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mujoco / data /src /xml /xml_native_reader.cc
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 // 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 "xml/xml_native_reader.h"
#include <array>
#include <cstddef>
#include <cstdio>
#include <cstring>
#include <functional>
#include <limits>
#include <map>
#include <optional>
#include <sstream>
#include <string>
#include <string_view>
#include <utility>
#include <vector>
#include <mujoco/mujoco.h>
#include <mujoco/mjmodel.h>
#include <mujoco/mjplugin.h>
#include <mujoco/mjtnum.h>
#include <mujoco/mjvisualize.h>
#include "engine/engine_plugin.h"
#include "engine/engine_util_errmem.h"
#include "engine/engine_util_misc.h"
#include <mujoco/mjspec.h>
#include "user/user_api.h"
#include "user/user_composite.h"
#include "user/user_flexcomp.h"
#include "user/user_util.h"
#include "xml/xml_base.h"
#include "xml/xml_util.h"
#include "tinyxml2.h"
namespace {
using std::string;
using std::string_view;
using std::vector;
using mujoco::user::FilePath;
using tinyxml2::XMLElement;
void ReadPluginConfigs(tinyxml2::XMLElement* elem, mjsPlugin* p) {
std::map<string, string, std::less<> > config_attribs;
XMLElement* child = FirstChildElement(elem);
while (child) {
string_view name = child->Value();
if (name == "config") {
string key, value;
mjXUtil::ReadAttrTxt(child, "key", key, /* required = */ true);
if (config_attribs.find(key) != config_attribs.end()) {
string err = "duplicate config key: " + key;
throw mjXError(child, "%s", err.c_str());
}
mjXUtil::ReadAttrTxt(child, "value", value, /* required = */ true);
config_attribs[key] = value;
}
child = NextSiblingElement(child);
}
if (!p && !config_attribs.empty()) {
throw mjXError(elem,
"plugin configuration attributes cannot be used in an "
"element that references a predefined plugin instance");
} else if (p) {
mjs_setPluginAttributes(p, &config_attribs);
}
}
static void UpdateString(string& psuffix, int count, int i) {
int ndigits = std::to_string(count).length();
string i_string = std::to_string(i);
string prefix = "";
while (ndigits-- > i_string.length()) {
prefix += '0';
}
psuffix += prefix + i_string;
}
} // namespace
//---------------------------------- MJCF schema ---------------------------------------------------
const char* MJCF[nMJCF][mjXATTRNUM] = {
{"mujoco", "!", "1", "model"},
{"<"},
{"compiler", "*", "20", "autolimits", "boundmass", "boundinertia", "settotalmass",
"balanceinertia", "strippath", "coordinate", "angle", "fitaabb", "eulerseq",
"meshdir", "texturedir", "discardvisual", "usethread", "fusestatic", "inertiafromgeom",
"inertiagrouprange", "saveinertial", "assetdir", "alignfree"},
{"<"},
{"lengthrange", "?", "10", "mode", "useexisting", "uselimit",
"accel", "maxforce", "timeconst", "timestep",
"inttotal", "interval", "tolrange"},
{">"},
{"option", "*", "27",
"timestep", "apirate", "impratio", "tolerance", "ls_tolerance", "noslip_tolerance",
"ccd_tolerance", "gravity", "wind", "magnetic", "density", "viscosity",
"o_margin", "o_solref", "o_solimp", "o_friction",
"integrator", "cone", "jacobian",
"solver", "iterations", "ls_iterations", "noslip_iterations", "ccd_iterations",
"sdf_iterations", "sdf_initpoints", "actuatorgroupdisable"},
{"<"},
{"flag", "?", "23", "constraint", "equality", "frictionloss", "limit", "contact",
"passive", "gravity", "clampctrl", "warmstart",
"filterparent", "actuation", "refsafe", "sensor", "midphase", "eulerdamp", "autoreset",
"override", "energy", "fwdinv", "invdiscrete", "multiccd", "island", "nativeccd"},
{">"},
{"size", "*", "14", "memory", "njmax", "nconmax", "nstack", "nuserdata", "nkey",
"nuser_body", "nuser_jnt", "nuser_geom", "nuser_site", "nuser_cam",
"nuser_tendon", "nuser_actuator", "nuser_sensor"},
{"visual", "*", "0"},
{"<"},
{"global", "?", "13", "cameraid", "orthographic", "fovy", "ipd", "azimuth", "elevation",
"linewidth", "glow", "offwidth", "offheight", "realtime", "ellipsoidinertia",
"bvactive"},
{"quality", "?", "5", "shadowsize", "offsamples", "numslices", "numstacks",
"numquads"},
{"headlight", "?", "4", "ambient", "diffuse", "specular", "active"},
{"map", "?", "13", "stiffness", "stiffnessrot", "force", "torque", "alpha",
"fogstart", "fogend", "znear", "zfar", "haze", "shadowclip", "shadowscale",
"actuatortendon"},
{"scale", "?", "17", "forcewidth", "contactwidth", "contactheight", "connect", "com",
"camera", "light", "selectpoint", "jointlength", "jointwidth", "actuatorlength",
"actuatorwidth", "framelength", "framewidth", "constraint", "slidercrank", "frustum"},
{"rgba", "?", "25", "fog", "haze", "force", "inertia", "joint",
"actuator", "actuatornegative", "actuatorpositive", "com",
"camera", "light", "selectpoint", "connect", "contactpoint", "contactforce",
"contactfriction", "contacttorque", "contactgap", "rangefinder",
"constraint", "slidercrank", "crankbroken", "frustum", "bv", "bvactive"},
{">"},
{"statistic", "*", "5", "meaninertia", "meanmass", "meansize", "extent", "center"},
{"default", "R", "1", "class"},
{"<"},
{"mesh", "?", "3", "scale", "maxhullvert", "inertia"},
{"material", "?", "10", "texture", "emission", "specular", "shininess",
"reflectance", "metallic", "roughness", "rgba", "texrepeat", "texuniform"},
{"joint", "?", "22", "type", "group", "pos", "axis", "springdamper",
"limited", "actuatorfrclimited", "solreflimit", "solimplimit",
"solreffriction", "solimpfriction", "stiffness", "range", "actuatorfrcrange",
"actuatorgravcomp", "margin", "ref", "springref", "armature", "damping",
"frictionloss", "user"},
{"geom", "?", "31", "type", "pos", "quat", "contype", "conaffinity", "condim",
"group", "priority", "size", "material", "friction", "mass", "density",
"shellinertia", "solmix", "solref", "solimp",
"margin", "gap", "fromto", "axisangle", "xyaxes", "zaxis", "euler",
"hfield", "mesh", "fitscale", "rgba", "fluidshape", "fluidcoef", "user"},
{"site", "?", "13", "type", "group", "pos", "quat", "material",
"size", "fromto", "axisangle", "xyaxes", "zaxis", "euler", "rgba", "user"},
{"camera", "?", "17", "orthographic", "fovy", "ipd", "resolution", "pos", "quat",
"axisangle", "xyaxes", "zaxis", "euler", "mode", "focal", "focalpixel",
"principal", "principalpixel", "sensorsize", "user"},
{"light", "?", "16", "pos", "dir", "bulbradius", "intensity", "range",
"directional", "type", "castshadow", "active", "attenuation", "cutoff", "exponent",
"ambient", "diffuse", "specular", "mode"},
{"pair", "?", "7", "condim", "friction", "solref", "solreffriction", "solimp",
"gap", "margin"},
{"equality", "?", "3", "active", "solref", "solimp"},
{"tendon", "?", "16", "group", "limited", "range",
"solreflimit", "solimplimit", "solreffriction", "solimpfriction",
"frictionloss", "springlength", "width", "material",
"margin", "stiffness", "damping", "rgba", "user"},
{"general", "?", "18", "ctrllimited", "forcelimited", "actlimited", "ctrlrange",
"forcerange", "actrange", "gear", "cranklength", "user", "group", "actdim",
"dyntype", "gaintype", "biastype", "dynprm", "gainprm", "biasprm", "actearly"},
{"motor", "?", "8", "ctrllimited", "forcelimited", "ctrlrange", "forcerange",
"gear", "cranklength", "user", "group"},
{"position", "?", "13", "ctrllimited", "forcelimited", "ctrlrange", "inheritrange",
"forcerange", "gear", "cranklength", "user", "group", "kp", "kv", "dampratio", "timeconst"},
{"velocity", "?", "9", "ctrllimited", "forcelimited", "ctrlrange", "forcerange",
"gear", "cranklength", "user", "group", "kv"},
{"intvelocity", "?", "13", "ctrllimited", "forcelimited",
"ctrlrange", "forcerange", "actrange", "inheritrange",
"gear", "cranklength", "user", "group",
"kp", "kv", "dampratio"},
{"damper", "?", "8", "forcelimited", "ctrlrange", "forcerange",
"gear", "cranklength", "user", "group", "kv"},
{"cylinder", "?", "12", "ctrllimited", "forcelimited", "ctrlrange", "forcerange",
"gear", "cranklength", "user", "group",
"timeconst", "area", "diameter", "bias"},
{"muscle", "?", "17", "ctrllimited", "forcelimited", "ctrlrange", "forcerange",
"gear", "cranklength", "user", "group",
"timeconst", "range", "force", "scale",
"lmin", "lmax", "vmax", "fpmax", "fvmax"},
{"adhesion", "?", "6", "forcelimited", "ctrlrange", "forcerange",
"gain", "user", "group"},
