all dofs are in world "subtree", SHOULD NOT OCCUR
	if (bodies_[0]->subtreedofs != nv) {
	throw mjCError(0, "all DOFs should be in world subtree");
	}

	// compute nB
	nB = 0;
	for (int i = 0; i < nbody; i++) {
	// add subtree dofs (including self)
	nB += bodies_[i]->subtreedofs;

	// add dofs in ancestor bodies
	int j = bodies_[i]->parent ? bodies_[i]->parent->id : 0;
	while (j > 0) {
	nB += bodies_[j]->dofnum;
	j = bodies_[j]->parent ? bodies_[j]->parent->id : 0;
	}
	}
	m->nB = nB;
	}

	// copy plugin data
	void mjCModel::CopyPlugins(mjModel* m) {
	// assign plugin slots and copy plugin config attributes
	{
	int adr = 0;
	for (int i = 0; i < nplugin; ++i) {
	m->plugin[i] = plugins_[i]->plugin_slot;
	const int size = plugins_[i]->flattened_attributes.size();
	std::memcpy(m->plugin_attr + adr,
	plugins_[i]->flattened_attributes.data(), size);
	m->plugin_attradr[i] = adr;
	adr += size;
	}
	}

	// query and set plugin-related information
	{
	// set actuator_plugin to the plugin instance ID
	std::vector<std::vector<int> > plugin_to_actuators(nplugin);
	for (int i = 0; i < nu; ++i) {
	if (actuators_[i]->plugin.active) {
	int actuator_plugin = static_cast<mjCPlugin*>(actuators_[i]->plugin.element)->id;
	m->actuator_plugin[i] = actuator_plugin;
	plugin_to_actuators[actuator_plugin].push_back(i);
	} else {
	m->actuator_plugin[i] = -1;
	}
	}

	for (int i = 0; i < nbody; ++i) {
	if (bodies_[i]->plugin.active) {
	m->body_plugin[i] = static_cast<mjCPlugin*>(bodies_[i]->plugin.element)->id;
	} else {
	m->body_plugin[i] = -1;
	}
	}

	for (int i = 0; i < ngeom; ++i) {
	if (geoms_[i]->plugin.active) {
	m->geom_plugin[i] = static_cast<mjCPlugin*>(geoms_[i]->plugin.element)->id;
	} else {
	m->geom_plugin[i] = -1;
	}
	}

	std::vector<std::vector<int> > plugin_to_sensors(nplugin);
	for (int i = 0; i < nsensor; ++i) {
	if (sensors_[i]->type == mjSENS_PLUGIN) {
	int sensor_plugin = static_cast<mjCPlugin*>(sensors_[i]->plugin.element)->id;
	m->sensor_plugin[i] = sensor_plugin;
	plugin_to_sensors[sensor_plugin].push_back(i);
	} else {
	m->sensor_plugin[i] = -1;
	}
	}

	// query plugin->nstate, compute and set plugin_state and plugin_stateadr
	// for sensor plugins, also query plugin->nsensordata and set nsensordata
	int stateadr = 0;
	for (int i = 0; i < nplugin; ++i) {
	const mjpPlugin* plugin = mjp_getPluginAtSlot(m->plugin[i]);
	if (!plugin->nstate) {
	mju_error("`nstate` is null for plugin at slot %d", m->plugin[i]);
	}
	int nstate = plugin->nstate(m, i);
	m->plugin_stateadr[i] = stateadr;
	m->plugin_statenum[i] = nstate;
	stateadr += nstate;
	if (plugin->capabilityflags & mjPLUGIN_SENSOR) {
	for (int sensor_id : plugin_to_sensors[i]) {
	if (!plugin->nsensordata) {
	mju_error("`nsensordata` is null for plugin at slot %d", m->plugin[i]);
	}
	int nsensordata = plugin->nsensordata(m, i, sensor_id);
	sensors_[sensor_id]->dim = nsensordata;
	sensors_[sensor_id]->needstage =
	static_cast<mjtStage>(plugin->needstage);
	this->nsensordata += nsensordata;
	}
	}
	}
	m->npluginstate = stateadr;
	}
	}



	// compute non-zeros in actuator_moment matrix
	int mjCModel::CountNJmom(const mjModel* m) {
	int nu = m->nu;
	int nv = m->nv;

	int count = 0;
	for (int i = 0; i < nu; i++) {
	// extract info
	int id = m->actuator_trnid[2 * i];

	// process according to transmission type
	switch ((mjtTrn)m->actuator_trntype[i]) {
	case mjTRN_JOINT:
	case mjTRN_JOINTINPARENT:
	switch ((mjtJoint)m->jnt_type[id]) {
	case mjJNT_SLIDE:
	case mjJNT_HINGE:
	count += 1;
	break;

	case mjJNT_BALL:
	count += 3;
	break;

	case mjJNT_FREE:
	count += 6;
	break;
	}
	break;
	// TODO(taylorhowell): improve upper bounds
	case mjTRN_SLIDERCRANK:
	count += nv;
	break;

	case mjTRN_TENDON:
	count += nv;
	break;

	case mjTRN_SITE:
	count += nv;
	break;

	case mjTRN_BODY:
	count += nv;
	break;

	default:
	// SHOULD NOT OCCUR
	throw mjCError(0, "unknown transmission type");
	break;
	}
	}
	return count;
	}



	// copy objects outside kinematic tree
	void mjCModel::CopyObjects(mjModel* m) {
	int adr, bone_adr, vert_adr, node_adr, normal_adr, face_adr, texcoord_adr, oct_adr;
	int edge_adr, elem_adr, elemdata_adr, elemedge_adr, shelldata_adr, evpair_adr;
	int bonevert_adr, graph_adr, data_adr, bvh_adr;
	int poly_adr, polymap_adr, polyvert_adr;

	// sizes outside call to mj_makeModel
	m->nemax = nemax;
	m->njmax = njmax;
	m->nconmax = nconmax;
	m->nsensordata = nsensordata;
	m->nuserdata = nuserdata;
	m->na = na;

	// find bvh_adr after bodies
	bvh_adr = 0;
	for (int i=0; i < nbody; i++) {
	bvh_adr = mjMAX(bvh_adr, m->body_bvhadr[i] + m->body_bvhnum[i]);
	}

	// meshes
	oct_adr = 0;
	vert_adr = 0;
	normal_adr = 0;
	texcoord_adr = 0;
	face_adr = 0;
	graph_adr = 0;
	poly_adr = 0;
	polyvert_adr = 0;
	polymap_adr = 0;
	for (int i=0; i < nmesh; i++) {
	// get pointer
	mjCMesh* pme = meshes_[i];

	// set fields
	m->mesh_polyadr[i] = poly_adr;
	m->mesh_polynum[i] = pme->npolygon();
	m->mesh_vertadr[i] = vert_adr;
	m->mesh_vertnum[i] = pme->nvert();
	m->mesh_normaladr[i] = normal_adr;
	m->mesh_normalnum[i] = pme->nnormal();
	m->mesh_texcoordadr[i] = (pme->HasTexcoord() ? texcoord_adr : -1);
	m->mesh_texcoordnum[i] = pme->ntexcoord();
	m->mesh_faceadr[i] = face_adr;
	m->mesh_facenum[i] = pme->nface();
	m->mesh_graphadr[i] = (pme->szgraph() ? graph_adr : -1);
	m->mesh_bvhnum[i] = pme->tree().Nbvh();
	m->mesh_bvhadr[i] = pme->tree().Nbvh() ? bvh_adr : -1;
	m->mesh_octnum[i] = pme->octree().NumNodes();
	m->mesh_octadr[i] = pme->octree().NumNodes() ? oct_adr : -1;
	mjuu_copyvec(&m->mesh_scale[3 * i], pme->Scale(), 3);
	mjuu_copyvec(&m->mesh_pos[3 * i], pme->GetPosPtr(), 3);
	mjuu_copyvec(&m->mesh_quat[4 * i], pme->GetQuatPtr(), 4);

	// copy vertices, normals, faces, texcoords, aux data
	pme->CopyVert(m->mesh_vert + 3*vert_adr);
	pme->CopyNormal(m->mesh_normal + 3*normal_adr);
	pme->CopyFace(m->mesh_face + 3*face_adr);
	pme->CopyFaceNormal(m->mesh_facenormal + 3*face_adr);
	if (pme->HasTexcoord()) {
	pme->CopyTexcoord(m->mesh_texcoord + 2*texcoord_adr);
	pme->CopyFaceTexcoord(m->mesh_facetexcoord + 3*face_adr);
	} else {
	memset(m->mesh_facetexcoord + 3face_adr, 0, 3pme->nface()*sizeof(int));
	}
	if (pme->szgraph()) {
	pme->CopyGraph(m->mesh_graph + graph_adr);
	}
	pme->CopyPolygonNormals(m->mesh_polynormal + 3*poly_adr);
	pme->CopyPolygons(m->mesh_polyvert + polyvert_adr, m->mesh_polyvertadr + poly_adr,
	m->mesh_polyvertnum + poly_adr, polyvert_adr);
	pme->CopyPolygonMap(m->mesh_polymap + polymap_adr, m->mesh_polymapadr + vert_adr,
	m->mesh_polymapnum + vert_adr, polymap_adr);

	// copy bvh data
	if (pme->tree().Nbvh()) {
	memcpy(m->bvh_aabb + 6bvh_adr, pme->tree().Bvh().data(), 6pme->tree().Nbvh()*sizeof(mjtNum));
	memcpy(m->bvh_child + 2bvh_adr, pme->tree().Child().data(), 2pme->tree().Nbvh()*sizeof(int));
	memcpy(m->bvh_depth + bvh_adr, pme->tree().Level().data(), pme->tree().Nbvh()*sizeof(int));
	for (int j=0; j < pme->tree().Nbvh(); j++) {
	m->bvh_nodeid[j + bvh_adr] = pme->tree().Nodeid(j) > -1 ? pme->tree().Nodeid(j) : -1;
	}
	}

	// copy octree data
	if (pme->octree().NumNodes()) {
	int n_oct = pme->octree().NumNodes();
	memcpy(m->oct_aabb + 6oct_adr, pme->octree().Nodes().data(), 6n_oct*sizeof(mjtNum));
	memcpy(m->oct_child + 8oct_adr, pme->octree().Child().data(), 8n_oct*sizeof(int));
	memcpy(m->oct_depth + oct_adr, pme->octree().Level().data(), n_oct*sizeof(int));
	if (!pme->octree().Coeff().empty()) {
	memcpy(m->oct_coeff + 8oct_adr, pme->octree().Coeff().data(), 8n_oct*sizeof(mjtNum));
	} else {
	mjuu_zerovec(m->oct_coeff + 8oct_adr, 8n_oct);
	}
	}

	// advance counters
	poly_adr += pme->npolygon();
	polyvert_adr += pme->npolygonvert();
	polymap_adr += pme->npolygonmap();
	vert_adr += pme->nvert();
	normal_adr += pme->nnormal();
	texcoord_adr += (pme->HasTexcoord() ? pme->ntexcoord() : 0);
	face_adr += pme->nface();
	graph_adr += pme->szgraph();
	bvh_adr += pme->tree().Nbvh();
	oct_adr += pme->octree().NumNodes();
	}

	// flexes
	vert_adr = 0;
	node_adr = 0;
	edge_adr = 0;
	elem_adr = 0;
	elemdata_adr = 0;
	elemedge_adr = 0;
	shelldata_adr = 0;
	evpair_adr = 0;
	texcoord_adr = 0;
	for (int i=0; i < nflex; i++) {
	// get pointer
	mjCFlex* pfl = flexes_[i];

	// set fields: geom-like
	m->flex_contype[i] = pfl->contype;
	m->flex_conaffinity[i] = pfl->conaffinity;
	m->flex_condim[i] = pfl->condim;
	m->flex_matid[i] = pfl->matid;
	m->flex_group[i] = pfl->group;
	m->flex_priority[i] = pfl->priority;
	m->flex_solmix[i] = (mjtNum)pfl->solmix;
	mjuu_copyvec(m->flex_solref + mjNREF * i, pfl->solref, mjNREF);
	mjuu_copyvec(m->flex_solimp + mjNIMP * i, pfl->solimp, mjNIMP);
	m->flex_radius[i] = (mjtNum)pfl->radius;
	mjuu_copyvec(m->flex_friction + 3 * i, pfl->friction, 3);
	m->flex_margin[i] = (mjtNum)pfl->margin;
	m->flex_gap[i] = (mjtNum)pfl->gap;
	mjuu_copyvec(m->flex_rgba + 4 * i, pfl->rgba, 4);

	// elasticity
	if (!pfl->stiffness.empty()) {
	mjuu_copyvec(m->flex_stiffness + 21 * elem_adr, pfl->stiffness.data(), pfl->stiffness.size());
	} else {
	mjuu_zerovec(m->flex_stiffness + 21 * elem_adr, 21 * pfl->nelem);
	}
	if (!pfl->bending.empty()) {
	mjuu_copyvec(m->flex_bending + 16 * edge_adr, pfl->bending.data(), pfl->bending.size());
	} else {
	mjuu_zerovec(m->flex_bending + 16 * edge_adr, 16 * pfl->nedge);
	}
	m->flex_damping[i] = (mjtNum)pfl->damping;

	// set fields: mesh-like
	m->flex_dim[i] = pfl->dim;
	m->flex_vertadr[i] = vert_adr;
	m->flex_vertnum[i] = pfl->nvert;
	m->flex_nodeadr[i] = node_adr;
	m->flex_nodenum[i] = pfl->nnode;
	m->flex_edgeadr[i] = edge_adr;
	m->flex_edgenum[i] = pfl->nedge;
	m->flex_elemadr[i] = elem_adr;
	m->flex_elemdataadr[i] = elemdata_adr;
	m->flex_elemedgeadr[i] = elemedge_adr;
	m->flex_shellnum[i] = (int)pfl->shell.size()/pfl->dim;
	m->flex_shelldataadr[i] = m->flex_shellnum[i] ? shelldata_adr : -1;
	if (pfl->evpair.empty()) {
	m->flex_evpairadr[i] = -1;
	m->flex_evpairnum[i] = 0;
	} else {
	m->flex_evpairadr[i] = evpair_adr;
	m->flex_evpairnum[i] = (int)pfl->evpair.size()/2;
	memcpy(m->flex_evpair + 2evpair_adr, pfl->evpair.data(), pfl->evpair.size()sizeof(int));
	}
	if (pfl->texcoord_.empty()) {
	m->flex_texcoordadr[i] = -1;
	memcpy(m->flex_elemtexcoord + elemdata_adr, pfl->elem_.data(), pfl->elem_.size()*sizeof(int));
	} else {
	m->flex_texcoordadr[i] = texcoord_adr;
	memcpy(m->flex_texcoord + 2*texcoord_adr,
	pfl->texcoord_.data(), pfl->texcoord_.size()*sizeof(float));
	memcpy(m->flex_elemtexcoord + elemdata_adr, pfl->elemtexcoord_.data(),
	pfl->elemtexcoord_.size()*sizeof(int));
	}
	m->flex_elemnum[i] = pfl->nelem;
	memcpy(m->flex_elem + elemdata_adr, pfl->elem_.data(), pfl->elem_.size()*sizeof(int));
	memcpy(m->flex_elemedge + elemedge_adr, pfl->edgeidx_.data(), pfl->edgeidx_.size()*sizeof(int));
	memcpy(m->flex_elemlayer + elem_adr, pfl->elemlayer.data(), pfl->nelem*sizeof(int));
	if (m->flex_shellnum[i]) {
	memcpy(m->flex_shell + shelldata_adr, pfl->shell.data(), pfl->shell.size()*sizeof(int));
	}
	m->flex_edgestiffness[i] = (mjtNum)pfl->edgestiffness;
	m->flex_edgedamping[i] = (mjtNum)pfl->edgedamping;
	m->flex_rigid[i] = pfl->rigid;
	m->flex_centered[i] = pfl->centered;
	m->flex_internal[i] = pfl->internal;
	m->flex_flatskin[i] = pfl->flatskin;
	m->flex_selfcollide[i] = pfl->selfcollide;
	m->flex_activelayers[i] = pfl->activelayers;
	m->flex_bvhnum[i] = pfl->tree.Nbvh();
	m->flex_bvhadr[i] = pfl->tree.Nbvh() ? bvh_adr : -1;

	// find equality constraint referencing this flex
	m->flex_edgeequality[i] = 0;
	for (int k=0; k < (int)equalities_.size(); k++) {
	if (equalities_[k]->type == mjEQ_FLEX && equalities_[k]->name1_ == pfl->name) {
	m->flex_edgeequality[i] = 1;
	break;
	}
	}

	// copy bvh data (flex aabb computed dynamically in mjData)
	if (pfl->tree.Nbvh()) {
	memcpy(m->bvh_child + 2bvh_adr, pfl->tree.Child().data(), 2pfl->tree.Nbvh()*sizeof(int));
	memcpy(m->bvh_depth + bvh_adr, pfl->tree.Level().data(), pfl->tree.Nbvh()*sizeof(int));
	for (int i=0; i < pfl->tree.Nbvh(); i++) {
	m->bvh_nodeid[i+ bvh_adr] = pfl->tree.Nodeidptr(i) ? *(pfl->tree.Nodeidptr(i)) : -1;
	}
	}

	// copy or set vert
	if (pfl->centered && !pfl->interpolated) {
	mjuu_zerovec(m->flex_vert + 3vert_adr, 3pfl->nvert);
	}
	else {
	mjuu_copyvec(m->flex_vert + 3vert_adr, pfl->vert_.data(), 3pfl->nvert);
	}

	// copy or set node
	if (pfl->centered && pfl->interpolated) {
	mjuu_zerovec(m->flex_node + 3node_adr, 3pfl->nnode);
	}
	else if (pfl->interpolated) {
	mjuu_copyvec(m->flex_node + 3node_adr, pfl->node_.data(), 3pfl->nnode);
	}

	// copy vert0
	mjuu_copyvec(m->flex_vert0 + 3vert_adr, pfl->vert0_.data(), 3pfl->nvert);

	// copy node0
	mjuu_copyvec(m->flex_node0 + 3node_adr, pfl->node0_.data(), 3pfl->nnode);

	// copy or set vertbodyid
	if (pfl->rigid) {
	for (int k=0; k < pfl->nvert; k++) {
	m->flex_vertbodyid[vert_adr + k] = pfl->vertbodyid[0];
	}
	}
	else {
	memcpy(m->flex_vertbodyid + vert_adr, pfl->vertbodyid.data(), pfl->nvert*sizeof(int));
	}

	// copy or set nodebodyid
	if (pfl->rigid) {
	for (int k=0; k < pfl->nnode; k++) {
	m->flex_nodebodyid[node_adr + k] = pfl->nodebodyid[0];
	}
	} else {
	memcpy(m->flex_nodebodyid + node_adr, pfl->nodebodyid.data(), pfl->nnode*sizeof(int));
	}

	// set interpolation type, only two types for now
	m->flex_interp[i] = pfl->interpolated;

	// convert edge pairs to int array, set edge rigid
	for (int k=0; k < pfl->nedge; k++) {
	m->flex_edge[2*(edge_adr+k)] = pfl->edge[k].first;
	m->flex_edge[2*(edge_adr+k)+1] = pfl->edge[k].second;
	if (pfl->dim == 2 && (pfl->elastic2d == 1 \|\| pfl->elastic2d == 3)) {
	m->flex_edgeflap[2*(edge_adr+k)+0] = pfl->flaps[k].vertices[2];
	m->flex_edgeflap[2*(edge_adr+k)+1] = pfl->flaps[k].vertices[3];
	} else {
	m->flex_edgeflap[2*(edge_adr+k)+0] = -1;
	m->flex_edgeflap[2*(edge_adr+k)+1] = -1;
	}

	if (pfl->rigid) {
	m->flexedge_rigid[edge_adr+k] = 1;
	} else if (!pfl->interpolated) {
	// check if vertex body weldids are the same
	// unsupported by trilinear interpolation
	int b1 = pfl->vertbodyid[pfl->edge[k].first];
	int b2 = pfl->vertbodyid[pfl->edge[k].second];
	m->flexedge_rigid[edge_adr+k] = (bodies_[b1]->weldid == bodies_[b2]->weldid);
	}
	}

	// advance counters
	vert_adr += pfl->nvert;
	node_adr += pfl->nnode;
	edge_adr += pfl->nedge;
	elem_adr += pfl->nelem;
	elemdata_adr += (pfl->dim+1) * pfl->nelem;
	elemedge_adr += (pfl->kNumEdges[pfl->dim-1]) * pfl->nelem;
	shelldata_adr += (int)pfl->shell.size();
	evpair_adr += (int)pfl->evpair.size()/2;
	texcoord_adr += (int)pfl->texcoord_.size()/2;
	bvh_adr += pfl->tree.Nbvh();
	}

	// skins
	vert_adr = 0;
	face_adr = 0;
	texcoord_adr = 0;
	bone_adr = 0;
	bonevert_adr = 0;
	for (int i=0; i < nskin; i++) {
	// get pointer
	mjCSkin* psk = skins_[i];

	// set fields
	m->skin_matid[i] = psk->matid;
	m->skin_group[i] = psk->group;
	mjuu_copyvec(m->skin_rgba+4*i, psk->rgba, 4);
	m->skin_inflate[i] = psk->inflate;
	m->skin_vertadr[i] = vert_adr;
	m->skin_vertnum[i] = psk->get_vert().size()/3;
	m->skin_texcoordadr[i] = (!psk->get_texcoord().empty() ? texcoord_adr : -1);
	m->skin_faceadr[i] = face_adr;
	m->skin_facenum[i] = psk->get_face().size()/3;
	m->skin_boneadr[i] = bone_adr;
	m->skin_bonenum[i] = psk->bodyid.size();

	// copy mesh data
	memcpy(m->skin_vert + 3vert_adr, psk->get_vert().data(), psk->get_vert().size()sizeof(float));
	if (!psk->get_texcoord().empty())
	memcpy(m->skin_texcoord + 2*texcoord_adr, psk->get_texcoord().data(),
	psk->get_texcoord().size()*sizeof(float));
	memcpy(m->skin_face + 3face_adr, psk->get_face().data(), psk->get_face().size()sizeof(int));

	// copy bind poses and body ids
	memcpy(m->skin_bonebindpos+3*bone_adr, psk->get_bindpos().data(),
	psk->get_bindpos().size()*sizeof(float));
	memcpy(m->skin_bonebindquat+4*bone_adr, psk->get_bindquat().data(),
	psk->get_bindquat().size()*sizeof(float));
	memcpy(m->skin_bonebodyid+bone_adr, psk->bodyid.data(),
	psk->bodyid.size()*sizeof(int));

	// copy per-bone vertex data, advance vertex counter
	for (int j=0; j < m->skin_bonenum[i]; j++) {
	// set fields
	m->skin_bonevertadr[bone_adr+j] = bonevert_adr;
	m->skin_bonevertnum[bone_adr+j] = (int)psk->get_vertid()[j].size();

	// copy data
	memcpy(m->skin_bonevertid+bonevert_adr, psk->get_vertid()[j].data(),
	psk->get_vertid()[j].size()*sizeof(int));
	memcpy(m->skin_bonevertweight+bonevert_adr, psk->get_vertweight()[j].data(),
	psk->get_vertid()[j].size()*sizeof(float));

	// advance counter
	bonevert_adr += m->skin_bonevertnum[bone_adr+j];
	}

	// advance mesh and bone counters
	vert_adr += m->skin_vertnum[i];
	texcoord_adr += psk->get_texcoord().size()/2;
	face_adr += m->skin_facenum[i];
	bone_adr += m->skin_bonenum[i];
	}

	// hfields
	data_adr = 0;
	for (int i=0; i < nhfield; i++) {
	// get pointer
	mjCHField* phf = hfields_[i];

	// set fields
	mjuu_copyvec(m->hfield_size+4*i, phf->size, 4);
	m->hfield_nrow[i] = phf->nrow;
	m->hfield_ncol[i] = phf->ncol;
	m->hfield_adr[i] = data_adr;

	// copy elevation data
	memcpy(m->hfield_data + data_adr, phf->data.data(), phf->nrowphf->ncolsizeof(float));

	// advance counter
	data_adr += phf->nrow*phf->ncol;
	}

	// textures
	data_adr = 0;
	for (int i=0; i < ntex; i++) {
	// get pointer
	mjCTexture* ptex = textures_[i];

	// set fields
	m->tex_type[i] = ptex->type;
	m->tex_colorspace[i] = ptex->colorspace;
	m->tex_height[i] = ptex->height;
	m->tex_width[i] = ptex->width;
	m->tex_nchannel[i] = ptex->nchannel;
	m->tex_adr[i] = data_adr;