{">"},
{"extension", "*", "0"},
{"<"},
{"plugin", "*", "1", "plugin"},
{"<"},
{"instance", "*", "1", "name"},
{"<"},
{"config", "*", "2", "key", "value"},
{">"},
{">"},
{">"},
{"custom", "*", "0"},
{"<"},
{"numeric", "*", "3", "name", "size", "data"},
{"text", "*", "2", "name", "data"},
{"tuple", "*", "1", "name"},
{"<"},
{"element", "*", "3", "objtype", "objname", "prm"},
{">"},
{">"},
{"asset", "*", "0"},
{"<"},
{"mesh", "*", "14", "name", "class", "content_type", "file", "vertex", "normal",
"texcoord", "face", "refpos", "refquat", "scale", "smoothnormal",
"maxhullvert", "inertia"},
{"<"},
{"plugin", "*", "2", "plugin", "instance"},
{"<"},
{"config", "*", "2", "key", "value"},
{">"},
{">"},
{"hfield", "*", "7", "name", "content_type", "file", "nrow", "ncol", "size", "elevation"},
{"skin", "*", "9", "name", "file", "material", "rgba", "inflate",
"vertex", "texcoord", "face", "group"},
{"<"},
{"bone", "*", "5", "body", "bindpos", "bindquat", "vertid", "vertweight"},
{">"},
{"texture", "*", "24", "name", "type", "colorspace", "content_type", "file", "gridsize",
"gridlayout", "fileright", "fileleft", "fileup", "filedown", "filefront", "fileback",
"builtin", "rgb1", "rgb2", "mark", "markrgb", "random", "width", "height",
"hflip", "vflip", "nchannel"},
{"material", "*", "12", "name", "class", "texture", "texrepeat", "texuniform",
"emission", "specular", "shininess", "reflectance", "metallic", "roughness", "rgba"},
{"<"},
{"layer", "*", "2", "texture", "role"},
{">"},
{"model", "*", "3", "name", "file", "content_type"},
{">"},
{"body", "R", "11", "name", "childclass", "pos", "quat", "mocap",
"axisangle", "xyaxes", "zaxis", "euler", "gravcomp", "user"},
{"<"},
{"inertial", "?", "9", "pos", "quat", "mass", "diaginertia",
"axisangle", "xyaxes", "zaxis", "euler", "fullinertia"},
{"joint", "*", "24", "name", "class", "type", "group", "pos", "axis",
"springdamper", "limited", "actuatorfrclimited",
"solreflimit", "solimplimit", "solreffriction", "solimpfriction",
"stiffness", "range", "actuatorfrcrange", "actuatorgravcomp", "margin", "ref",
"springref", "armature", "damping", "frictionloss", "user"},
{"freejoint", "*", "3", "name", "group", "align"},
{"geom", "*", "33", "name", "class", "type", "contype", "conaffinity", "condim",
"group", "priority", "size", "material", "friction", "mass", "density",
"shellinertia", "solmix", "solref", "solimp",
"margin", "gap", "fromto", "pos", "quat", "axisangle", "xyaxes", "zaxis", "euler",
"hfield", "mesh", "fitscale", "rgba", "fluidshape", "fluidcoef", "user"},
{"<"},
{"plugin", "*", "2", "plugin", "instance"},
{"<"},
{"config", "*", "2", "key", "value"},
{">"},
{">"},
{"attach", "*", "3", "model", "body", "prefix"},
{"site", "*", "15", "name", "class", "type", "group", "pos", "quat",
"material", "size", "fromto", "axisangle", "xyaxes", "zaxis", "euler", "rgba", "user"},
{"camera", "*", "20", "name", "class", "orthographic", "fovy", "ipd", "resolution", "pos",
"quat", "axisangle", "xyaxes", "zaxis", "euler", "mode", "target",
"focal", "focalpixel", "principal", "principalpixel", "sensorsize", "user"},
{"light", "*", "20", "name", "class", "directional", "type", "castshadow", "active",
"pos", "dir", "bulbradius", "intensity", "range", "attenuation", "cutoff",
"exponent", "ambient", "diffuse", "specular", "mode", "target", "texture"},
{"plugin", "*", "2", "plugin", "instance"},
{"<"},
{"config", "*", "2", "key", "value"},
{">"},
{"composite", "*", "9", "prefix", "type", "count", "offset",
"vertex", "initial", "curve", "size", "quat"},
{"<"},
{"joint", "*", "17", "kind", "group", "stiffness", "damping", "armature",
"solreffix", "solimpfix", "type", "axis",
"limited", "range", "margin", "solreflimit", "solimplimit",
"frictionloss", "solreffriction", "solimpfriction"},
{"skin", "?", "6", "texcoord", "material", "group", "rgba", "inflate", "subgrid"},
{"geom", "?", "17", "type", "contype", "conaffinity", "condim",
"group", "priority", "size", "material", "rgba", "friction", "mass",
"density", "solmix", "solref", "solimp", "margin", "gap"},
{"site", "?", "4", "group", "size", "material", "rgba"},
{"plugin", "*", "2", "plugin", "instance"},
{"<"},
{"config", "*", "2", "key", "value"},
{">"},
{">"},
{"flexcomp", "*", "26", "name", "type", "group", "dim", "dof",
"count", "spacing", "radius", "rigid", "mass", "inertiabox",
"scale", "file", "point", "element", "texcoord", "material", "rgba",
"flatskin", "pos", "quat", "axisangle", "xyaxes", "zaxis", "euler", "origin"},
{"<"},
{"edge", "?", "5", "equality", "solref", "solimp", "stiffness", "damping"},
{"elasticity", "?", "5", "young", "poisson", "damping", "thickness", "elastic2d"},
{"contact", "?", "14", "contype", "conaffinity", "condim", "priority",
"friction", "solmix", "solref", "solimp", "margin", "gap",
"internal", "selfcollide", "activelayers", "vertcollide"},
{"pin", "*", "4", "id", "range", "grid", "gridrange"},
{"plugin", "*", "2", "plugin", "instance"},
{"<"},
{"config", "*", "2", "key", "value"},
{">"},
{">"},
{">"},
{"deformable", "*", "0"},
{"<"},
{"flex", "*", "13", "name", "group", "dim", "radius", "material",
"rgba", "flatskin", "body", "vertex", "element", "texcoord", "elemtexcoord", "node"},
{"<"},
{"contact", "?", "14", "contype", "conaffinity", "condim", "priority",
"friction", "solmix", "solref", "solimp", "margin", "gap",
"internal", "selfcollide", "activelayers", "vertcollide"},
{"edge", "?", "2", "stiffness", "damping"},
{"elasticity", "?", "5", "young", "poisson", "damping", "thickness", "elastic2d"},
{">"},
{"skin", "*", "9", "name", "file", "material", "rgba", "inflate",
"vertex", "texcoord", "face", "group"},
{"<"},
{"bone", "*", "5", "body", "bindpos", "bindquat", "vertid", "vertweight"},
{">"},
{">"},
{"contact", "*", "0"},
{"<"},
{"pair", "*", "11", "name", "class", "geom1", "geom2", "condim", "friction",
"solref", "solreffriction", "solimp", "gap", "margin"},
{"exclude", "*", "3", "name", "body1", "body2"},
{">"},
{"equality", "*", "0"},
{"<"},
{"connect", "*", "10", "name", "class", "body1", "body2", "anchor",
"site1", "site2", "active", "solref", "solimp"},
{"weld", "*", "12", "name", "class", "body1", "body2", "relpose", "anchor",
"site1", "site2", "active", "solref", "solimp", "torquescale"},
{"joint", "*", "8", "name", "class", "joint1", "joint2", "polycoef",
"active", "solref", "solimp"},
{"tendon", "*", "8", "name", "class", "tendon1", "tendon2", "polycoef",
"active", "solref", "solimp"},
{"flex", "*", "6", "name", "class", "flex",
"active", "solref", "solimp"},
{">"},
{"tendon", "*", "0"},
{"<"},
{"spatial", "*", "21", "name", "class", "group", "limited", "actuatorfrclimited", "range",
"actuatorfrcrange", "solreflimit", "solimplimit", "solreffriction", "solimpfriction",
"frictionloss", "springlength", "width", "material",
"margin", "stiffness", "damping", "armature", "rgba", "user"},
{"<"},
{"site", "*", "1", "site"},
{"geom", "*", "2", "geom", "sidesite"},
{"pulley", "*", "1", "divisor"},
{">"},
{"fixed", "*", "18", "name", "class", "group", "limited", "actuatorfrclimited", "range",
"actuatorfrcrange","solreflimit", "solimplimit", "solreffriction", "solimpfriction",
"frictionloss", "springlength", "margin", "stiffness", "damping", "armature", "user"},
{"<"},
{"joint", "*", "2", "joint", "coef"},
{">"},
{">"},
{"actuator", "*", "0"},
{"<"},
{"general", "*", "29", "name", "class", "group",
"ctrllimited", "forcelimited", "actlimited", "ctrlrange", "forcerange", "actrange",
"lengthrange", "gear", "cranklength", "user",
"joint", "jointinparent", "tendon", "slidersite", "cranksite", "site", "refsite",
"body", "actdim", "dyntype", "gaintype", "biastype", "dynprm", "gainprm", "biasprm",
"actearly"},
{"motor", "*", "18", "name", "class", "group",
"ctrllimited", "forcelimited", "ctrlrange", "forcerange",
"lengthrange", "gear", "cranklength", "user",
"joint", "jointinparent", "tendon", "slidersite", "cranksite", "site", "refsite"},
{"position", "*", "23", "name", "class", "group",
"ctrllimited", "forcelimited", "ctrlrange", "inheritrange", "forcerange",
"lengthrange", "gear", "cranklength", "user",
"joint", "jointinparent", "tendon", "slidersite", "cranksite", "site", "refsite",
"kp", "kv", "dampratio", "timeconst"},
{"velocity", "*", "19", "name", "class", "group",
"ctrllimited", "forcelimited", "ctrlrange", "forcerange",
"lengthrange", "gear", "cranklength", "user",
"joint", "jointinparent", "tendon", "slidersite", "cranksite", "site", "refsite",
"kv"},
{"intvelocity", "*", "23", "name", "class", "group",
"ctrllimited", "forcelimited",
"ctrlrange", "forcerange", "actrange", "inheritrange", "lengthrange",
"gear", "cranklength", "user",
"joint", "jointinparent", "tendon", "slidersite", "cranksite", "site", "refsite",
"kp", "kv", "dampratio"},
{"damper", "*", "18", "name", "class", "group",
"forcelimited", "ctrlrange", "forcerange",
"lengthrange", "gear", "cranklength", "user",
"joint", "jointinparent", "tendon", "slidersite", "cranksite", "site", "refsite",
"kv"},
{"cylinder", "*", "22", "name", "class", "group",
"ctrllimited", "forcelimited", "ctrlrange", "forcerange",
"lengthrange", "gear", "cranklength", "user",
"joint", "jointinparent", "tendon", "slidersite", "cranksite", "site", "refsite",
"timeconst", "area", "diameter", "bias"},
{"muscle", "*", "26", "name", "class", "group",
"ctrllimited", "forcelimited", "ctrlrange", "forcerange",
"lengthrange", "gear", "cranklength", "user",
"joint", "jointinparent", "tendon", "slidersite", "cranksite",
"timeconst", "tausmooth", "range", "force", "scale",
"lmin", "lmax", "vmax", "fpmax", "fvmax"},
{"adhesion", "*", "9", "name", "class", "group",
"forcelimited", "ctrlrange", "forcerange", "user", "body", "gain"},
{"plugin", "*", "25", "name", "class", "plugin", "instance", "group",
"ctrllimited", "forcelimited", "actlimited", "ctrlrange", "forcerange", "actrange",
"lengthrange", "gear", "cranklength", "joint", "jointinparent",
"site", "actdim", "dyntype", "dynprm", "tendon", "cranksite", "slidersite", "user",
"actearly"},
{"<"},
{"config", "*", "2", "key", "value"},
{">"},
{">"},
{"sensor", "*", "0"},
{"<"},
{"touch", "*", "5", "name", "site", "cutoff", "noise", "user"},
{"accelerometer", "*", "5", "name", "site", "cutoff", "noise", "user"},
{"velocimeter", "*", "5", "name", "site", "cutoff", "noise", "user"},
{"gyro", "*", "5", "name", "site", "cutoff", "noise", "user"},
{"force", "*", "5", "name", "site", "cutoff", "noise", "user"},
{"torque", "*", "5", "name", "site", "cutoff", "noise", "user"},
{"magnetometer", "*", "5", "name", "site", "cutoff", "noise", "user"},
{"camprojection", "*", "6", "name", "site", "camera", "cutoff", "noise", "user"},
{"rangefinder", "*", "5", "name", "site", "cutoff", "noise", "user"},
{"jointpos", "*", "5", "name", "joint", "cutoff", "noise", "user"},
{"jointvel", "*", "5", "name", "joint", "cutoff", "noise", "user"},
{"tendonpos", "*", "5", "name", "tendon", "cutoff", "noise", "user"},
{"tendonvel", "*", "5", "name", "tendon", "cutoff", "noise", "user"},
{"actuatorpos", "*", "5", "name", "actuator", "cutoff", "noise", "user"},
{"actuatorvel", "*", "5", "name", "actuator", "cutoff", "noise", "user"},
{"actuatorfrc", "*", "5", "name", "actuator", "cutoff", "noise", "user"},
{"jointactuatorfrc", "*", "5", "name", "joint", "cutoff", "noise", "user"},
{"tendonactuatorfrc", "*", "5", "name", "tendon", "cutoff", "noise", "user"},
{"ballquat", "*", "5", "name", "joint", "cutoff", "noise", "user"},
{"ballangvel", "*", "5", "name", "joint", "cutoff", "noise", "user"},
{"jointlimitpos", "*", "5", "name", "joint", "cutoff", "noise", "user"},
{"jointlimitvel", "*", "5", "name", "joint", "cutoff", "noise", "user"},
{"jointlimitfrc", "*", "5", "name", "joint", "cutoff", "noise", "user"},
{"tendonlimitpos", "*", "5", "name", "tendon", "cutoff", "noise", "user"},
{"tendonlimitvel", "*", "5", "name", "tendon", "cutoff", "noise", "user"},
{"tendonlimitfrc", "*", "5", "name", "tendon", "cutoff", "noise", "user"},
{"framepos", "*", "8", "name", "objtype", "objname", "reftype", "refname", "cutoff", "noise", "user"},
{"framequat", "*", "8", "name", "objtype", "objname", "reftype", "refname", "cutoff", "noise", "user"},
{"framexaxis", "*", "8", "name", "objtype", "objname", "reftype", "refname", "cutoff", "noise", "user"},
{"frameyaxis", "*", "8", "name", "objtype", "objname", "reftype", "refname", "cutoff", "noise", "user"},
{"framezaxis", "*", "8", "name", "objtype", "objname", "reftype", "refname", "cutoff", "noise", "user"},
{"framelinvel", "*", "8", "name", "objtype", "objname", "reftype", "refname", "cutoff", "noise", "user"},
{"frameangvel", "*", "8", "name", "objtype", "objname", "reftype", "refname", "cutoff", "noise", "user"},
{"framelinacc", "*", "6", "name", "objtype", "objname", "cutoff", "noise", "user"},
{"frameangacc", "*", "6", "name", "objtype", "objname", "cutoff", "noise", "user"},
{"subtreecom", "*", "5", "name", "body", "cutoff", "noise", "user"},
{"subtreelinvel", "*", "5", "name", "body", "cutoff", "noise", "user"},
{"subtreeangmom", "*", "5", "name", "body", "cutoff", "noise", "user"},
{"insidesite", "*", "7", "name", "site", "objtype", "objname", "cutoff", "noise", "user"},
{"distance", "*", "8", "name", "geom1", "geom2", "body1", "body2", "cutoff", "noise", "user"},
{"normal", "*", "8", "name", "geom1", "geom2", "body1", "body2", "cutoff", "noise", "user"},
{"fromto", "*", "8", "name", "geom1", "geom2", "body1", "body2", "cutoff", "noise", "user"},
{"e_potential", "*", "4", "name", "cutoff", "noise", "user"},
{"e_kinetic", "*", "4", "name", "cutoff", "noise", "user"},
{"clock", "*", "4", "name", "cutoff", "noise", "user"},
{"user", "*", "9", "name", "objtype", "objname", "datatype", "needstage",
"dim", "cutoff", "noise", "user"},
{"plugin", "*", "9", "name", "plugin", "instance", "cutoff", "objtype", "objname", "reftype", "refname",
"user"},
{"<"},
{"config", "*", "2", "key", "value"},
{">"},
{">"},
{"keyframe", "*", "0"},
{"<"},
{"key", "*", "8", "name", "time", "qpos", "qvel", "act", "mpos", "mquat", "ctrl"},
{">"},
{">"}
};
//---------------------------------- MJCF keywords used in attributes ------------------------------
// coordinate type
const mjMap coordinate_map[2] = {
{"local", 0},
{"global", 1}
};
// angle type
const mjMap angle_map[2] = {
{"radian", 0},
{"degree", 1}
};
// bool type
const mjMap bool_map[2] = {
{"false", 0},
{"true", 1}
};
// fluidshape type
const mjMap fluid_map[2] = {
{"none", 0},
{"ellipsoid", 1}
};
// enable type
const mjMap enable_map[2] = {
{"disable", 0},
{"enable", 1}
};
// TFAuto type
const mjMap TFAuto_map[3] = {
{"false", 0},
{"true", 1},
{"auto", 2}
};
// joint type
const int joint_sz = 4;
const mjMap joint_map[joint_sz] = {
{"free", mjJNT_FREE},
{"ball", mjJNT_BALL},
{"slide", mjJNT_SLIDE},
{"hinge", mjJNT_HINGE}
};
// geom type
const mjMap geom_map[mjNGEOMTYPES] = {
{"plane", mjGEOM_PLANE},
{"hfield", mjGEOM_HFIELD},
{"sphere", mjGEOM_SPHERE},
{"capsule", mjGEOM_CAPSULE},
{"ellipsoid", mjGEOM_ELLIPSOID},
{"cylinder", mjGEOM_CYLINDER},
{"box", mjGEOM_BOX},
{"mesh", mjGEOM_MESH},
{"sdf", mjGEOM_SDF}
};
// camlight type
const int camlight_sz = 5;
const mjMap camlight_map[camlight_sz] = {
{"fixed", mjCAMLIGHT_FIXED},
{"track", mjCAMLIGHT_TRACK},
{"trackcom", mjCAMLIGHT_TRACKCOM},
{"targetbody", mjCAMLIGHT_TARGETBODY},
{"targetbodycom", mjCAMLIGHT_TARGETBODYCOM}
};
// light type
const int lighttype_sz = 4;
const mjMap lighttype_map[lighttype_sz] = {
{"spot", mjLIGHT_SPOT},
{"directional", mjLIGHT_DIRECTIONAL},
{"point", mjLIGHT_POINT},
{"image", mjLIGHT_IMAGE}
};
// texmat role type
const int texrole_sz = mjNTEXROLE - 1;
const mjMap texrole_map[texrole_sz] = {
{"rgb", mjTEXROLE_RGB},
{"occlusion", mjTEXROLE_OCCLUSION},
{"roughness", mjTEXROLE_ROUGHNESS},
{"metallic", mjTEXROLE_METALLIC},
{"normal", mjTEXROLE_NORMAL},
{"opacity", mjTEXROLE_OPACITY},
{"emissive", mjTEXROLE_EMISSIVE},
{"rgba", mjTEXROLE_RGBA},
{"orm", mjTEXROLE_ORM},
};
// integrator type
const int integrator_sz = 4;
const mjMap integrator_map[integrator_sz] = {
{"Euler", mjINT_EULER},
{"RK4", mjINT_RK4},
{"implicit", mjINT_IMPLICIT},
{"implicitfast", mjINT_IMPLICITFAST}
};
// cone type
const int cone_sz = 2;
const mjMap cone_map[cone_sz] = {
{"pyramidal", mjCONE_PYRAMIDAL},
{"elliptic", mjCONE_ELLIPTIC}
};
// Jacobian type
const int jac_sz = 3;
const mjMap jac_map[jac_sz] = {
{"dense", mjJAC_DENSE},
{"sparse", mjJAC_SPARSE},
{"auto", mjJAC_AUTO}
};
// solver type
const int solver_sz = 3;
const mjMap solver_map[solver_sz] = {