	// copy rgb data
	memcpy(m->tex_data + data_adr, ptex->data_.data(),
	ptex->nchannel * ptex->width * ptex->height);

	// advance counter
	data_adr += ptex->nchannel * ptex->width * ptex->height;
	}

	// materials
	for (int i=0; i < nmat; i++) {
	// get pointer
	mjCMaterial* pmat = materials_[i];

	// set fields
	for (int j=0; j < mjNTEXROLE; j++) {
	m->mat_texid[mjNTEXROLE*i+j] = pmat->texid[j];
	}
	m->mat_texuniform[i] = pmat->texuniform;
	mjuu_copyvec(m->mat_texrepeat+2*i, pmat->texrepeat, 2);
	m->mat_emission[i] = pmat->emission;
	m->mat_specular[i] = pmat->specular;
	m->mat_shininess[i] = pmat->shininess;
	m->mat_reflectance[i] = pmat->reflectance;
	m->mat_metallic[i] = pmat->metallic;
	m->mat_roughness[i] = pmat->roughness;
	mjuu_copyvec(m->mat_rgba+4*i, pmat->rgba, 4);
	}

	// geom pairs to include
	for (int i=0; i < npair; i++) {
	m->pair_dim[i] = pairs_[i]->condim;
	m->pair_geom1[i] = pairs_[i]->geom1->id;
	m->pair_geom2[i] = pairs_[i]->geom2->id;
	m->pair_signature[i] = pairs_[i]->signature;
	mjuu_copyvec(m->pair_solref+mjNREF*i, pairs_[i]->solref, mjNREF);
	mjuu_copyvec(m->pair_solreffriction+mjNREF*i, pairs_[i]->solreffriction, mjNREF);
	mjuu_copyvec(m->pair_solimp+mjNIMP*i, pairs_[i]->solimp, mjNIMP);
	m->pair_margin[i] = (mjtNum)pairs_[i]->margin;
	m->pair_gap[i] = (mjtNum)pairs_[i]->gap;
	mjuu_copyvec(m->pair_friction+5*i, pairs_[i]->friction, 5);
	}

	// body pairs to exclude
	for (int i=0; i < nexclude; i++) {
	m->exclude_signature[i] = excludes_[i]->signature;
	}

	// equality constraints
	for (int i=0; i < neq; i++) {
	// get pointer
	mjCEquality* peq = equalities_[i];

	// set fields
	m->eq_type[i] = peq->type;
	m->eq_obj1id[i] = peq->obj1id;
	m->eq_obj2id[i] = peq->obj2id;
	m->eq_objtype[i] = peq->objtype;
	m->eq_active0[i] = peq->active;
	mjuu_copyvec(m->eq_solref+mjNREF*i, peq->solref, mjNREF);
	mjuu_copyvec(m->eq_solimp+mjNIMP*i, peq->solimp, mjNIMP);
	mjuu_copyvec(m->eq_data+mjNEQDATA*i, peq->data, mjNEQDATA);
	}

	// tendons and wraps
	adr = 0;
	for (int i=0; i < ntendon; i++) {
	// get pointer
	mjCTendon* pte = tendons_[i];

	// set fields
	m->tendon_adr[i] = adr;
	m->tendon_num[i] = (int)pte->path.size();
	m->tendon_matid[i] = pte->matid;
	m->tendon_group[i] = pte->group;
	m->tendon_limited[i] = (mjtByte)pte->is_limited();
	m->tendon_actfrclimited[i] = (mjtByte)pte->is_actfrclimited();
	m->tendon_width[i] = (mjtNum)pte->width;
	mjuu_copyvec(m->tendon_solref_lim+mjNREF*i, pte->solref_limit, mjNREF);
	mjuu_copyvec(m->tendon_solimp_lim+mjNIMP*i, pte->solimp_limit, mjNIMP);
	mjuu_copyvec(m->tendon_solref_fri+mjNREF*i, pte->solref_friction, mjNREF);
	mjuu_copyvec(m->tendon_solimp_fri+mjNIMP*i, pte->solimp_friction, mjNIMP);
	m->tendon_range[2*i] = (mjtNum)pte->range[0];
	m->tendon_range[2*i+1] = (mjtNum)pte->range[1];
	m->tendon_actfrcrange[2*i] = (mjtNum)pte->actfrcrange[0];
	m->tendon_actfrcrange[2*i+1] = (mjtNum)pte->actfrcrange[1];
	m->tendon_margin[i] = (mjtNum)pte->margin;
	m->tendon_stiffness[i] = (mjtNum)pte->stiffness;
	m->tendon_damping[i] = (mjtNum)pte->damping;
	m->tendon_armature[i] = (mjtNum)pte->armature;
	m->tendon_frictionloss[i] = (mjtNum)pte->frictionloss;
	m->tendon_lengthspring[2*i] = (mjtNum)pte->springlength[0];
	m->tendon_lengthspring[2*i+1] = (mjtNum)pte->springlength[1];
	mjuu_copyvec(m->tendon_user+nuser_tendon*i, pte->get_userdata().data(), nuser_tendon);
	mjuu_copyvec(m->tendon_rgba+4*i, pte->rgba, 4);

	// set wraps
	for (int j=0; j < (int)pte->path.size(); j++) {
	m->wrap_type[adr+j] = pte->path[j]->type;
	m->wrap_objid[adr+j] = pte->path[j]->obj ? pte->path[j]->obj->id : -1;
	m->wrap_prm[adr+j] = (mjtNum)pte->path[j]->prm;
	if (pte->path[j]->type == mjWRAP_SPHERE \|\| pte->path[j]->type == mjWRAP_CYLINDER) {
	m->wrap_prm[adr+j] = (mjtNum)pte->path[j]->sideid;
	}
	}

	// advance address counter
	adr += (int)pte->path.size();
	}

	// actuators
	adr = 0;
	for (int i=0; i < nu; i++) {
	// get pointer
	mjCActuator* pac = actuators_[i];

	// set fields
	m->actuator_trntype[i] = pac->trntype;
	m->actuator_dyntype[i] = pac->dyntype;
	m->actuator_gaintype[i] = pac->gaintype;
	m->actuator_biastype[i] = pac->biastype;
	m->actuator_trnid[2*i] = pac->trnid[0];
	m->actuator_trnid[2*i+1] = pac->trnid[1];
	m->actuator_actnum[i] = pac->actdim;
	m->actuator_actadr[i] = m->actuator_actnum[i] ? adr : -1;
	pac->actadr_ = m->actuator_actadr[i];
	pac->actdim_ = m->actuator_actnum[i];
	adr += m->actuator_actnum[i];
	m->actuator_group[i] = pac->group;
	m->actuator_ctrllimited[i] = (mjtByte)pac->is_ctrllimited();
	m->actuator_forcelimited[i] = (mjtByte)pac->is_forcelimited();
	m->actuator_actlimited[i] = (mjtByte)pac->is_actlimited();
	m->actuator_actearly[i] = pac->actearly;
	m->actuator_cranklength[i] = (mjtNum)pac->cranklength;
	mjuu_copyvec(m->actuator_gear + 6*i, pac->gear, 6);
	mjuu_copyvec(m->actuator_dynprm + mjNDYN*i, pac->dynprm, mjNDYN);
	mjuu_copyvec(m->actuator_gainprm + mjNGAIN*i, pac->gainprm, mjNGAIN);
	mjuu_copyvec(m->actuator_biasprm + mjNBIAS*i, pac->biasprm, mjNBIAS);
	mjuu_copyvec(m->actuator_ctrlrange + 2*i, pac->ctrlrange, 2);
	mjuu_copyvec(m->actuator_forcerange + 2*i, pac->forcerange, 2);
	mjuu_copyvec(m->actuator_actrange + 2*i, pac->actrange, 2);
	mjuu_copyvec(m->actuator_lengthrange + 2*i, pac->lengthrange, 2);
	mjuu_copyvec(m->actuator_user+nuser_actuator*i, pac->get_userdata().data(), nuser_actuator);
	}

	// sensors
	adr = 0;
	for (int i=0; i < nsensor; i++) {
	// get pointer
	mjCSensor* psen = sensors_[i];

	// set fields
	m->sensor_type[i] = psen->type;
	m->sensor_datatype[i] = psen->datatype;
	m->sensor_needstage[i] = psen->needstage;
	m->sensor_objtype[i] = psen->objtype;
	m->sensor_objid[i] = psen->obj ? psen->obj->id : -1;
	m->sensor_reftype[i] = psen->reftype;
	m->sensor_refid[i] = psen->ref ? psen->ref->id : -1;
	mjuu_copyvec(m->sensor_intprm+i*mjNSENS, psen->intprm, mjNSENS);
	m->sensor_dim[i] = psen->dim;
	m->sensor_cutoff[i] = (mjtNum)psen->cutoff;
	m->sensor_noise[i] = (mjtNum)psen->noise;
	mjuu_copyvec(m->sensor_user+nuser_sensor*i, psen->get_userdata().data(), nuser_sensor);

	// calculate address and advance
	m->sensor_adr[i] = adr;
	adr += psen->dim;
	}

	// numeric fields
	adr = 0;
	for (int i=0; i < nnumeric; i++) {
	// get pointer
	mjCNumeric* pcu = numerics_[i];

	// set fields
	m->numeric_adr[i] = adr;
	m->numeric_size[i] = pcu->size;
	for (int j=0; j < (int)pcu->data_.size(); j++) {
	m->numeric_data[adr+j] = (mjtNum)pcu->data_[j];
	}
	for (int j=(int)pcu->data_.size(); j < (int)pcu->size; j++) {
	m->numeric_data[adr+j] = 0;
	}

	// advance address counter
	adr += m->numeric_size[i];
	}

	// text fields
	adr = 0;
	for (int i=0; i < ntext; i++) {
	// get pointer
	mjCText* pte = texts_[i];

	// set fields
	m->text_adr[i] = adr;
	m->text_size[i] = (int)pte->data_.size()+1;
	mju_strncpy(m->text_data + adr, pte->data_.c_str(), m->ntextdata - adr);

	// advance address counter
	adr += m->text_size[i];
	}

	// tuple fields
	adr = 0;
	for (int i=0; i < ntuple; i++) {
	// get pointer
	mjCTuple* ptu = tuples_[i];

	// set fields
	m->tuple_adr[i] = adr;
	m->tuple_size[i] = (int)ptu->objtype_.size();
	for (int j=0; j < m->tuple_size[i]; j++) {
	m->tuple_objtype[adr+j] = (int)ptu->objtype_[j];
	m->tuple_objid[adr+j] = ptu->obj[j]->id;
	m->tuple_objprm[adr+j] = (mjtNum)ptu->objprm_[j];
	}

	// advance address counter
	adr += m->tuple_size[i];
	}

	// copy keyframe data
	for (int i=0; i < nkey; i++) {
	// copy data
	m->key_time[i] = (mjtNum)keys_[i]->time;
	mjuu_copyvec(m->key_qpos+i*nq, keys_[i]->qpos_.data(), nq);
	mjuu_copyvec(m->key_qvel+i*nv, keys_[i]->qvel_.data(), nv);
	if (na) {
	mjuu_copyvec(m->key_act+i*na, keys_[i]->act_.data(), na);
	}
	if (nmocap) {
	mjuu_copyvec(m->key_mpos + i3nmocap, keys_[i]->mpos_.data(), 3*nmocap);
	mjuu_copyvec(m->key_mquat + i4nmocap, keys_[i]->mquat_.data(), 4*nmocap);
	}

	// normalize quaternions in m->key_qpos
	for (int j=0; j < m->njnt; j++) {
	if (m->jnt_type[j] == mjJNT_BALL \|\| m->jnt_type[j] == mjJNT_FREE) {
	mjuu_normvec(m->key_qpos+inq+m->jnt_qposadr[j]+3(m->jnt_type[j] == mjJNT_FREE), 4);
	}
	}

	// normalize quaternions in m->key_mquat
	for (int j=0; j < nmocap; j++) {
	mjuu_normvec(m->key_mquat+i4nmocap+4*j, 4);
	}

	mjuu_copyvec(m->key_ctrl+i*nu, keys_[i]->ctrl_.data(), nu);
	}

	// save qpos0 in user model (to recognize changed key_qpos in write)
	qpos0.resize(nq);
	body_pos0.resize(3*nbody);
	body_quat0.resize(4*nbody);
	mjuu_copyvec(qpos0.data(), m->qpos0, nq);
	mjuu_copyvec(body_pos0.data(), m->body_pos, 3*nbody);
	mjuu_copyvec(body_quat0.data(), m->body_quat, 4*nbody);
	}