{"PGS", mjSOL_PGS},
{"CG", mjSOL_CG},
{"Newton", mjSOL_NEWTON}
};
// constraint type
const int equality_sz = 6;
const mjMap equality_map[equality_sz] = {
{"connect", mjEQ_CONNECT},
{"weld", mjEQ_WELD},
{"joint", mjEQ_JOINT},
{"tendon", mjEQ_TENDON},
{"flex", mjEQ_FLEX},
{"distance", mjEQ_DISTANCE}
};
// type for texture
const int texture_sz = 3;
const mjMap texture_map[texture_sz] = {
{"2d", mjTEXTURE_2D},
{"cube", mjTEXTURE_CUBE},
{"skybox", mjTEXTURE_SKYBOX}
};
// colorspace for texture
const int colorspace_sz = 3;
const mjMap colorspace_map[colorspace_sz] = {
{"auto", mjCOLORSPACE_AUTO},
{"linear", mjCOLORSPACE_LINEAR},
{"sRGB", mjCOLORSPACE_SRGB}
};
// builtin type for texture
const int builtin_sz = 4;
const mjMap builtin_map[builtin_sz] = {
{"none", mjBUILTIN_NONE},
{"gradient", mjBUILTIN_GRADIENT},
{"checker", mjBUILTIN_CHECKER},
{"flat", mjBUILTIN_FLAT}
};
// mark type for texture
const int mark_sz = 4;
const mjMap mark_map[mark_sz] = {
{"none", mjMARK_NONE},
{"edge", mjMARK_EDGE},
{"cross", mjMARK_CROSS},
{"random", mjMARK_RANDOM}
};
// dyn type
const int dyn_sz = 6;
const mjMap dyn_map[dyn_sz] = {
{"none", mjDYN_NONE},
{"integrator", mjDYN_INTEGRATOR},
{"filter", mjDYN_FILTER},
{"filterexact", mjDYN_FILTEREXACT},
{"muscle", mjDYN_MUSCLE},
{"user", mjDYN_USER}
};
// gain type
const int gain_sz = 4;
const mjMap gain_map[gain_sz] = {
{"fixed", mjGAIN_FIXED},
{"affine", mjGAIN_AFFINE},
{"muscle", mjGAIN_MUSCLE},
{"user", mjGAIN_USER}
};
// bias type
const int bias_sz = 4;
const mjMap bias_map[bias_sz] = {
{"none", mjBIAS_NONE},
{"affine", mjBIAS_AFFINE},
{"muscle", mjBIAS_MUSCLE},
{"user", mjBIAS_USER}
};
// stage type
const int stage_sz = 4;
const mjMap stage_map[stage_sz] = {
{"none", mjSTAGE_NONE},
{"pos", mjSTAGE_POS},
{"vel", mjSTAGE_VEL},
{"acc", mjSTAGE_ACC}
};
// data type
const int datatype_sz = 4;
const mjMap datatype_map[datatype_sz] = {
{"real", mjDATATYPE_REAL},
{"positive", mjDATATYPE_POSITIVE},
{"axis", mjDATATYPE_AXIS},
{"quaternion", mjDATATYPE_QUATERNION}
};
// LR mode
const int lrmode_sz = 4;
const mjMap lrmode_map[lrmode_sz] = {
{"none", mjLRMODE_NONE},
{"muscle", mjLRMODE_MUSCLE},
{"muscleuser", mjLRMODE_MUSCLEUSER},
{"all", mjLRMODE_ALL}
};
// composite type
const mjMap comp_map[mjNCOMPTYPES] = {
{"particle", mjCOMPTYPE_PARTICLE},
{"grid", mjCOMPTYPE_GRID},
{"rope", mjCOMPTYPE_ROPE},
{"loop", mjCOMPTYPE_LOOP},
{"cable", mjCOMPTYPE_CABLE},
{"cloth", mjCOMPTYPE_CLOTH}
};
// composite joint kind
const mjMap jkind_map[1] = {
{"main", mjCOMPKIND_JOINT}
};
// composite rope shape
const mjMap shape_map[mjNCOMPSHAPES] = {
{"s", mjCOMPSHAPE_LINE},
{"cos(s)", mjCOMPSHAPE_COS},
{"sin(s)", mjCOMPSHAPE_SIN},
{"0", mjCOMPSHAPE_ZERO}
};
// mesh type
const mjMap meshtype_map[2] = {
{"false", mjINERTIA_VOLUME},
{"true", mjINERTIA_SHELL},
};
// mesh inertia type
const mjMap meshinertia_map[4] = {
{"convex", mjMESH_INERTIA_CONVEX},
{"legacy", mjMESH_INERTIA_LEGACY},
{"exact", mjMESH_INERTIA_EXACT},
{"shell", mjMESH_INERTIA_SHELL}
};
// flexcomp type
const mjMap fcomp_map[mjNFCOMPTYPES] = {
{"grid", mjFCOMPTYPE_GRID},
{"box", mjFCOMPTYPE_BOX},
{"cylinder", mjFCOMPTYPE_CYLINDER},
{"ellipsoid", mjFCOMPTYPE_ELLIPSOID},
{"square", mjFCOMPTYPE_SQUARE},
{"disc", mjFCOMPTYPE_DISC},
{"circle", mjFCOMPTYPE_CIRCLE},
{"mesh", mjFCOMPTYPE_MESH},
{"gmsh", mjFCOMPTYPE_GMSH},
{"direct", mjFCOMPTYPE_DIRECT}
};
// flexcomp dof type
const mjMap fdof_map[mjNFCOMPDOFS] = {
{"full", mjFCOMPDOF_FULL},
{"radial", mjFCOMPDOF_RADIAL},
{"trilinear", mjFCOMPDOF_TRILINEAR}
};
// flex selfcollide type
const mjMap flexself_map[5] = {
{"none", mjFLEXSELF_NONE},
{"narrow", mjFLEXSELF_NARROW},
{"bvh", mjFLEXSELF_BVH},
{"sap", mjFLEXSELF_SAP},
{"auto", mjFLEXSELF_AUTO},
};
// flex elastic 2d type
const mjMap elastic2d_map[5] = {
{"none", 0},
{"bend", 1},
{"stretch", 2},
{"both", 3},
};
//---------------------------------- class mjXReader implementation --------------------------------
// constructor
mjXReader::mjXReader() : schema(MJCF, nMJCF) {
readingdefaults = false;
}
// print schema
void mjXReader::PrintSchema(std::stringstream& str, bool html, bool pad) {
if (html) {
schema.PrintHTML(str, 0, pad);
} else {
schema.Print(str, 0);
}
}
// main entry point for XML parser
// mjCModel is allocated here; caller is responsible for deallocation
void mjXReader::Parse(XMLElement* root, const mjVFS* vfs) {
// check schema
if (!schema.GetError().empty()) {
throw mjXError(0, "XML Schema Construction Error: %s", schema.GetError().c_str());
}
// validate
XMLElement* bad = 0;
if ((bad = schema.Check(root, 0))) {
throw mjXError(bad, "Schema violation: %s", schema.GetError().c_str());
}
// get model name
string modelname;
if (ReadAttrTxt(root, "model", modelname)) {
mjs_setString(spec->modelname, modelname.c_str());
}
// get comment
if (root->FirstChild() && root->FirstChild()->ToComment()) {
mjs_setString(spec->comment, root->FirstChild()->Value());
} else {
mjs_setString(spec->comment, "");
}
//------------------- parse MuJoCo sections embedded in all XML formats
for (XMLElement* section = FirstChildElement(root, "compiler"); section;
section = NextSiblingElement(section, "compiler")) {
Compiler(section, spec);
}
for (XMLElement* section = FirstChildElement(root, "option"); section;
section = NextSiblingElement(section, "option")) {
Option(section, &spec->option);
}
for (XMLElement* section = FirstChildElement(root, "size"); section;
section = NextSiblingElement(section, "size")) {
Size(section, spec);
}
//------------------ parse MJCF-specific sections
for (XMLElement* section = FirstChildElement(root, "visual"); section;
section = NextSiblingElement(section, "visual")) {
Visual(section);
}
for (XMLElement* section = FirstChildElement(root, "statistic"); section;
section = NextSiblingElement(section, "statistic")) {
Statistic(section);
}
readingdefaults = true;
for (XMLElement* section = FirstChildElement(root, "default"); section;
section = NextSiblingElement(section, "default")) {
Default(section, nullptr, vfs);
}
readingdefaults = false;
for (XMLElement* section = FirstChildElement(root, "extension"); section;
section = NextSiblingElement(section, "extension")) {
Extension(section);
}
for (XMLElement* section = FirstChildElement(root, "custom"); section;
section = NextSiblingElement(section, "custom")) {
Custom(section);
}
for (XMLElement* section = FirstChildElement(root, "asset"); section;
section = NextSiblingElement(section, "asset")) {
Asset(section, vfs);
}
for (XMLElement* section = FirstChildElement(root, "contact"); section;
section = NextSiblingElement(section, "contact")) {
Contact(section);
}
for (XMLElement* section = FirstChildElement(root, "deformable"); section;
section = NextSiblingElement(section, "deformable")) {
Deformable(section, vfs);
}
for (XMLElement* section = FirstChildElement(root, "equality"); section;
section = NextSiblingElement(section, "equality")) {
Equality(section);
}
for (XMLElement* section = FirstChildElement(root, "tendon"); section;
section = NextSiblingElement(section, "tendon")) {
Tendon(section);
}
for (XMLElement* section = FirstChildElement(root, "actuator"); section;
section = NextSiblingElement(section, "actuator")) {
Actuator(section);
}
for (XMLElement* section = FirstChildElement(root, "sensor"); section;
section = NextSiblingElement(section, "sensor")) {
Sensor(section);
}
for (XMLElement* section = FirstChildElement(root, "keyframe"); section;
section = NextSiblingElement(section, "keyframe")) {
Keyframe(section);
}
// set deepcopy flag to true to copy child specs during attach calls
mjs_setDeepCopy(spec, true);
for (XMLElement* section = FirstChildElement(root, "worldbody"); section;
section = NextSiblingElement(section, "worldbody")) {
Body(section, mjs_findBody(spec, "world"), nullptr, vfs);
}
// set deepcopy flag to false to disable copying during attach in all future calls
mjs_setDeepCopy(spec, false);
}
// compiler section parser
void mjXReader::Compiler(XMLElement* section, mjSpec* s) {
string text;
int n;
// top-level attributes
if (MapValue(section, "autolimits", &n, bool_map, 2)) {
s->compiler.autolimits = (n == 1);
}
ReadAttr(section, "boundmass", 1, &s->compiler.boundmass, text);
ReadAttr(section, "boundinertia", 1, &s->compiler.boundinertia, text);
ReadAttr(section, "settotalmass", 1, &s->compiler.settotalmass, text);
if (MapValue(section, "balanceinertia", &n, bool_map, 2)) {
s->compiler.balanceinertia = (n == 1);
}
if (MapValue(section, "strippath", &n, bool_map, 2)) {
s->strippath = (n == 1);
}
if (MapValue(section, "fitaabb", &n, bool_map, 2)) {
s->compiler.fitaabb = (n == 1);
}
if (MapValue(section, "coordinate", &n, coordinate_map, 2)) {
if (n == 1) {
throw mjXError(section, "global coordinates no longer supported. To convert existing models, "
"load and save them in MuJoCo 2.3.3 or older");
}
}
if (MapValue(section, "angle", &n, angle_map, 2)) {
s->compiler.degree = (n == 1);
}
if (ReadAttrTxt(section, "eulerseq", text)) {
if (text.size() != 3) {
throw mjXError(section, "euler format must have length 3");
}
memcpy(s->compiler.eulerseq, text.c_str(), 3);
}
if (ReadAttrTxt(section, "assetdir", text)) {
mjs_setString(s->meshdir, text.c_str());
mjs_setString(s->texturedir, text.c_str());
}
// meshdir and texturedir take precedence over assetdir
string meshdir, texturedir;
if (ReadAttrTxt(section, "meshdir", meshdir)) {
mjs_setString(s->meshdir, meshdir.c_str());
};
if (ReadAttrTxt(section, "texturedir", texturedir)) {
mjs_setString(s->texturedir, texturedir.c_str());
}
if (MapValue(section, "discardvisual", &n, bool_map, 2)) {
s->compiler.discardvisual = (n == 1);
}
if (MapValue(section, "usethread", &n, bool_map, 2)) {
s->compiler.usethread = (n == 1);
}
if (MapValue(section, "fusestatic", &n, bool_map, 2)) {
s->compiler.fusestatic = (n == 1);
}
MapValue(section, "inertiafromgeom", &s->compiler.inertiafromgeom, TFAuto_map, 3);
ReadAttr(section, "inertiagrouprange", 2, s->compiler.inertiagrouprange, text);
if (MapValue(section, "alignfree", &n, bool_map, 2)) {
s->compiler.alignfree = (n == 1);
}
if (MapValue(section, "saveinertial", &n, bool_map, 2)) {
s->compiler.saveinertial = (n == 1);
}
// lengthrange subelement
XMLElement* elem = FindSubElem(section, "lengthrange");
if (elem) {
mjLROpt* opt = &(s->compiler.LRopt);
// flags
MapValue(elem, "mode", &opt->mode, lrmode_map, lrmode_sz);
if (MapValue(elem, "useexisting", &n, bool_map, 2)) {
opt->useexisting = (n == 1);
}
if (MapValue(elem, "uselimit", &n, bool_map, 2)) {
opt->uselimit = (n == 1);
}
// algorithm parameters
ReadAttr(elem, "accel", 1, &opt->accel, text);
ReadAttr(elem, "maxforce", 1, &opt->maxforce, text);
ReadAttr(elem, "timeconst", 1, &opt->timeconst, text);
ReadAttr(elem, "timestep", 1, &opt->timestep, text);
ReadAttr(elem, "inttotal", 1, &opt->inttotal, text);
ReadAttr(elem, "interval", 1, &opt->interval, text);
ReadAttr(elem, "tolrange", 1, &opt->tolrange, text);
}
}
// option section parser
void mjXReader::Option(XMLElement* section, mjOption* opt) {
string text;
int n;
// read options
ReadAttr(section, "timestep", 1, &opt->timestep, text);
ReadAttr(section, "apirate", 1, &opt->apirate, text);
ReadAttr(section, "impratio", 1, &opt->impratio, text);
ReadAttr(section, "tolerance", 1, &opt->tolerance, text);
ReadAttr(section, "ls_tolerance", 1, &opt->ls_tolerance, text);
ReadAttr(section, "noslip_tolerance", 1, &opt->noslip_tolerance, text);
ReadAttr(section, "ccd_tolerance", 1, &opt->ccd_tolerance, text);
ReadAttr(section, "gravity", 3, opt->gravity, text);
ReadAttr(section, "wind", 3, opt->wind, text);
ReadAttr(section, "magnetic", 3, opt->magnetic, text);
ReadAttr(section, "density", 1, &opt->density, text);
ReadAttr(section, "viscosity", 1, &opt->viscosity, text);
ReadAttr(section, "o_margin", 1, &opt->o_margin, text);
ReadAttr(section, "o_solref", mjNREF, opt->o_solref, text, false, false);
ReadAttr(section, "o_solimp", mjNIMP, opt->o_solimp, text, false, false);
ReadAttr(section, "o_friction", 5, opt->o_friction, text, false, false);
MapValue(section, "integrator", &opt->integrator, integrator_map, integrator_sz);
MapValue(section, "cone", &opt->cone, cone_map, cone_sz);
MapValue(section, "jacobian", &opt->jacobian, jac_map, jac_sz);
MapValue(section, "solver", &opt->solver, solver_map, solver_sz);
ReadAttrInt(section, "iterations", &opt->iterations);
ReadAttrInt(section, "ls_iterations", &opt->ls_iterations);
ReadAttrInt(section, "noslip_iterations", &opt->noslip_iterations);
ReadAttrInt(section, "ccd_iterations", &opt->ccd_iterations);
ReadAttrInt(section, "sdf_iterations", &opt->sdf_iterations);
ReadAttrInt(section, "sdf_initpoints", &opt->sdf_initpoints);
// actuatorgroupdisable
constexpr int num_bitflags = 31;
int disabled_act_groups[num_bitflags];
int num_found = ReadAttr(section, "actuatorgroupdisable", num_bitflags, disabled_act_groups,
text, false, false);
for (int i=0; i < num_found; i++) {
int group = disabled_act_groups[i];
if (group < 0) {
throw mjXError(section, "disabled actuator group value must be non-negative");
}
if (group > num_bitflags - 1) {
throw mjXError(section, "disabled actuator group value cannot exceed 30");
}
opt->disableactuator |= (1 << group);
}
// read disable sub-element
XMLElement* elem = FindSubElem(section, "flag");
if (elem) {
#define READDSBL(NAME, MASK) \
if (MapValue(elem, NAME, &n, enable_map, 2)) { \
opt->disableflags ^= (opt->disableflags & MASK); \
opt->disableflags |= (n ? 0 : MASK); }
READDSBL("constraint", mjDSBL_CONSTRAINT)
READDSBL("equality", mjDSBL_EQUALITY)
READDSBL("frictionloss", mjDSBL_FRICTIONLOSS)
READDSBL("limit", mjDSBL_LIMIT)
READDSBL("contact", mjDSBL_CONTACT)
READDSBL("passive", mjDSBL_PASSIVE)
READDSBL("gravity", mjDSBL_GRAVITY)
READDSBL("clampctrl", mjDSBL_CLAMPCTRL)
READDSBL("warmstart", mjDSBL_WARMSTART)
READDSBL("filterparent", mjDSBL_FILTERPARENT)
READDSBL("actuation", mjDSBL_ACTUATION)
READDSBL("refsafe", mjDSBL_REFSAFE)
READDSBL("sensor", mjDSBL_SENSOR)
READDSBL("midphase", mjDSBL_MIDPHASE)
READDSBL("eulerdamp", mjDSBL_EULERDAMP)
READDSBL("autoreset", mjDSBL_AUTORESET)
READDSBL("nativeccd", mjDSBL_NATIVECCD)
#undef READDSBL
#define READENBL(NAME, MASK) \
if (MapValue(elem, NAME, &n, enable_map, 2)) { \
opt->enableflags ^= (opt->enableflags & MASK); \
opt->enableflags |= (n ? MASK : 0); }
READENBL("override", mjENBL_OVERRIDE)
READENBL("energy", mjENBL_ENERGY)
READENBL("fwdinv", mjENBL_FWDINV)
READENBL("invdiscrete", mjENBL_INVDISCRETE)
READENBL("multiccd", mjENBL_MULTICCD)
READENBL("island", mjENBL_ISLAND)
#undef READENBL
}
}
// size section parser
void mjXReader::Size(XMLElement* section, mjSpec* s) {
// read memory bytes
{
constexpr char err_msg[] =
"unsigned integer with an optional suffix {K,M,G,T,P,E} is expected in "
"attribute 'memory' (or the size specified is too big)";
auto memory = [&]() -> std::optional<std::size_t> {
const char* pstr = section->Attribute("memory");
if (!pstr) {
return std::nullopt;
}
// trim entire string
string trimmed;
{
std::istringstream strm((string(pstr)));
strm >> trimmed;
string trailing;
strm >> trailing;
if (!trailing.empty() || !strm.eof()) {
throw mjXError(section, "%s", err_msg);
}
// allow explicit specification of the default "-1" value
if (trimmed == "-1") {
return std::nullopt;
}
}
std::istringstream strm(trimmed);
// check that the number is not negative
if (strm.peek() == '-') {
throw mjXError(section, "%s", err_msg);
}
std::size_t base_size;
strm >> base_size;
if (strm.fail()) {
// either not an integer or the number without the suffix is already bigger than size_t
throw mjXError(section, "%s", err_msg);
}
// parse the multiplier suffix
int multiplier_bit = 0;
if (!strm.eof()) {
char suffix = strm.get();
if (suffix == 'K' || suffix == 'k') {
multiplier_bit = 10;
} else if (suffix == 'M' || suffix == 'm') {
multiplier_bit = 20;
} else if (suffix == 'G' || suffix == 'g') {
multiplier_bit = 30;
} else if (suffix == 'T' || suffix == 't') {
multiplier_bit = 40;
} else if (suffix == 'P' || suffix == 'p') {
multiplier_bit = 50;
} else if (suffix == 'E' || suffix == 'e') {
multiplier_bit = 60;
}
// check for invalid suffix, or suffix longer than one character
strm.get();
if (!multiplier_bit || !strm.eof()) {
throw mjXError(section, "%s", err_msg);
}
}
// check that the specified suffix isn't bigger than size_t
if (multiplier_bit + 1 > std::numeric_limits<std::size_t>::digits) {
throw mjXError(section, "%s", err_msg);
}
// check that the suffix won't take the total size beyond size_t