	// finalize simple bodies/dofs including tendon information
	void mjCModel::FinalizeSimple(mjModel* m) {
	// demote bodies affected by inertia-bearing tendon to non-simple
	for (int i=0; i < ntendon; i++) {
	if (m->tendon_armature[i] == 0) {
	continue;
	}
	int adr = m->tendon_adr[i];
	int num = m->tendon_num[i];
	for (int j=adr; j < adr+num; j++) {
	int objid = m->wrap_objid[j];
	if (m->wrap_type[j] == mjWRAP_SITE) {
	m->body_simple[m->site_bodyid[objid]] = 0;
	}
	if (m->wrap_type[j] == mjWRAP_CYLINDER \|\| m->wrap_type[j] == mjWRAP_SPHERE) {
	m->body_simple[m->geom_bodyid[objid]] = 0;
	}
	}
	}

	// set dof_simplenum
	int count = 0;
	for (int i=nv-1; i >= 0; i--) {
	if (m->body_simple[m->dof_bodyid[i]]) {
	count++; // increment counter
	} else {
	count = 0; // reset
	}
	m->dof_simplenum[i] = count;
	}

	// compute nC
	int nOD = 0; // number of off-diagonal (non-simple) parent dofs
	for (int i=0; i < nv; i++) {
	// count ancestor (off-diagonal) dofs
	if (!m->dof_simplenum[i]) {
	int j = i;
	while (j >= 0) {
	if (j != i) nOD++;
	j = m->dof_parentid[j];
	}
	}
	}
	m->nC = nC = nOD + nv;
	}



	// save the current state
	template <class T>
	void mjCModel::SaveState(const std::string& state_name, const T* qpos, const T* qvel, const T* act,
	const T* ctrl, const T* mpos, const T* mquat) {
	for (auto joint : joints_) {
	if (joint->qposadr_ < -1 \|\| joint->dofadr_ < -1) {
	throw mjCError(nullptr, "SaveState: joint %s has invalid address", joint->name.c_str());
	}
	if (qpos && joint->qposadr_ != -1) {
	mjuu_copyvec(joint->qpos(state_name), qpos + joint->qposadr_, joint->nq());
	}
	if (qvel && joint->dofadr_ != -1) {
	mjuu_copyvec(joint->qvel(state_name), qvel + joint->dofadr_, joint->nv());
	}
	}

	for (unsigned int i=0; i < actuators_.size(); i++) {
	auto actuator = actuators_[i];
	if (actuator->actadr_ != -1 && actuator->actdim_ != -1 && act) {
	actuator->act(state_name).assign(actuator->actdim_, 0);
	mjuu_copyvec(actuator->act(state_name).data(), act + actuator->actadr_, actuator->actdim_);
	}
	if (ctrl) {
	actuator->ctrl(state_name) = ctrl[i];
	}
	}

	for (auto body : bodies_) {
	if (!body->spec.mocap \|\| body->mocapid == -1) {
	continue;
	}
	if (mpos) {
	mjuu_copyvec(body->mpos(state_name), mpos + 3*body->mocapid, 3);
	}
	if (mquat) {
	mjuu_copyvec(body->mquat(state_name), mquat + 4*body->mocapid, 4);
	}
	}
	}



	// clear existing data
	void mjCModel::MakeData(const mjModel* m, mjData** dest) {
	mj_makeRawData(dest, m);
	mjData* d = *dest;
	if (d) {
	mj_initPlugin(m, d);
	mj_resetData(m, d);
	}
	}



	// restore the previous state
	template <class T>
	void mjCModel::RestoreState(const std::string& state_name, const mjtNum* pos0,
	const mjtNum* mpos0, const mjtNum* mquat0, T* qpos,
	T* qvel, T* act, T* ctrl, T* mpos, T* mquat) {
	for (auto joint : joints_) {
	if (qpos) {
	if (mjuu_defined(joint->qpos(state_name)[0])) {
	mjuu_copyvec(qpos + joint->qposadr_, joint->qpos(state_name), joint->nq());
	} else {
	mjuu_copyvec(qpos + joint->qposadr_, pos0 + joint->qposadr_, joint->nq());
	}
	}
	if (mjuu_defined(joint->qvel(state_name)[0]) && qvel) {
	mjuu_copyvec(qvel + joint->dofadr_, joint->qvel(state_name), joint->nv());
	}
	}

	// restore act
	for (unsigned int i=0; i < actuators_.size(); i++) {
	auto actuator = actuators_[i];
	if (!actuator->act(state_name).empty() && mjuu_defined(actuator->act(state_name)[0]) && act) {
	mjuu_copyvec(act + actuator->actadr_, actuator->act(state_name).data(), actuator->actdim_);
	}
	if (ctrl) {
	ctrl[i] = mjuu_defined(actuator->ctrl(state_name)) ? actuator->ctrl(state_name) : 0;
	}
	}

	for (unsigned int i=0; i < bodies_.size(); i++) {
	auto body = bodies_[i];
	if (!body->spec.mocap) {
	continue;
	}
	if (mpos) {
	if (mjuu_defined(body->mpos(state_name)[0])) {
	mjuu_copyvec(mpos + 3*body->mocapid, body->mpos(state_name), 3);
	} else {
	mjuu_copyvec(mpos + 3body->mocapid, mpos0 + 3i, 3);
	}
	}
	if (mquat) {
	if (mjuu_defined(body->mquat(state_name)[0])) {
	mjuu_copyvec(mquat + 4*body->mocapid, body->mquat(state_name), 4);
	} else {
	mjuu_copyvec(mquat + 4body->mocapid, mquat0 + 4i, 4);
	}
	}
	}
	}

	// force explicit instantiations
	template void mjCModel::SaveState<mjtNum>(
	const std::string& name, const mjtNum* qpos, const mjtNum* qvel, const mjtNum* act,
	const mjtNum* ctrl, const mjtNum* mpos, const mjtNum* mquat);

	template void mjCModel::RestoreState<mjtNum>(
	const std::string& name, const mjtNum* qpos0, const mjtNum* mpos0, const mjtNum* mquat0,
	mjtNum* qpos, mjtNum* qvel, mjtNum* act, mjtNum* ctrl, mjtNum* mpos, mjtNum* mquat);



	// resolve keyframe references
	void mjCModel::StoreKeyframes(mjCModel* dest) {
	if (this != dest && !key_pending_.empty()) {
	mju_warning(
	"Child model has pending keyframes. They will not be namespaced correctly. "
	"To prevent this, compile the child model before attaching it again.");
	}

	// do not change compilation quantities in case the user wants to recompile preserving the state
	if (!compiled) {
	SaveDofOffsets(/computesize=/true);
	ComputeReference();
	}

	// save keyframe info and resize keyframes
	for (auto& key : keys_) {
	mjKeyInfo info;
	info.name = prefix + key->name + suffix;
	info.time = key->spec.time;
	info.qpos = !key->spec_qpos_.empty();
	info.qvel = !key->spec_qvel_.empty();
	info.act = !key->spec_act_.empty();
	info.ctrl = !key->spec_ctrl_.empty();
	info.mpos = !key->spec_mpos_.empty();
	info.mquat = !key->spec_mquat_.empty();
	dest->key_pending_.push_back(info);
	if (!key->spec_qpos_.empty() && key->spec_qpos_.size() != nq) {
	throw mjCError(nullptr, "Keyframe '%s' has invalid qpos size, got %d, should be %d",
	key->name.c_str(), key->spec_qpos_.size(), nq);
	}
	if (!key->spec_qvel_.empty() && key->spec_qvel_.size() != nv) {
	throw mjCError(nullptr, "Keyframe %s has invalid qvel size, got %d, should be %d",
	key->name.c_str(), key->spec_qvel_.size(), nv);
	}
	if (!key->spec_act_.empty() && key->spec_act_.size() != na) {
	throw mjCError(nullptr, "Keyframe %s has invalid act size, got %d, should be %d",
	key->name.c_str(), key->spec_act_.size(), na);
	}
	if (!key->spec_ctrl_.empty() && key->spec_ctrl_.size() != nu) {
	throw mjCError(nullptr, "Keyframe %s has invalid ctrl size, got %d, should be %d",
	key->name.c_str(), key->spec_ctrl_.size(), nu);
	}
	if (!key->spec_mpos_.empty() && key->spec_mpos_.size() != 3*nmocap) {
	throw mjCError(nullptr, "Keyframe %s has invalid mpos size, got %d, should be %d",
	key->name.c_str(), key->spec_mpos_.size(), 3*nmocap);
	}
	if (!key->spec_mquat_.empty() && key->spec_mquat_.size() != 4*nmocap) {
	throw mjCError(nullptr, "Keyframe %s has invalid mquat size, got %d, should be %d",
	key->name.c_str(), key->spec_mquat_.size(), 4*nmocap);
	}
	SaveState(info.name, key->spec_qpos_.data(), key->spec_qvel_.data(),
	key->spec_act_.data(), key->spec_ctrl_.data(),
	key->spec_mpos_.data(), key->spec_mquat_.data());
	}

	if (!compiled) {
	nq = nv = na = nu = nmocap = 0;
	}
	}



	//------------------------------- FUSE STATIC ------------------------------------------------------

	template <class T>
	static void makelistid(std::vector<T>& dest, std::vector<T>& source) {
	for (int i=0; i < source.size(); i++) {
	source[i]->id = (int)dest.size();
	dest.push_back(source[i]);
	}
	}

	// change frame to parent body
	static void changeframe(double childpos[3], double childquat[4],
	const double bodypos[3], const double bodyquat[4]) {
	double pos[3], quat[4];
	mjuu_copyvec(pos, bodypos, 3);
	mjuu_copyvec(quat, bodyquat, 4);
	mjuu_frameaccum(pos, quat, childpos, childquat);
	mjuu_copyvec(childpos, pos, 3);
	mjuu_copyvec(childquat, quat, 4);
	}



	// reindex elements during fuse
	void mjCModel::FuseReindex(mjCBody* body) {
	// set parentid and weldid of children
	for (int i=0; i < body->bodies.size(); i++) {
	body->bodies[i]->parent = body;
	body->bodies[i]->weldid = (!body->bodies[i]->joints.empty() ?
	body->bodies[i]->id : body->weldid);
	}

	makelistid(joints_, body->joints);
	makelistid(geoms_, body->geoms);
	makelistid(sites_, body->sites);

	// process children recursively
	for (int i=0; i < body->bodies.size(); i++) {
	FuseReindex(body->bodies[i]);
	}
	}



	template <class T>
	void mjCModel::ReassignChild(std::vector<T>& dest, std::vector<T>& list,
	mjCBody* parent, mjCBody* body) {
	for (int j=0; j < list.size(); j++) {
	// assign
	list[j]->body = parent;
	dest.push_back(list[j]);

	// change frame
	changeframe(list[j]->pos, list[j]->quat, body->pos, body->quat);
	}
	list.clear();
	}



	template <class T>
	void mjCModel::ResolveReferences(std::vector<T>& list, mjCBody body) {
	for (auto& item : list) {
	item->CopyFromSpec();
	item->ResolveReferences(this);
	}
	}



	template <>
	void mjCModel::ResolveReferences(std::vector<mjCSensor>& list, mjCBody body) {
	for (auto& item : list) {
	item->CopyFromSpec();
	item->ResolveReferences(this);
	}
	for (mjCSensor* sensor : list) {
	if (sensor->objtype == mjOBJ_SITE &&
	(sensor->type == mjSENS_FORCE \|\| sensor->type == mjSENS_TORQUE) &&
	static_cast<mjCSite*>(sensor->obj)->body == body) {
	throw mjCError(sensor, "cannot fuse a body used by a force/torque sensor");
	}
	}
	}



	// fuse static bodies with their parent
	void mjCModel::FuseStatic(void) {
	for (int i=1; i < bodies_.size(); i++) {
	// check if the body can be fused
	if (!bodies_[i]->name.empty()) {
	ids[mjOBJ_BODY].erase(bodies_[i]->name);

	// try to resolve references without the name of this body, if it fails, skip
	try {
	ResolveReferences(cameras_);
	ResolveReferences(lights_);
	ResolveReferences(skins_);
	ResolveReferences(pairs_);
	ResolveReferences(excludes_);
	ResolveReferences(equalities_);
	ResolveReferences(tendons_);
	ResolveReferences(actuators_);
	ResolveReferences(sensors_, bodies_[i]);
	ResolveReferences(tuples_);
	} catch (mjCError err) {
	ids[mjOBJ_BODY].insert({bodies_[i]->name, i});
	continue;
	}

	// put body back the body name in the map
	ids[mjOBJ_BODY].insert({bodies_[i]->name, i});
	}

	// get body and parent
	mjCBody* body = bodies_[i];
	mjCBody* par = body->parent;

	// skip if body has joints or mocap
	if (!body->joints.empty() \|\| body->mocap) {
	continue;
	}

	//------------- add mass and inertia (if parent not world)
	if (body->parent && body->parent->name != "world" && body->mass >= mjMINVAL) {
	par->AccumulateInertia(body);
	}

	//------------- replace body with its children in parent body list

	// change frames of child bodies
	for (int j=0; j < body->bodies.size(); j++)
	changeframe(body->bodies[j]->pos, body->bodies[j]->quat,
	body->pos, body->quat);

	// find body in parent list, insert children before it
	bool found = false;
	for (auto iter=par->bodies.begin(); iter != par->bodies.end(); iter++) {
	if (*iter == body) {
	par->bodies.insert(iter, body->bodies.begin(), body->bodies.end());
	found = true;
	break;
	}
	}
	if (!found) {
	mju_error("Internal error: FuseStatic: body not found");
	}

	// find body in parent list, erase
	found = false;
	for (auto iter=par->bodies.begin(); iter != par->bodies.end(); iter++) {
	if (*iter == body) {
	par->bodies.erase(iter);
	found = true;
	break;
	}
	}
	if (!found) {
	mju_error("Internal error: FuseStatic: body not found");
	}

	//------------- assign geoms and sites to parent, change frames

	ReassignChild(par->geoms, body->geoms, par, body);
	ReassignChild(par->sites, body->sites, par, body);

	//------------- remove from global body list, reduce global counts

	// find in global and erase
	found = false;
	for (auto iter=bodies_.begin(); iter != bodies_.end(); iter++) {
	if (*iter == body) {
	bodies_.erase(iter);
	found = true;
	break;
	}
	}
	if (!found) {
	mju_error("Internal error: FuseStatic: body not found");
	}

	// reduce counts
	nbody--;
	nnames -= ((int)body->name.length() + 1);

	//------------- re-index bodies, joints, geoms, sites

	// body ids
	for (int j=0; j < bodies_.size(); j++) {
	bodies_[j]->id = j;
	}

	// everything else
	joints_.clear();
	geoms_.clear();
	sites_.clear();
	FuseReindex(bodies_[0]);

	// recompute parent contype, conaffinity, and margin
	par->contype = par->conaffinity = 0;
	par->margin = 0;
	for (const auto& geom : par->geoms) {
	par->contype \|= geom->contype;
	par->conaffinity \|= geom->conaffinity;
	par->margin = std::max(par->margin, geom->margin);
	}

	// recompute BVH
	int nbvhfuse = body->tree.Nbvh() + par->tree.Nbvh();
	par->ComputeBVH();
	nbvhstatic += par->tree.Nbvh() - nbvhfuse;
	nbvh += par->tree.Nbvh() - nbvhfuse;

	//------------- delete body (without deleting children)

	// remove body name from map
	if (!body->name.empty()) {
	ids[mjOBJ_BODY].erase(body->name);
	}

	// delete allocation
	body->bodies.clear();
	delete body;

	// check index i again (we have a new body at this index)
	i--;
	}

	// remove empty names
	ProcessList_(ids, bodies_, mjOBJ_BODY, /checkrepeat=/true);
	}



	//------------------------------- COMPILER ---------------------------------------------------------

	// signature comparisons
	static int comparePair(mjCPair* el1, mjCPair* el2) {
	return el1->GetSignature() < el2->GetSignature();
	}
	static int compareBodyPair(mjCBodyPair* el1, mjCBodyPair* el2) {
	return el1->GetSignature() < el2->GetSignature();
	}


	// reassign ids
	template <class T>
	static void reassignid(vector<T*>& list) {
	for (int i=0; i < (int)list.size(); i++) {
	list[i]->id = i;
	}
	}



	// set object ids, check for repeated names
	void mjCModel::ProcessLists(bool checkrepeat) {
	for (int i = 0; i < mjNOBJECT; i++) {
	if (i != mjOBJ_XBODY && object_lists_[i]) {
	ids[i].clear();
	ProcessList_(ids, *object_lists_[i], (mjtObj) i, checkrepeat);
	}
	}

	// check repeated names in meta elements
	ProcessList_(ids, frames_, mjOBJ_FRAME, checkrepeat);
	}



	// set ids, check for repeated names
	template <class T>
	void mjCModel::ProcessList_(mjListKeyMap& ids, vector<T*>& list,
	mjtObj type, bool checkrepeat) {
	// assign ids for regular elements
	if (type < mjNOBJECT) {
	for (size_t i=0; i < list.size(); i++) {
	// check for incompatible id setting; SHOULD NOT OCCUR
	if (list[i]->id != -1 && list[i]->id != i) {
	throw mjCError(list[i], "incompatible id in %s array, position %d", mju_type2Str(type), i);
	}

	// id equals position in array
	list[i]->id = i;

	// add to ids map
	ids[type][list[i]->name] = i;
	}
	}

	// check for repeated names
	if (checkrepeat) {
	CheckRepeat(type);
	}
	}



	// check for repeated names in list
	void mjCModel::CheckRepeat(mjtObj type) {
	std::vector<mjCBase> list = nullptr;
	if (type < mjNOBJECT) {
	list = object_lists_[type];
	} else if (type == mjOBJ_FRAME) {
	list = (std::vector<mjCBase>) &frames_;
	}

	// created vectors with all names
	vector<string> allnames;
	for (size_t i=0; i < list->size(); i++) {
	if (!(*list)[i]->name.empty()) {
	allnames.push_back((*list)[i]->name);
	}
	}

	// sort and check for duplicates
	if (allnames.size() > 1) {
	std::sort(allnames.begin(), allnames.end());
	auto adjacent = std::adjacent_find(allnames.begin(), allnames.end());
	if (adjacent != allnames.end()) {
	string msg = "repeated name '" + *adjacent + "' in " + mju_type2Str(type);
	throw mjCError(nullptr, "%s", msg.c_str());
	}
	}
	}



	// error handler for low-level engine
	constexpr int kErrorBufferSize = 500;
	static thread_local std::jmp_buf error_jmp_buf;
	static thread_local char errortext[kErrorBufferSize] = "";
	static void errorhandler(const char* msg) {
	mju::strcpy_arr(errortext, msg);
	std::longjmp(error_jmp_buf, 1);
	}


	// warning handler for low-level engine
	static thread_local char warningtext[kErrorBufferSize] = ""; // top-level warning buffer
	static thread_local std::string* local_warningtext_ptr = nullptr; // sub-thread warning buffer
	static void warninghandler(const char* msg) {
	if (local_warningtext_ptr) {
	*local_warningtext_ptr = msg;
	} else {
	mju::strcpy_arr(warningtext, msg);
	}
	}


	// compiler
	mjModel* mjCModel::Compile(const mjVFS* vfs, mjModel** m) {
	if (compiled) {
	Clear();
	}

	CopyFromSpec();

	// The volatile keyword is necessary to prevent a possible memory leak due to
	// an interaction between longjmp and compiler optimization. Specifically, at
	// the point where the setjmp takes places, these pointers have never been
	// reassigned from their nullptr initialization. Without the volatile keyword,
	// the compiler is free to assume that these pointers remain nullptr when the
	// setjmp returns, and therefore to pass nullptr directly to the
	// mj_deleteModel and mj_deleteData calls in the subsequent catch block,
	// without ever reading the actual pointer values.
	mjModel* volatile model = (m && m) ? m : nullptr;
	mjData* volatile data = nullptr;

	// save error and warning handlers
	void (save_error)(const char) = _mjPRIVATE__get_tls_error_fn();
	void (save_warning)(const char) = _mjPRIVATE__get_tls_warning_fn();

	// install error and warning handlers, clear error and warning
	_mjPRIVATE__set_tls_error_fn(errorhandler);
	_mjPRIVATE__set_tls_warning_fn(warninghandler);

	errInfo = mjCError();
	warningtext[0] = 0;

	try {
	if (attached_) {
	throw mjCError(0, "cannot compile child spec if attached by reference to a parent spec");
	}
	if (setjmp(error_jmp_buf) != 0) {
	// TryCompile resulted in an mju_error which was converted to a longjmp.
	std::string error_msg = errortext;
	// also include the last warning that was issued. this is useful for
	// warnings that came out of plugin implementations.
	if (warningtext[0]) {
	error_msg += "\n";
	error_msg += warningtext;
	}
	throw mjCError(0, "engine error: %s", error_msg.c_str());
	}
	TryCompile(const_cast<mjModel>(&model), const_cast<mjData**>(&data), vfs);
	} catch (mjCError err) {
	// deallocate everything allocated in Compile
	mj_deleteModel(model);
	mj_deleteData(data);
	Clear();

	// save error info
	errInfo = err;

	// restore handler, return 0
	_mjPRIVATE__set_tls_error_fn(save_error);
	_mjPRIVATE__set_tls_warning_fn(save_warning);
	return nullptr;
	}

	// restore error handler, mark as compiled, return mjModel
	_mjPRIVATE__set_tls_error_fn(save_error);
	_mjPRIVATE__set_tls_warning_fn(save_warning);
	compiled = true;
	return model;
	}



	// mesh compilation function to be used in threads
	void CompileMesh(mjCMesh* mesh, const mjVFS* vfs, std::exception_ptr& exception,
	std::mutex& exception_mutex, std::string* warningtext) {
	// set warning text buffer to this local thread
	local_warningtext_ptr = warningtext;
	auto previous_handler = _mjPRIVATE__get_tls_warning_fn();
	_mjPRIVATE__set_tls_warning_fn(warninghandler);

	// compile the mesh, catch exception to be rethrown later
	try {
	mesh->Compile(vfs);
	} catch (...) {
	std::lock_guard<std::mutex> lock(exception_mutex);
	if (!exception) {
	exception = std::current_exception();
	}
	}

	// restore warning handler to top-level
	_mjPRIVATE__set_tls_warning_fn(previous_handler);
	local_warningtext_ptr = nullptr;
	}



	// multi-threaded mesh compilation
	void mjCModel::CompileMeshes(const mjVFS* vfs) {
	std::vector<std::thread> threads;
	int nmesh = meshes_.size();
	int hardware_threads = std::thread::hardware_concurrency() / 2;
	int maxthread = std::min(nmesh, std::min(kMaxCompilerThreads, hardware_threads));
	int nthread = std::max(1, maxthread);

	threads.reserve(nthread);

	// holds an exception thrown by a worker thread
	std::exception_ptr exception;
	std::mutex except_mutex;

	std::atomic_int next_mesh = 0;
	std::vector<std::string> mesh_warningtext(nmesh);
	for (int i = 0; i < nthread; ++i) {
	threads.emplace_back([&] {
	for (int meshid = next_mesh++; meshid < nmesh; meshid = next_mesh++) {
	auto& mesh = meshes_[meshid];
	CompileMesh(mesh, vfs, exception, except_mutex,
	&mesh_warningtext[meshid]);
	}
	});
	}

	// join threads
	for (auto& thread : threads) {
	if (thread.joinable()) {
	thread.join();
	}
	}

	// concatenate all warnings from threads, copy into warningtext
	std::string concatenated_warnings;
	bool has_warning = false;
	for (int i = 0; i < nmesh; i++) {
	if (!mesh_warningtext[i].empty()) {
	if (has_warning) {
	concatenated_warnings += "\n";
	}
	concatenated_warnings += mesh_warningtext[i];
	has_warning = true;
	}
	}
	mju::strcpy_arr(warningtext, concatenated_warnings.c_str());

	// if exception was caught, rethrow it
	if (exception) {
	std::rethrow_exception(exception);
	}
	}