const std::size_t max_base_size =
(std::numeric_limits<std::size_t>::max() << multiplier_bit) >> multiplier_bit;
if (base_size > max_base_size) {
throw mjXError(section, "%s", err_msg);
}
const std::size_t total_size = base_size << multiplier_bit;
return total_size;
}();
if (memory.has_value()) {
if (*memory / sizeof(mjtNum) > std::numeric_limits<std::size_t>::max()) {
throw mjXError(section, "%s", err_msg);
}
s->memory = *memory;
}
}
// read sizes
ReadAttrInt(section, "nuserdata", &s->nuserdata);
ReadAttrInt(section, "nkey", &s->nkey);
ReadAttrInt(section, "nconmax", &s->nconmax);
if (s->nconmax < -1) throw mjXError(section, "nconmax must be >= -1");
{
int nstack = -1;
const bool has_nstack = ReadAttrInt(section, "nstack", &nstack);
if (has_nstack) {
if (s->nstack < -1) {
throw mjXError(section, "nstack must be >= -1");
}
if (s->memory != -1 && nstack != -1) {
throw mjXError(section,
"either 'memory' and 'nstack' attribute can be specified, not both");
}
s->nstack = nstack;
}
}
{
int njmax = -1;
const bool has_njmax = ReadAttrInt(section, "njmax", &njmax);
if (has_njmax) {
if (s->njmax < -1) {
throw mjXError(section, "njmax must be >= -1");
}
if (s->memory != -1 && njmax != -1) {
throw mjXError(section,
"either 'memory' and 'njmax' attribute can be specified, not both");
}
s->njmax = njmax;
}
}
ReadAttrInt(section, "nuser_body", &s->nuser_body);
if (s->nuser_body < -1) throw mjXError(section, "nuser_body must be >= -1");
ReadAttrInt(section, "nuser_jnt", &s->nuser_jnt);
if (s->nuser_jnt < -1) throw mjXError(section, "nuser_jnt must be >= -1");
ReadAttrInt(section, "nuser_geom", &s->nuser_geom);
if (s->nuser_geom < -1) throw mjXError(section, "nuser_geom must be >= -1");
ReadAttrInt(section, "nuser_site", &s->nuser_site);
if (s->nuser_site < -1) throw mjXError(section, "nuser_site must be >= -1");
ReadAttrInt(section, "nuser_cam", &s->nuser_cam);
if (s->nuser_cam < -1) throw mjXError(section, "nuser_cam must be >= -1");
ReadAttrInt(section, "nuser_tendon", &s->nuser_tendon);
if (s->nuser_tendon < -1) throw mjXError(section, "nuser_tendon must be >= -1");
ReadAttrInt(section, "nuser_actuator", &s->nuser_actuator);
if (s->nuser_actuator < -1) throw mjXError(section, "nuser_actuator must be >= -1");
ReadAttrInt(section, "nuser_sensor", &s->nuser_sensor);
if (s->nuser_sensor < -1) throw mjXError(section, "nuser_sensor must be >= -1");
}
// statistic section parser
void mjXReader::Statistic(XMLElement* section) {
string text;
// read statistics
ReadAttr(section, "meaninertia", 1, &spec->stat.meaninertia, text);
ReadAttr(section, "meanmass", 1, &spec->stat.meanmass, text);
ReadAttr(section, "meansize", 1, &spec->stat.meansize, text);
ReadAttr(section, "extent", 1, &spec->stat.extent, text);
if (mjuu_defined(spec->stat.extent) && spec->stat.extent <= 0) {
throw mjXError(section, "extent must be strictly positive");
}
ReadAttr(section, "center", 3, spec->stat.center, text);
}
//---------------------------------- one-element parsers -------------------------------------------
// flex element parser
void mjXReader::OneFlex(XMLElement* elem, mjsFlex* flex) {
string text, name, material, nodebody;
int n;
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(flex->element, name.c_str());
}
if (ReadAttrTxt(elem, "material", material)) {
mjs_setString(flex->material, material.c_str());
}
ReadAttr(elem, "radius", 1, &flex->radius, text);
ReadAttr(elem, "rgba", 4, flex->rgba, text);
if (MapValue(elem, "flatskin", &n, bool_map, 2)) {
flex->flatskin = (n == 1);
}
ReadAttrInt(elem, "dim", &flex->dim);
ReadAttrInt(elem, "group", &flex->group);
// read data vectors
if (ReadAttrTxt(elem, "body", text, true)) {
mjs_setStringVec(flex->vertbody, text.c_str());
}
if (ReadAttrTxt(elem, "node", nodebody)) {
mjs_setStringVec(flex->nodebody, nodebody.c_str());
}
auto vert = ReadAttrVec<double>(elem, "vertex");
if (vert.has_value()) {
mjs_setDouble(flex->vert, vert->data(), vert->size());
}
auto element = ReadAttrVec<int>(elem, "element", true);
if (element.has_value()) {
mjs_setInt(flex->elem, element->data(), element->size());
}
auto texcoord = ReadAttrVec<float>(elem, "texcoord");
if (texcoord.has_value()) {
mjs_setFloat(flex->texcoord, texcoord->data(), texcoord->size());
}
auto elemtexcoord = ReadAttrVec<int>(elem, "elemtexcoord");
if (elemtexcoord.has_value()) {
mjs_setInt(flex->elemtexcoord, elemtexcoord->data(), elemtexcoord->size());
}
// contact subelement
XMLElement* cont = FirstChildElement(elem, "contact");
if (cont) {
ReadAttrInt(cont, "contype", &flex->contype);
ReadAttrInt(cont, "conaffinity", &flex->conaffinity);
ReadAttrInt(cont, "condim", &flex->condim);
ReadAttrInt(cont, "priority", &flex->priority);
ReadAttr(cont, "friction", 3, flex->friction, text, false, false);
ReadAttr(cont, "solmix", 1, &flex->solmix, text);
ReadAttr(cont, "solref", mjNREF, flex->solref, text, false, false);
ReadAttr(cont, "solimp", mjNIMP, flex->solimp, text, false, false);
ReadAttr(cont, "margin", 1, &flex->margin, text);
ReadAttr(cont, "gap", 1, &flex->gap, text);
if (MapValue(cont, "internal", &n, bool_map, 2)) {
flex->internal = (n == 1);
}
MapValue(cont, "selfcollide", &flex->selfcollide, flexself_map, 5);
if (MapValue(cont, "vertcollide", &flex->vertcollide, bool_map, 2)) {
flex->vertcollide = (n == 1);
}
ReadAttrInt(cont, "activelayers", &flex->activelayers);
}
// edge subelement
XMLElement* edge = FirstChildElement(elem, "edge");
if (edge) {
ReadAttr(edge, "stiffness", 1, &flex->edgestiffness, text);
ReadAttr(edge, "damping", 1, &flex->edgedamping, text);
}
// elasticity subelement
XMLElement* elasticity = FirstChildElement(elem, "elasticity");
if (elasticity) {
ReadAttr(elasticity, "young", 1, &flex->young, text);
ReadAttr(elasticity, "poisson", 1, &flex->poisson, text);
ReadAttr(elasticity, "thickness", 1, &flex->thickness, text);
ReadAttr(elasticity, "damping", 1, &flex->damping, text);
MapValue(elasticity, "elastic2d", &flex->elastic2d, elastic2d_map, 4);
}
// write error info
mjs_setString(flex->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// mesh element parser
void mjXReader::OneMesh(XMLElement* elem, mjsMesh* mesh, const mjVFS* vfs) {
int n;
string text, name, content_type;
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(mesh->element, name.c_str());
}
if (ReadAttrTxt(elem, "content_type", content_type)) {
*mesh->content_type = content_type;
}
auto file = ReadAttrFile(elem, "file", vfs, MeshDir());
if (file) {
mjs_setString(mesh->file, file->c_str());
}
ReadAttr(elem, "refpos", 3, mesh->refpos, text);
ReadAttr(elem, "refquat", 4, mesh->refquat, text);
ReadAttr(elem, "scale", 3, mesh->scale, text);
if (MapValue(elem, "inertia", &n, meshinertia_map, 4)) {
mesh->inertia = (mjtMeshInertia)n;
}
XMLElement* eplugin = FirstChildElement(elem, "plugin");
if (eplugin) {
OnePlugin(eplugin, &mesh->plugin);
}
if (MapValue(elem, "smoothnormal", &n, bool_map, 2)) {
mesh->smoothnormal = (n == 1);
}
if (ReadAttrInt(elem, "maxhullvert", &n)) {
if (n != -1 && n < 4) throw mjXError(elem, "maxhullvert must be larger than 3");
mesh->maxhullvert = n;
}
// read user vertex data
if (ReadAttrTxt(elem, "vertex", text)) {
auto uservert = ReadAttrVec<float>(elem, "vertex");
if (uservert.has_value()) {
mjs_setFloat(mesh->uservert, uservert->data(), uservert->size());
}
}
// read user normal data
if (ReadAttrTxt(elem, "normal", text)) {
auto usernormal = ReadAttrVec<float>(elem, "normal");
if (usernormal.has_value()) {
mjs_setFloat(mesh->usernormal, usernormal->data(), usernormal->size());
}
}
// read user texcoord data
if (ReadAttrTxt(elem, "texcoord", text)) {
auto usertexcoord = ReadAttrVec<float>(elem, "texcoord");
if (usertexcoord.has_value()) {
mjs_setFloat(mesh->usertexcoord, usertexcoord->data(), usertexcoord->size());
}
}
// read user face data
if (ReadAttrTxt(elem, "face", text)) {
auto userface = ReadAttrVec<int>(elem, "face");
if (userface.has_value()) {
mjs_setInt(mesh->userface, userface->data(), userface->size());
}
}
// write error info
mjs_setString(mesh->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// skin element parser
void mjXReader::OneSkin(XMLElement* elem, mjsSkin* skin, const mjVFS* vfs) {
string text, name, material;