	// compute qpos0
	void mjCModel::ComputeReference() {
	int b = 0;
	qpos0.resize(nq);
	body_pos0.resize(3*bodies_.size());
	body_quat0.resize(4*bodies_.size());
	for (auto body : bodies_) {
	mjuu_copyvec(body_pos0.data()+3*b, body->spec.pos, 3);
	mjuu_copyvec(body_quat0.data()+4*b, body->spec.quat, 4);
	for (auto joint : body->joints) {
	switch (joint->type) {
	case mjJNT_FREE:
	mjuu_copyvec(qpos0.data()+joint->qposadr_, body->spec.pos, 3);
	mjuu_copyvec(qpos0.data()+joint->qposadr_+3, body->spec.quat, 4);
	break;

	case mjJNT_BALL:
	mjuu_setvec(qpos0.data()+joint->qposadr_, 1, 0, 0, 0);
	break;

	case mjJNT_SLIDE:
	case mjJNT_HINGE:
	qpos0[joint->qposadr_] = (mjtNum)joint->spec.ref;
	break;

	default:
	throw mjCError(joint, "unknown joint type");
	}
	}
	b++;
	}
	}



	// resizes a keyframe, filling in missing values
	void mjCModel::ResizeKeyframe(mjCKey* key, const mjtNum* qpos0_,
	const mjtNum* bpos, const mjtNum* bquat) {
	if (!key->spec_qpos_.empty()) {
	int nq0 = key->spec_qpos_.size();
	key->spec_qpos_.resize(nq);
	for (int i=nq0; i < nq; i++) {
	key->spec_qpos_[i] = (double)qpos0_[i];
	}
	}
	if (!key->spec_qvel_.empty()) {
	key->spec_qvel_.resize(nv);
	}
	if (!key->spec_act_.empty()) {
	key->spec_act_.resize(na);
	}
	if (!key->spec_ctrl_.empty()) {
	key->spec_ctrl_.resize(nu);
	}
	if (!key->spec_mpos_.empty()) {
	int nmocap0 = key->spec_mpos_.size() / 3;
	key->spec_mpos_.resize(3*nmocap);
	for (unsigned int j = 0; j < bodies_.size(); j++) {
	if (bodies_[j]->mocapid < nmocap0) {
	continue;
	}
	int i = bodies_[j]->mocapid;
	key->spec_mpos_[3i+0] = (double)bpos[3j+0];
	key->spec_mpos_[3i+1] = (double)bpos[3j+1];
	key->spec_mpos_[3i+2] = (double)bpos[3j+2];
	}
	}
	if (!key->spec_mquat_.empty()) {
	int nmocap0 = key->spec_mquat_.size() / 4;
	key->spec_mquat_.resize(4*nmocap);
	for (unsigned int j = 0; j < bodies_.size(); j++) {
	if (bodies_[j]->mocapid < nmocap0) {
	continue;
	}
	int i = bodies_[j]->mocapid;
	key->spec_mquat_[4i+0] = (double)bquat[4j+0];
	key->spec_mquat_[4i+1] = (double)bquat[4j+1];
	key->spec_mquat_[4i+2] = (double)bquat[4j+2];
	key->spec_mquat_[4i+3] = (double)bquat[4j+3];
	}
	}
	}

	// convert pending keyframes info to actual keyframes
	void mjCModel::ResolveKeyframes(const mjModel* m) {
	// store dof offsets in joints and actuators
	SaveDofOffsets();

	// create new keyframes, fill in missing default values
	for (const auto& info : key_pending_) {
	mjCKey* key = (mjCKey*)FindObject(mjOBJ_KEY, info.name);
	key->name = info.name;
	key->spec.time = info.time;
	if (info.qpos) key->spec_qpos_.assign(nq, 0);
	if (info.qvel) key->spec_qvel_.assign(nv, 0);
	if (info.act) key->spec_act_.assign(na, 0);
	if (info.ctrl) key->spec_ctrl_.assign(nu, 0);
	if (info.mpos) key->spec_mpos_.assign(3*nmocap, 0);
	if (info.mquat) key->spec_mquat_.assign(4*nmocap, 0);
	RestoreState(info.name, m->qpos0, m->body_pos, m->body_quat,
	key->spec_qpos_.data(), key->spec_qvel_.data(),
	key->spec_act_.data(), key->spec_ctrl_.data(),
	key->spec_mpos_.data(), key->spec_mquat_.data());
	}

	// the attached keyframes have been copied into the model
	key_pending_.clear();
	}



	void mjCModel::TryCompile(mjModel& m, mjData& d, const mjVFS* vfs) {
	// check if nan test works
	double test = mjNAN;
	if (mjuu_defined(test)) {
	throw mjCError(0, "NaN test does not work for present compiler/options");
	}

	// check for joints in world body
	if (!bodies_[0]->joints.empty()) {
	throw mjCError(0, "joint found in world body");
	}

	// check for too many body+flex
	if (bodies_.size()+flexes_.size() >= 65534) {
	throw mjCError(0, "number of bodies plus flexes must be less than 65534");
	}

	// append directory separator
	if (!meshdir_.empty()) {
	int n = meshdir_.length();
	if (meshdir_[n-1] != '/' && meshdir_[n-1] != '\\') {
	meshdir_ += '/';
	}
	}
	if (!texturedir_.empty()) {
	int n = texturedir_.length();
	if (texturedir_[n-1] != '/' && texturedir_[n-1] != '\\') {
	texturedir_ += '/';
	}
	}

	// add missing keyframes
	for (int i=keys_.size(); i < nkey; i++) {
	AddKey();
	}

	// clear subtreedofs
	for (int i=0; i < bodies_.size(); i++) {
	bodies_[i]->subtreedofs = 0;
	}

	// initialize spec signature (needed if the user changed sensor or joint types)
	spec.element->signature = Signature();

	// fill missing names and check that they are all filled
	for (const auto& asset : meshes_) asset->CopyFromSpec();
	for (const auto& asset : skins_) asset->CopyFromSpec();
	for (const auto& asset : hfields_) asset->CopyFromSpec();
	for (const auto& asset : textures_) asset->CopyFromSpec();
	CheckEmptyNames();

	// create pending keyframes
	for (const auto& info : key_pending_) {
	mjCKey* key = AddKey();
	key->name = info.name;
	}

	// set object ids, check for repeated names
	ProcessLists();

	// delete visual assets
	if (compiler.discardvisual) {
	DeleteAll(materials_);
	DeleteTexcoord(flexes_);
	DeleteTexcoord(meshes_);
	DeleteAll(textures_);
	}

	// map names to asset references
	IndexAssets(/discard=/false);

	// mark meshes that need convex hull
	for (int i=0; i < geoms_.size(); i++) {
	if (geoms_[i]->mesh &&
	(geoms_[i]->spec.type == mjGEOM_MESH \|\| geoms_[i]->spec.type == mjGEOM_SDF) &&
	(geoms_[i]->spec.contype \|\| geoms_[i]->spec.conaffinity \|\|
	geoms_[i]->mesh->spec.inertia == mjMESH_INERTIA_CONVEX)) {
	geoms_[i]->mesh->SetNeedHull(true);
	}
	}

	// automatically set nuser fields
	SetNuser();

	// compile meshes (needed for geom compilation)
	if (!compiler.usethread && meshes_.size() > 1) {
	// multi-threaded mesh compile
	CompileMeshes(vfs);
	} else {
	// single-threaded mesh compile
	for (int i=0; i < meshes_.size(); i++) {
	meshes_[i]->Compile(vfs);
	}
	}

	// compile objects in kinematic tree
	for (int i=0; i < bodies_.size(); i++) {
	bodies_[i]->Compile(); // also compiles joints, geoms, sites, cameras, lights, frames
	}

	// fuse static if enabled
	if (compiler.fusestatic) {
	FuseStatic();
	for (int i=0; i < lights_.size(); i++) {
	lights_[i]->Compile();
	}
	for (int i=0; i < cameras_.size(); i++) {
	cameras_[i]->Compile();
	}
	}

	// compile all other objects except for keyframes
	for (auto flex : flexes_) flex->Compile(vfs);
	for (auto skin : skins_) skin->Compile(vfs);
	for (auto hfield : hfields_) hfield->Compile(vfs);
	for (auto texture : textures_) texture->Compile(vfs);
	for (auto material : materials_) material->Compile();
	for (auto pair : pairs_) pair->Compile();
	for (auto exclude : excludes_) exclude->Compile();
	for (auto equality : equalities_) equality->Compile();
	for (auto tendon : tendons_) tendon->Compile();
	for (auto actuator : actuators_) actuator->Compile();
	for (auto sensor : sensors_) sensor->Compile();
	for (auto numeric : numerics_) numeric->Compile();
	for (auto text : texts_) text->Compile();
	for (auto tuple : tuples_) tuple->Compile();
	for (auto plugin : plugins_) plugin->Compile();

	// compile def: to enforce userdata length for writer
	for (mjCDef* def : defaults_) {
	def->Compile(this);
	}

	// sort pair, exclude in increasing signature order; reassign ids
	std::stable_sort(pairs_.begin(), pairs_.end(), comparePair);
	std::stable_sort(excludes_.begin(), excludes_.end(), compareBodyPair);
	reassignid(pairs_);
	reassignid(excludes_);

	// resolve asset references, compute sizes
	IndexAssets(compiler.discardvisual);
	SetSizes();

	// set nmocap and body.mocapid
	for (mjCBody* body : bodies_) {
	if (body->mocap) {
	body->mocapid = nmocap;
	nmocap++;
	} else {
	body->mocapid = -1;
	}
	}

	// check mass and inertia of moving bodies
	for (int i=1; i < bodies_.size(); i++) {
	if (!bodies_[i]->joints.empty() && !CheckBodyMassInertia(bodies_[i])) {
	throw mjCError(bodies_[i], "mass and inertia of moving bodies must be larger than mjMINVAL");
	}
	}

	// create low-level model
	mj_makeModel(&m,
	nq, nv, nu, na, nbody, nbvh, nbvhstatic, nbvhdynamic, noct, njnt, ngeom, nsite,
	ncam, nlight, nflex, nflexnode, nflexvert, nflexedge, nflexelem,
	nflexelemdata, nflexelemedge, nflexshelldata, nflexevpair, nflextexcoord,
	nmesh, nmeshvert, nmeshnormal, nmeshtexcoord, nmeshface, nmeshgraph, nmeshpoly,
	nmeshpolyvert, nmeshpolymap, nskin, nskinvert, nskintexvert, nskinface, nskinbone,
	nskinbonevert, nhfield, nhfielddata, ntex, ntexdata, nmat, npair, nexclude,
	neq, ntendon, nwrap, nsensor, nnumeric, nnumericdata, ntext, ntextdata,
	ntuple, ntupledata, nkey, nmocap, nplugin, npluginattr,
	nuser_body, nuser_jnt, nuser_geom, nuser_site, nuser_cam,
	nuser_tendon, nuser_actuator, nuser_sensor, nnames, npaths);
	if (!m) {
	throw mjCError(0, "could not create mjModel");
	}

	// copy everything into low-level model
	m->opt = option;
	m->vis = visual;
	CopyNames(m);
	CopyPaths(m);
	CopyTree(m);
	CopyPlugins(m);

	// keyframe compilation needs access to nq, nv, na, nmocap, qpos0
	ResolveKeyframes(m);

	for (int i=0; i < keys_.size(); i++) {
	keys_[i]->Compile(m);
	}

	// copy objects outsite kinematic tree (including keyframes)
	CopyObjects(m);

	// finalize simple bodies/dofs including tendon information
	FinalizeSimple(m);

	// compute non-zeros in actuator_moment
	m->nJmom = nJmom = CountNJmom(m);

	// scale mass
	if (compiler.settotalmass > 0) {
	mj_setTotalmass(m, compiler.settotalmass);
	}

	// set arena size into m->narena
	if (memory != -1) {
	// memory size is user-specified in bytes
	m->narena = memory;
	} else {
	const int nconmax = m->nconmax == -1 ? 100 : m->nconmax;
	const int njmax = m->njmax == -1 ? 500 : m->njmax;
	if (nstack != -1) {
	// (legacy) stack size is user-specified as multiple of sizeof(mjtNum)
	m->narena = sizeof(mjtNum) * nstack;
	} else {
	// use a conservative heuristic if neither memory nor nstack is specified in XML
	m->narena = sizeof(mjtNum) * static_cast<size_t>(mjMAX(
	1000,
	5(njmax + m->neq + m->nv)(njmax + m->neq + m->nv) +
	20*(m->nq + m->nv + m->nu + m->na + m->nbody + m->njnt +
	m->ngeom + m->nsite + m->neq + m->ntendon + m->nwrap)));
	}

	// add an arena space equal to memory footprint prior to the introduction of the arena
	const std::size_t arena_bytes = (
	nconmax * sizeof(mjContact) +
	njmax * (8 * sizeof(int) + 14 * sizeof(mjtNum)) +
	m->nv * (3 * sizeof(int)) +
	njmax * m->nv * (2 * sizeof(int) + 2 * sizeof(mjtNum)) +
	njmax * njmax * (sizeof(int) + sizeof(mjtNum)));
	m->narena += arena_bytes;