float data[4];
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(skin->element, name.c_str());
}
auto file = ReadAttrFile(elem, "file", vfs, AssetDir());
if (file.has_value()) {
mjs_setString(skin->file, file->c_str());
}
if (ReadAttrTxt(elem, "material", material)) {
mjs_setString(skin->material, material.c_str());
}
ReadAttrInt(elem, "group", &skin->group);
if (skin->group < 0 || skin->group >= mjNGROUP) {
throw mjXError(elem, "skin group must be between 0 and 5");
}
ReadAttr(elem, "rgba", 4, skin->rgba, text);
ReadAttr(elem, "inflate", 1, &skin->inflate, text);
// read vertex data
auto vertex = ReadAttrVec<float>(elem, "vertex");
if (vertex.has_value()) {
mjs_setFloat(skin->vert, vertex->data(), vertex->size());
}
// read texcoord data
auto texcoord = ReadAttrVec<float>(elem, "texcoord");
if (texcoord.has_value()) {
mjs_setFloat(skin->texcoord, texcoord->data(), texcoord->size());
}
// read user face data
auto face = ReadAttrVec<int>(elem, "face");
if (face.has_value()) {
mjs_setInt(skin->face, face->data(), face->size());
}
// read bones
XMLElement* bone = FirstChildElement(elem, "bone");
std::vector<float> bindpos;
std::vector<float> bindquat;
while (bone) {
// read body
ReadAttrTxt(bone, "body", text, true);
mjs_appendString(skin->bodyname, text.c_str());
// read bindpos
ReadAttr(bone, "bindpos", 3, data, text, true);
bindpos.push_back(data[0]);
bindpos.push_back(data[1]);
bindpos.push_back(data[2]);
// read bindquat
ReadAttr(bone, "bindquat", 4, data, text, true);
bindquat.push_back(data[0]);
bindquat.push_back(data[1]);
bindquat.push_back(data[2]);
bindquat.push_back(data[3]);
// read vertid
auto tempid = ReadAttrVec<int>(bone, "vertid", true);
if (tempid.has_value()) {
mjs_appendIntVec(skin->vertid, tempid->data(), tempid->size());
}
// read vertweight
auto tempweight = ReadAttrVec<float>(bone, "vertweight", true);
if (tempweight.has_value()) {
mjs_appendFloatVec(skin->vertweight, tempweight->data(), tempweight->size());
}
// advance to next bone
bone = NextSiblingElement(bone, "bone");
}
// set bind vectors
mjs_setFloat(skin->bindpos, bindpos.data(), bindpos.size());
mjs_setFloat(skin->bindquat, bindquat.data(), bindquat.size());
// write error info
mjs_setString(skin->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// material element parser
void mjXReader::OneMaterial(XMLElement* elem, mjsMaterial* material) {
string text, name, texture;
int n;
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(material->element, name.c_str());
}
bool tex_attributes_found = false;
if (ReadAttrTxt(elem, "texture", texture)) {
mjs_setInStringVec(material->textures, mjTEXROLE_RGB, texture.c_str());
tex_attributes_found = true;
}
XMLElement* layer = FirstChildElement(elem);
while (layer) {
if (tex_attributes_found) {
throw mjXError(layer, "A material with a texture attribute cannot have layer sub-elements");
}
// layer sub-element
ReadAttrTxt(layer, "role", text, true);
int role = FindKey(texrole_map, texrole_sz, text);
ReadAttrTxt(layer, "texture", text, true);
mjs_setInStringVec(material->textures, role, text.c_str());
layer = NextSiblingElement(layer);
}
if (MapValue(elem, "texuniform", &n, bool_map, 2)) {
material->texuniform = (n == 1);
}
ReadAttr(elem, "texrepeat", 2, material->texrepeat, text);
ReadAttr(elem, "emission", 1, &material->emission, text);
ReadAttr(elem, "specular", 1, &material->specular, text);
ReadAttr(elem, "shininess", 1, &material->shininess, text);
ReadAttr(elem, "reflectance", 1, &material->reflectance, text);
ReadAttr(elem, "metallic", 1, &material->metallic, text);
ReadAttr(elem, "roughness", 1, &material->roughness, text);
ReadAttr(elem, "rgba", 4, material->rgba, text);
// write error info
mjs_setString(material->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// joint element parser
void mjXReader::OneJoint(XMLElement* elem, mjsJoint* joint) {
string text, name;
std::vector<double> userdata;
int n;
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(joint->element, name.c_str());
}
if (MapValue(elem, "type", &n, joint_map, joint_sz)) {
joint->type = (mjtJoint)n;
}
MapValue(elem, "limited", &joint->limited, TFAuto_map, 3);
MapValue(elem, "actuatorfrclimited", &joint->actfrclimited, TFAuto_map, 3);
ReadAttrInt(elem, "group", &joint->group);
ReadAttr(elem, "solreflimit", mjNREF, joint->solref_limit, text, false, false);
ReadAttr(elem, "solimplimit", mjNIMP, joint->solimp_limit, text, false, false);
ReadAttr(elem, "solreffriction", mjNREF, joint->solref_friction, text, false, false);
ReadAttr(elem, "solimpfriction", mjNIMP, joint->solimp_friction, text, false, false);
ReadAttr(elem, "pos", 3, joint->pos, text);
ReadAttr(elem, "axis", 3, joint->axis, text);
ReadAttr(elem, "springdamper", 2, joint->springdamper, text);
ReadAttr(elem, "stiffness", 1, &joint->stiffness, text);
ReadAttr(elem, "range", 2, joint->range, text);
ReadAttr(elem, "actuatorfrcrange", 2, joint->actfrcrange, text);
ReadAttr(elem, "margin", 1, &joint->margin, text);
ReadAttr(elem, "ref", 1, &joint->ref, text);
ReadAttr(elem, "springref", 1, &joint->springref, text);
ReadAttr(elem, "armature", 1, &joint->armature, text);
ReadAttr(elem, "damping", 1, &joint->damping, text);
ReadAttr(elem, "frictionloss", 1, &joint->frictionloss, text);
if (MapValue(elem, "actuatorgravcomp", &n, bool_map, 2)) {
joint->actgravcomp = (n == 1);
}
// read userdata
if (ReadVector(elem, "user", userdata, text)) {
mjs_setDouble(joint->userdata, userdata.data(), userdata.size());
}
// write error info
mjs_setString(joint->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// geom element parser
void mjXReader::OneGeom(XMLElement* elem, mjsGeom* geom) {
string text, name;
std::vector<double> userdata;
string hfieldname, meshname, material;
int n;
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(geom->element, name.c_str());
}
if (MapValue(elem, "type", &n, geom_map, mjNGEOMTYPES)) {
geom->type = (mjtGeom)n;
}
ReadAttr(elem, "size", 3, geom->size, text, false, false);
ReadAttrInt(elem, "contype", &geom->contype);
ReadAttrInt(elem, "conaffinity", &geom->conaffinity);
ReadAttrInt(elem, "condim", &geom->condim);
ReadAttrInt(elem, "group", &geom->group);
ReadAttrInt(elem, "priority", &geom->priority);
ReadAttr(elem, "friction", 3, geom->friction, text, false, false);
ReadAttr(elem, "solmix", 1, &geom->solmix, text);
ReadAttr(elem, "solref", mjNREF, geom->solref, text, false, false);
ReadAttr(elem, "solimp", mjNIMP, geom->solimp, text, false, false);
ReadAttr(elem, "margin", 1, &geom->margin, text);
ReadAttr(elem, "gap", 1, &geom->gap, text);
if (ReadAttrTxt(elem, "hfield", hfieldname)) {
mjs_setString(geom->hfieldname, hfieldname.c_str());
}
if (ReadAttrTxt(elem, "mesh", meshname)) {
mjs_setString(geom->meshname, meshname.c_str());
}
ReadAttr(elem, "fitscale", 1, &geom->fitscale, text);
if (ReadAttrTxt(elem, "material", material)) {
mjs_setString(geom->material, material.c_str());
}
ReadAttr(elem, "rgba", 4, geom->rgba, text);
if (MapValue(elem, "fluidshape", &n, fluid_map, 2)) {
geom->fluid_ellipsoid = (n == 1);
}
ReadAttr(elem, "fluidcoef", 5, geom->fluid_coefs, text, false, false);
// read userdata
if (ReadVector(elem, "user", userdata, text)) {
mjs_setDouble(geom->userdata, userdata.data(), userdata.size());
}
// plugin sub-element
XMLElement* eplugin = FirstChildElement(elem, "plugin");
if (eplugin) {
OnePlugin(eplugin, &geom->plugin);
}
// remaining attributes
ReadAttr(elem, "mass", 1, &geom->mass, text);
ReadAttr(elem, "density", 1, &geom->density, text);
ReadAttr(elem, "fromto", 6, geom->fromto, text);
ReadAttr(elem, "pos", 3, geom->pos, text);
ReadQuat(elem, "quat", geom->quat, text);
ReadAlternative(elem, geom->alt);
// compute inertia using either solid or shell geometry
if (MapValue(elem, "shellinertia", &n, meshtype_map, 2)) {
geom->typeinertia = (mjtGeomInertia)n;
}
// write error info
mjs_setString(geom->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// site element parser
void mjXReader::OneSite(XMLElement* elem, mjsSite* site) {
int n;
string text, name;
std::vector<double> userdata;
string material;
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(site->element, name.c_str());
}
if (MapValue(elem, "type", &n, geom_map, mjNGEOMTYPES)) {