	// round up to the nearest megabyte
	constexpr std::size_t kMegabyte = 1 << 20;
	std::size_t nstack_mb = m->narena / kMegabyte;
	std::size_t residual_mb = m->narena % kMegabyte ? 1 : 0;
	m->narena = kMegabyte * (nstack_mb + residual_mb);
	}

	// create data
	int disableflags = m->opt.disableflags;
	m->opt.disableflags \|= mjDSBL_CONTACT;
	mj_makeRawData(&d, m);
	if (!d) {
	// m will be deleted by the catch statement in mjCModel::Compile()
	throw mjCError(0, "could not create mjData");
	}
	mj_resetData(m, d);

	// normalize keyframe quaternions
	for (int i=0; i < m->nkey; i++) {
	mj_normalizeQuat(m, m->key_qpos+i*m->nq);
	}

	// set constant fields
	mj_setConst(m, d);

	// automatic spring-damper adjustment
	AutoSpringDamper(m);

	// actuator lengthrange computation
	LengthRange(m, d);

	// save automatically-computed statistics, to disambiguate when saving
	extent_auto = m->stat.extent;
	meaninertia_auto = m->stat.meaninertia;
	meanmass_auto = m->stat.meanmass;
	meansize_auto = m->stat.meansize;
	mjuu_copyvec(center_auto, m->stat.center, 3);

	// override model statistics if defined by user
	if (mjuu_defined(stat.extent)) m->stat.extent = (mjtNum)stat.extent;
	if (mjuu_defined(stat.meaninertia)) m->stat.meaninertia = (mjtNum)stat.meaninertia;
	if (mjuu_defined(stat.meanmass)) m->stat.meanmass = (mjtNum)stat.meanmass;
	if (mjuu_defined(stat.meansize)) m->stat.meansize = (mjtNum)stat.meansize;
	if (mjuu_defined(stat.center[0])) mjuu_copyvec(m->stat.center, stat.center, 3);

	// assert that model has valid references
	const char* validationerr = mj_validateReferences(m);
	if (validationerr) { // SHOULD NOT OCCUR
	// m and d will be deleted by the catch statement in mjCModel::Compile()
	throw mjCError(0, "%s", validationerr);
	}

	// delete partial mjData (no plugins), make a complete one
	mj_deleteData(d);
	d = nullptr;
	d = mj_makeData(m);
	if (!d) {
	// m will be deleted by the catch statement in mjCModel::Compile()
	throw mjCError(0, "could not create mjData");
	}

	// test forward simulation
	mj_step(m, d);

	// delete data
	mj_deleteData(d);
	m->opt.disableflags = disableflags;
	d = nullptr;

	// pass warning back
	if (warningtext[0]) {
	mju::strcpy_arr(errInfo.message, warningtext);
	errInfo.warning = true;
	}

	// save signature
	m->signature = Signature();

	// special cases that are not caused by user edits
	if (compiler.fusestatic \|\| compiler.discardvisual \|\|
	!pairs_.empty() \|\| !excludes_.empty()) {
	spec.element->signature = m->signature;
	}

	// check that the signature matches the spec
	if (m->signature != spec.element->signature) {
	throw mjCError(0, "signature mismatch"); // SHOULD NOT OCCUR
	}
	}



	std::string mjCModel::PrintTree(const mjCBody* body, std::string indent) {
	std::string tree;
	tree += indent + "<body>\n";
	indent += " ";
	for (const auto& joint : body->joints) {
	tree += indent + "<joint>" + std::to_string(joint->nq()) + "</joint>\n";
	}
	for (uint64_t i = 0; i < body->geoms.size(); ++i) {
	tree += indent + "<geom/>\n";
	}
	for (uint64_t i = 0; i < body->sites.size(); ++i) {
	tree += indent + "<site/>\n";
	}
	for (uint64_t i = 0; i < body->cameras.size(); ++i) {
	tree += indent + "<camera/>\n";
	}
	for (uint64_t i = 0; i < body->lights.size(); ++i) {
	tree += indent + "<light/>\n";
	}
	for (uint64_t i = 0; i < body->bodies.size(); ++i) {
	tree += PrintTree(body->bodies[i], indent);
	}
	indent.pop_back();
	indent.pop_back();
	tree += indent + "</body>\n";
	return tree;
	}



	uint64_t mjCModel::Signature() {
	std::string tree = "\n" + PrintTree(bodies_[0]);
	for (unsigned int i = 0; i < flexes_.size(); ++i) {
	tree += "<flex/>\n";
	}
	for (unsigned int i = 0; i < meshes_.size(); ++i) {
	tree += "<mesh/>\n";
	}
	for (unsigned int i = 0; i < skins_.size(); ++i) {
	tree += "<skin/>\n";
	}
	for (unsigned int i = 0; i < hfields_.size(); ++i) {
	tree += "<heightfield/>\n";
	}
	for (unsigned int i = 0; i < textures_.size(); ++i) {
	tree += "<texture/>\n";
	}
	for (unsigned int i = 0; i < materials_.size(); ++i) {
	tree += "<material/>\n";
	}
	for (unsigned int i = 0; i < pairs_.size(); ++i) {
	tree += "<pair/>\n";
	}
	for (unsigned int i = 0; i < excludes_.size(); ++i) {
	tree += "<exclude/>\n";
	}
	for (unsigned int i = 1; i < equalities_.size(); ++i) {
	tree += "<equality/>\n";
	}
	for (unsigned int i = 0; i < tendons_.size(); ++i) {
	tree += "<tendon/>\n";
	}
	for (unsigned int i = 0; i < actuators_.size(); ++i) {
	tree += "<actuator/>\n";
	}
	for (unsigned int i = 0; i < sensors_.size(); ++i) {
	tree += "<sensor>" + std::to_string(sensors_[i]->spec.type) + "<sensor/>\n";
	}
	for (unsigned int i = 0; i < keys_.size(); ++i) {
	tree += "<key/>\n";
	}
	return mj_hashString(tree.c_str(), UINT64_MAX);
	}



	bool mjCModel::CheckBodyMassInertia(mjCBody* body) {
	// check if body has valid mass and inertia
	if (body->mass >= mjMINVAL &&
	body->inertia[0] >= mjMINVAL &&
	body->inertia[1] >= mjMINVAL &&
	body->inertia[2] >= mjMINVAL) {
	return true;
	}

	// body is valid if we find a single static child with valid mass and inertia
	for (int i=0; i < body->Bodies().size(); i++) {
	// if we find a child with a joint, time to move on to the next moving body
	if (!body->Bodies()[i]->joints.empty()) {
	continue;
	}
	if (CheckBodyMassInertia(body->Bodies()[i])) {
	return true;
	}
	}

	// we did not find a child with valid mass and inertia
	return false;
	}



	//------------------------------- DECOMPILER -------------------------------------------------------

	// get numeric data back from mjModel
	bool mjCModel::CopyBack(const mjModel* m) {
	// check for null pointer
	if (!m) {
	errInfo = mjCError(0, "mjModel pointer is null in CopyBack");
	return false;
	}

	// make sure model has been compiled
	if (!compiled) {
	errInfo = mjCError(0, "mjCModel has not been compiled in CopyBack");
	return false;
	}

	// make sure sizes match
	if (nq != m->nq \|\| nv != m->nv \|\| nu != m->nu \|\| na != m->na \|\|
	nbody != m->nbody \|\|njnt != m->njnt \|\| ngeom != m->ngeom \|\| nsite != m->nsite \|\|
	ncam != m->ncam \|\| nlight != m->nlight \|\| nmesh != m->nmesh \|\|
	nskin != m->nskin \|\| nhfield != m->nhfield \|\|
	nmat != m->nmat \|\| ntex != m->ntex \|\| npair != m->npair \|\| nexclude != m->nexclude \|\|
	neq != m->neq \|\| ntendon != m->ntendon \|\| nwrap != m->nwrap \|\| nsensor != m->nsensor \|\|
	nnumeric != m->nnumeric \|\| nnumericdata != m->nnumericdata \|\| ntext != m->ntext \|\|
	ntextdata != m->ntextdata \|\| nnames != m->nnames \|\|
	nM != m->nM \|\| nD != m->nD \|\| nC != m->nC \|\| nB != m->nB \|\| nJmom != m->nJmom \|\|
	nemax != m->nemax \|\| nconmax != m->nconmax \|\| njmax != m->njmax \|\|
	npaths != m->npaths) {
	errInfo = mjCError(0, "incompatible models in CopyBack");
	return false;
	}

	if (spec.element->signature != m->signature) {
	errInfo = mjCError(0, "incompatible signatures in CopyBack");
	return false;
	}

	// option and visual
	option = m->opt;
	visual = m->vis;

	// runtime-modifiable members of mjStatistic, if different from computed values
	if (m->stat.meaninertia != meaninertia_auto) stat.meaninertia = m->stat.meaninertia;
	if (m->stat.meanmass != meanmass_auto) stat.meanmass = m->stat.meanmass;
	if (m->stat.meansize != meansize_auto) stat.meansize = m->stat.meansize;
	if (m->stat.extent != extent_auto) stat.extent = m->stat.extent;
	if (m->stat.center[0] != center_auto[0] \|\|
	m->stat.center[1] != center_auto[1] \|\|
	m->stat.center[2] != center_auto[2]) {
	mjuu_copyvec(stat.center, m->stat.center, 3);
	}

	// qpos0, qpos_spring
	for (int i=0; i < njnt; i++) {
	switch (joints_[i]->type) {
	case mjJNT_FREE:
	mjuu_copyvec(bodies_[m->jnt_bodyid[i]]->pos, m->qpos0+m->jnt_qposadr[i], 3);
	mjuu_copyvec(bodies_[m->jnt_bodyid[i]]->quat, m->qpos0+m->jnt_qposadr[i]+3, 4);
	break;

	case mjJNT_SLIDE:
	case mjJNT_HINGE:
	joints_[i]->ref = (double)m->qpos0[m->jnt_qposadr[i]];
	joints_[i]->springref = (double)m->qpos_spring[m->jnt_qposadr[i]];
	break;

	case mjJNT_BALL:
	// nothing to do, qpos = unit quaternion always
	break;
	}
	}
	mjuu_copyvec(qpos0.data(), m->qpos0, m->nq);

	// body
	mjCBody* pb;
	for (int i=0; i < nbody; i++) {
	pb = bodies_[i];

	mjuu_copyvec(pb->pos, m->body_pos+3*i, 3);
	mjuu_copyvec(pb->quat, m->body_quat+4*i, 4);
	mjuu_copyvec(pb->ipos, m->body_ipos+3*i, 3);
	mjuu_copyvec(pb->iquat, m->body_iquat+4*i, 4);
	pb->mass = (double)m->body_mass[i];
	mjuu_copyvec(pb->inertia, m->body_inertia+3*i, 3);

	if (nuser_body) {
	mjuu_copyvec(pb->userdata_.data(), m->body_user + nuser_body*i, nuser_body);
	}
	}

	// joint and dof
	mjCJoint* pj;
	for (int i=0; i < njnt; i++) {
	pj = joints_[i];

	// joint data
	mjuu_copyvec(pj->pos, m->jnt_pos+3*i, 3);
	mjuu_copyvec(pj->axis, m->jnt_axis+3*i, 3);
	pj->stiffness = (double)m->jnt_stiffness[i];
	mjuu_copyvec(pj->range, m->jnt_range+2*i, 2);
	mjuu_copyvec(pj->solref_limit, m->jnt_solref+mjNREF*i, mjNREF);
	mjuu_copyvec(pj->solimp_limit, m->jnt_solimp+mjNIMP*i, mjNIMP);
	pj->margin = (double)m->jnt_margin[i];

	if (nuser_jnt) {
	mjuu_copyvec(pj->userdata_.data(), m->jnt_user + nuser_jnt*i, nuser_jnt);
	}

	// dof data
	int j = m->jnt_dofadr[i];
	mjuu_copyvec(pj->solref_friction, m->dof_solref+mjNREF*j, mjNREF);
	mjuu_copyvec(pj->solimp_friction, m->dof_solimp+mjNIMP*j, mjNIMP);
	pj->armature = (double)m->dof_armature[j];
	pj->damping = (double)m->dof_damping[j];
	pj->frictionloss = (double)m->dof_frictionloss[j];
	}

	// geom
	mjCGeom* pg;
	for (int i=0; i < ngeom; i++) {
	pg = geoms_[i];

	mjuu_copyvec(pg->size, m->geom_size+3*i, 3);
	mjuu_copyvec(pg->pos, m->geom_pos+3*i, 3);
	mjuu_copyvec(pg->quat, m->geom_quat+4*i, 4);
	mjuu_copyvec(pg->friction, m->geom_friction+3*i, 3);
	mjuu_copyvec(pg->solref, m->geom_solref+mjNREF*i, mjNREF);
	mjuu_copyvec(pg->solimp, m->geom_solimp+mjNIMP*i, mjNIMP);
	mjuu_copyvec(pg->rgba, m->geom_rgba+4*i, 4);
	pg->solmix = (double)m->geom_solmix[i];
	pg->margin = (double)m->geom_margin[i];
	pg->gap = (double)m->geom_gap[i];

	if (nuser_geom) {
	mjuu_copyvec(pg->userdata_.data(), m->geom_user + nuser_geom*i, nuser_geom);
	}
	}

	// mesh
	mjCMesh* pm;
	for (int i=0; i < nmesh; i++) {
	pm = meshes_[i];
	mjuu_copyvec(pm->GetPosPtr(), m->mesh_pos+3*i, 3);
	mjuu_copyvec(pm->GetQuatPtr(), m->mesh_quat+4*i, 4);
	}

	// heightfield
	mjCHField* phf;
	for (int i=0; i < nhfield; i++) {
	phf = hfields_[i];
	int size = phf->get_userdata().size();
	if (size) {
	int nrow = m->hfield_nrow[i];
	int ncol = m->hfield_ncol[i];
	float* userdata = phf->get_userdata().data();
	float* modeldata = m->hfield_data + m->hfield_adr[i];
	// copy back in reverse row order
	for (int j=0; j < nrow; j++) {
	int flip = nrow-1-j;
	mjuu_copyvec(userdata + flipncol, modeldata+jncol, ncol);
	}
	}
	}

	// sites
	for (int i=0; i < nsite; i++) {
	mjuu_copyvec(sites_[i]->size, m->site_size + 3 * i, 3);
	mjuu_copyvec(sites_[i]->pos, m->site_pos+3*i, 3);
	mjuu_copyvec(sites_[i]->quat, m->site_quat+4*i, 4);
	mjuu_copyvec(sites_[i]->rgba, m->site_rgba+4*i, 4);

	if (nuser_site) {
	mjuu_copyvec(sites_[i]->userdata_.data(), m->site_user + nuser_site*i, nuser_site);
	}
	}

	// cameras
	for (int i=0; i < ncam; i++) {
	mjuu_copyvec(cameras_[i]->pos, m->cam_pos+3*i, 3);
	mjuu_copyvec(cameras_[i]->quat, m->cam_quat+4*i, 4);
	cameras_[i]->fovy = (double)m->cam_fovy[i];
	cameras_[i]->ipd = (double)m->cam_ipd[i];
	mjuu_copyvec(cameras_[i]->resolution, m->cam_resolution+2*i, 2);
	mjuu_copyvec(cameras_[i]->intrinsic, m->cam_intrinsic+4*i, 4);

	if (nuser_cam) {
	mjuu_copyvec(cameras_[i]->userdata_.data(), m->cam_user + nuser_cam*i, nuser_cam);
	}
	}

	// lights
	for (int i=0; i < nlight; i++) {
	mjuu_copyvec(lights_[i]->pos, m->light_pos+3*i, 3);
	mjuu_copyvec(lights_[i]->dir, m->light_dir+3*i, 3);
	mjuu_copyvec(lights_[i]->attenuation, m->light_attenuation+3*i, 3);
	lights_[i]->cutoff = m->light_cutoff[i];
	lights_[i]->exponent = m->light_exponent[i];
	mjuu_copyvec(lights_[i]->ambient, m->light_ambient+3*i, 3);
	mjuu_copyvec(lights_[i]->diffuse, m->light_diffuse+3*i, 3);
	mjuu_copyvec(lights_[i]->specular, m->light_specular+3*i, 3);
	}

	// materials
	for (int i=0; i < nmat; i++) {
	mjuu_copyvec(materials_[i]->texrepeat, m->mat_texrepeat+2*i, 2);
	materials_[i]->emission = m->mat_emission[i];
	materials_[i]->specular = m->mat_specular[i];
	materials_[i]->shininess = m->mat_shininess[i];
	materials_[i]->reflectance = m->mat_reflectance[i];
	mjuu_copyvec(materials_[i]->rgba, m->mat_rgba+4*i, 4);
	}

	// pairs
	for (int i=0; i < npair; i++) {
	mjuu_copyvec(pairs_[i]->solref, m->pair_solref+mjNREF*i, mjNREF);
	mjuu_copyvec(pairs_[i]->solreffriction, m->pair_solreffriction+mjNREF*i, mjNREF);
	mjuu_copyvec(pairs_[i]->solimp, m->pair_solimp+mjNIMP*i, mjNIMP);
	pairs_[i]->margin = (double)m->pair_margin[i];
	pairs_[i]->gap = (double)m->pair_gap[i];
	mjuu_copyvec(pairs_[i]->friction, m->pair_friction+5*i, 5);
	}

	// equality constraints
	for (int i=0; i < neq; i++) {
	mjuu_copyvec(equalities_[i]->data, m->eq_data+mjNEQDATA*i, mjNEQDATA);
	mjuu_copyvec(equalities_[i]->solref, m->eq_solref+mjNREF*i, mjNREF);
	mjuu_copyvec(equalities_[i]->solimp, m->eq_solimp+mjNIMP*i, mjNIMP);
	}

	// tendons
	for (int i=0; i < ntendon; i++) {
	mjuu_copyvec(tendons_[i]->range, m->tendon_range+2*i, 2);
	mjuu_copyvec(tendons_[i]->actfrcrange, m->tendon_actfrcrange+2*i, 2);
	mjuu_copyvec(tendons_[i]->solref_limit, m->tendon_solref_lim+mjNREF*i, mjNREF);
	mjuu_copyvec(tendons_[i]->solimp_limit, m->tendon_solimp_lim+mjNIMP*i, mjNIMP);
	mjuu_copyvec(tendons_[i]->solref_friction, m->tendon_solref_fri+mjNREF*i, mjNREF);
	mjuu_copyvec(tendons_[i]->solimp_friction, m->tendon_solimp_fri+mjNIMP*i, mjNIMP);
	mjuu_copyvec(tendons_[i]->rgba, m->tendon_rgba+4*i, 4);
	tendons_[i]->width = (double)m->tendon_width[i];
	tendons_[i]->margin = (double)m->tendon_margin[i];
	tendons_[i]->stiffness = (double)m->tendon_stiffness[i];
	tendons_[i]->damping = (double)m->tendon_damping[i];
	tendons_[i]->armature = (double)m->tendon_armature[i];
	tendons_[i]->frictionloss = (double)m->tendon_frictionloss[i];

	if (nuser_tendon) {
	mjuu_copyvec(tendons_[i]->userdata_.data(), m->tendon_user + nuser_tendon*i, nuser_tendon);
	}
	}

	// actuators
	mjCActuator* pa;
	for (int i=0; i < nu; i++) {
	pa = actuators_[i];

	mjuu_copyvec(pa->dynprm, m->actuator_dynprm+i*mjNDYN, mjNDYN);
	mjuu_copyvec(pa->gainprm, m->actuator_gainprm+i*mjNGAIN, mjNGAIN);
	mjuu_copyvec(pa->biasprm, m->actuator_biasprm+i*mjNBIAS, mjNBIAS);
	mjuu_copyvec(pa->ctrlrange, m->actuator_ctrlrange+2*i, 2);
	mjuu_copyvec(pa->forcerange, m->actuator_forcerange+2*i, 2);
	mjuu_copyvec(pa->actrange, m->actuator_actrange+2*i, 2);
	mjuu_copyvec(pa->lengthrange, m->actuator_lengthrange+2*i, 2);
	mjuu_copyvec(pa->gear, m->actuator_gear+6*i, 6);
	pa->cranklength = (double)m->actuator_cranklength[i];

	if (nuser_actuator) {
	mjuu_copyvec(pa->userdata_.data(), m->actuator_user + nuser_actuator*i, nuser_actuator);
	}
	}

	// sensors
	for (int i=0; i < nsensor; i++) {
	sensors_[i]->cutoff = (double)m->sensor_cutoff[i];
	sensors_[i]->noise = (double)m->sensor_noise[i];

	if (nuser_sensor) {
	mjuu_copyvec(sensors_[i]->userdata_.data(), m->sensor_user + nuser_sensor*i, nuser_sensor);
	}
	}

	// numeric data
	for (int i=0; i < nnumeric; i++) {
	for (int j=0; j < m->numeric_size[i]; j++) {
	numerics_[i]->data_[j] = (double)m->numeric_data[m->numeric_adr[i]+j];
	}
	}

	// tuple data
	for (int i=0; i < ntuple; i++) {
	for (int j=0; j < m->tuple_size[i]; j++) {
	tuples_[i]->objprm_[j] = (double)m->tuple_objprm[m->tuple_adr[i]+j];
	}
	}

	// keyframes
	for (int i=0; i < m->nkey; i++) {
	mjCKey* pk = keys_[i];

	pk->time = (double)m->key_time[i];
	mjuu_copyvec(pk->qpos_.data(), m->key_qpos + i*nq, nq);
	mjuu_copyvec(pk->qvel_.data(), m->key_qvel + i*nv, nv);
	if (na) {
	mjuu_copyvec(pk->act_.data(), m->key_act + i*na, na);
	}
	if (nmocap) {
	mjuu_copyvec(pk->mpos_.data(), m->key_mpos + i3nmocap, 3*nmocap);
	mjuu_copyvec(pk->mquat_.data(), m->key_mquat + i4nmocap, 4*nmocap);
	}
	if (nu) {
	mjuu_copyvec(pk->ctrl_.data(), m->key_ctrl + i*nu, nu);
	}
	}

	return true;
	}



	void mjCModel::ActivatePlugin(const mjpPlugin* plugin, int slot) {
	bool already_declared = false;
	for (const auto& [existing_plugin, existing_slot] : active_plugins_) {
	if (plugin == existing_plugin) {
	already_declared = true;
	break;
	}
	}
	if (!already_declared) {
	active_plugins_.emplace_back(std::make_pair(plugin, slot));
	}
	}



	void mjCModel::ResolvePlugin(mjCBase* obj, const std::string& plugin_name,
	const std::string& plugin_instance_name, mjCPlugin** plugin_instance) {
	std::string pname = plugin_name;

	// if the plugin name is not specified by the user, infer it from the plugin instance
	if (plugin_name.empty() && !plugin_instance_name.empty()) {
	mjCBase* plugin_obj = FindObject(mjOBJ_PLUGIN, plugin_instance_name);
	if (plugin_obj) {
	pname = static_cast<mjCPlugin*>(plugin_obj)->plugin_name;
	} else {
	throw mjCError(obj, "unrecognized name '%s' for plugin instance",
	plugin_instance_name.c_str());
	}
	}

	// if plugin_name is specified, check if it is in the list of active plugins
	// (in XML, active plugins are those declared as <required>)
	int plugin_slot = -1;
	if (!pname.empty()) {
	for (int i = 0; i < active_plugins_.size(); ++i) {
	if (active_plugins_[i].first->name == pname) {
	plugin_slot = active_plugins_[i].second;
	break;
	}
	}
	if (plugin_slot == -1) {
	throw mjCError(obj, "unrecognized plugin '%s'", pname.c_str());
	}
	}

	// implicit plugin instance
	if (plugin_instance && (plugin_instance)->plugin_slot == -1) {
	(*plugin_instance)->plugin_slot = plugin_slot;
	(*plugin_instance)->parent = obj;
	}

	// explicit plugin instance, look up existing mjCPlugin by instance name
	else if (!*plugin_instance) {
	*plugin_instance =
	static_cast<mjCPlugin*>(FindObject(mjOBJ_PLUGIN, plugin_instance_name));
	(*plugin_instance)->plugin_slot = plugin_slot;
	if (!*plugin_instance) {
	throw mjCError(
	obj, "unrecognized name '%s' for plugin instance", plugin_instance_name.c_str());
	}
	if (plugin_slot != -1 && plugin_slot != (*plugin_instance)->plugin_slot) {
	throw mjCError(
	obj, "'plugin' attribute does not match that of the instance");
	}
	plugin_slot = (*plugin_instance)->plugin_slot;
	}
	}