site->type = (mjtGeom)n;
}
ReadAttr(elem, "size", 3, site->size, text, false, false);
ReadAttrInt(elem, "group", &site->group);
ReadAttr(elem, "pos", 3, site->pos, text);
ReadQuat(elem, "quat", site->quat, text);
if (ReadAttrTxt(elem, "material", material)) {
mjs_setString(site->material, material.c_str());
}
ReadAttr(elem, "rgba", 4, site->rgba, text);
ReadAttr(elem, "fromto", 6, site->fromto, text);
ReadAlternative(elem, site->alt);
if (ReadVector(elem, "user", userdata, text)) {
mjs_setDouble(site->userdata, userdata.data(), userdata.size());
}
// write error info
mjs_setString(site->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// camera element parser
void mjXReader::OneCamera(XMLElement* elem, mjsCamera* camera) {
int n;
string text, name, targetbody;
std::vector<double> userdata;
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(camera->element, name.c_str());
}
if (ReadAttrTxt(elem, "target", targetbody)) {
mjs_setString(camera->targetbody, targetbody.c_str());
}
if (MapValue(elem, "mode", &n, camlight_map, camlight_sz)) {
camera->mode = (mjtCamLight)n;
}
ReadAttr(elem, "pos", 3, camera->pos, text);
ReadQuat(elem, "quat", camera->quat, text);
ReadAlternative(elem, camera->alt);
ReadAttr(elem, "ipd", 1, &camera->ipd, text);
if (MapValue(elem, "orthographic", &n, bool_map, 2)) {
camera->orthographic = (n == 1);
}
bool has_principal = ReadAttr(elem, "principalpixel", 2, camera->principal_pixel, text) ||
ReadAttr(elem, "principal", 2, camera->principal_length, text);
bool has_focal = ReadAttr(elem, "focalpixel", 2, camera->focal_pixel, text) ||
ReadAttr(elem, "focal", 2, camera->focal_length, text);
bool needs_sensorsize = has_principal || has_focal;
bool has_sensorsize = ReadAttr(elem, "sensorsize", 2, camera->sensor_size, text, needs_sensorsize);
bool has_fovy = ReadAttr(elem, "fovy", 1, &camera->fovy, text);
bool needs_resolution = has_focal || has_sensorsize;
ReadAttr(elem, "resolution", 2, camera->resolution, text, needs_resolution);
if (camera->resolution[0] < 0 || camera->resolution[1] < 0) {
throw mjXError(elem, "camera resolution cannot be negative");
}
if (has_fovy && has_sensorsize) {
throw mjXError(
elem,
"either 'fovy' or 'sensorsize' attribute can be specified, not both");
}
// read userdata
ReadVector(elem, "user", userdata, text);
mjs_setDouble(camera->userdata, userdata.data(), userdata.size());
// write error info
mjs_setString(camera->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// light element parser
void mjXReader::OneLight(XMLElement* elem, mjsLight* light) {
int n;
bool has_directional = false;
string text, name, texture, targetbody;
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(light->element, name.c_str());
}
if (ReadAttrTxt(elem, "texture", texture)) {
mjs_setString(light->texture, texture.c_str());
}
if (ReadAttrTxt(elem, "target", targetbody)) {
mjs_setString(light->targetbody, targetbody.c_str());
}
if (MapValue(elem, "mode", &n, camlight_map, camlight_sz)) {
light->mode = (mjtCamLight)n;
}
if (MapValue(elem, "directional", &n, bool_map, 2)) {
light->type = (n == 1) ? mjLIGHT_DIRECTIONAL : mjLIGHT_SPOT;
has_directional = true;
}
if (MapValue(elem, "type", &n, lighttype_map, lighttype_sz)) {
if (has_directional) {
throw mjXError(elem, "type and directional cannot both be defined");
}
light->type = (mjtLightType)n;
}
if (MapValue(elem, "castshadow", &n, bool_map, 2)) {
light->castshadow = (n == 1);
}
if (MapValue(elem, "active", &n, bool_map, 2)) {
light->active = (n == 1);
}
ReadAttr(elem, "pos", 3, light->pos, text);
ReadAttr(elem, "dir", 3, light->dir, text);
ReadAttr(elem, "bulbradius", 1, &light->bulbradius, text);
ReadAttr(elem, "intensity", 1, &light->intensity, text);
ReadAttr(elem, "range", 1, &light->range, text);
ReadAttr(elem, "attenuation", 3, light->attenuation, text);
ReadAttr(elem, "cutoff", 1, &light->cutoff, text);
ReadAttr(elem, "exponent", 1, &light->exponent, text);
ReadAttr(elem, "ambient", 3, light->ambient, text);
ReadAttr(elem, "diffuse", 3, light->diffuse, text);
ReadAttr(elem, "specular", 3, light->specular, text);
// write error info
mjs_setString(light->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// pair element parser
void mjXReader::OnePair(XMLElement* elem, mjsPair* pair) {
string text, name, geomname1, geomname2;
// regular only
if (!readingdefaults) {
if (ReadAttrTxt(elem, "geom1", geomname1)) {
mjs_setString(pair->geomname1, geomname1.c_str());
}
if (ReadAttrTxt(elem, "geom2", geomname2)) {
mjs_setString(pair->geomname2, geomname2.c_str());
}
}
// read other parameters
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(pair->element, name.c_str());
}
ReadAttrInt(elem, "condim", &pair->condim);
ReadAttr(elem, "solref", mjNREF, pair->solref, text, false, false);
ReadAttr(elem, "solreffriction", mjNREF, pair->solreffriction, text, false, false);
ReadAttr(elem, "solimp", mjNIMP, pair->solimp, text, false, false);
ReadAttr(elem, "margin", 1, &pair->margin, text);
ReadAttr(elem, "gap", 1, &pair->gap, text);
ReadAttr(elem, "friction", 5, pair->friction, text, false, false);
// write error info
mjs_setString(pair->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// equality element parser
void mjXReader::OneEquality(XMLElement* elem, mjsEquality* equality) {
int n;
string text, name1, name2, name;
// read type (bad keywords already detected by schema)
text = elem->Value();
equality->type = (mjtEq)FindKey(equality_map, equality_sz, text);
// regular only
if (!readingdefaults) {
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(equality->element, name.c_str());
}
switch (equality->type) {
case mjEQ_CONNECT: {
auto maybe_site1 = ReadAttrStr(elem, "site1");
auto maybe_site2 = ReadAttrStr(elem, "site2");
auto maybe_body1 = ReadAttrStr(elem, "body1");
auto maybe_body2 = ReadAttrStr(elem, "body2");
bool has_anchor = ReadAttr(elem, "anchor", 3, equality->data, text);
bool maybe_site = maybe_site1.has_value() || maybe_site2.has_value();
bool maybe_body = maybe_body1.has_value() || maybe_body2.has_value() || has_anchor;
if (maybe_site && maybe_body) {
throw mjXError(elem, "body and site semantics cannot be mixed");
}
bool site_semantic = maybe_site1.has_value() && maybe_site2.has_value();
bool body_semantic = maybe_body1.has_value() && has_anchor;
if (site_semantic == body_semantic) {
throw mjXError(elem, "either both body1 and anchor must be defined,"
" or both site1 and site2 must be defined");
}
if (body_semantic) {
name1 = maybe_body1.value();
if (maybe_body2.has_value()) {
name2 = maybe_body2.value();
}
equality->objtype = mjOBJ_BODY;
} else {
name1 = maybe_site1.value();
name2 = maybe_site2.value();
equality->objtype = mjOBJ_SITE;
}
}
break;
case mjEQ_WELD: {
auto maybe_site1 = ReadAttrStr(elem, "site1");
auto maybe_site2 = ReadAttrStr(elem, "site2");
auto maybe_body1 = ReadAttrStr(elem, "body1");
auto maybe_body2 = ReadAttrStr(elem, "body2");
bool has_anchor = ReadAttr(elem, "anchor", 3, equality->data, text);
bool has_relpose = ReadAttr(elem, "relpose", 7, equality->data+3, text);
bool maybe_site = maybe_site1.has_value() || maybe_site2.has_value();
bool maybe_body = maybe_body1.has_value() ||
maybe_body2.has_value() ||
has_anchor ||
has_relpose;
if (maybe_site && maybe_body) {
throw mjXError(elem, "body and site semantics cannot be mixed");
}
bool site_semantic = maybe_site1.has_value() && maybe_site2.has_value();
bool body_semantic = maybe_body1.has_value();
if (site_semantic == body_semantic) {
throw mjXError(
elem,
"either body1 must be defined and optionally {body2, anchor, relpose},"
" or site1 and site2 must be defined");
}
if (body_semantic) {
name1 = maybe_body1.value();
if (maybe_body2.has_value()) {
name2 = maybe_body2.value();
}
equality->objtype = mjOBJ_BODY;
if (!has_anchor) {
mjuu_zerovec(equality->data, 3);
}
} else {
name1 = maybe_site1.value();
name2 = maybe_site2.value();
equality->objtype = mjOBJ_SITE;
}
ReadAttr(elem, "torquescale", 1, equality->data+10, text);
}
break;
case mjEQ_JOINT:
ReadAttrTxt(elem, "joint1", name1, true);
ReadAttrTxt(elem, "joint2", name2);
ReadAttr(elem, "polycoef", 5, equality->data, text, false, false);
break;
case mjEQ_TENDON:
ReadAttrTxt(elem, "tendon1", name1, true);
ReadAttrTxt(elem, "tendon2", name2);
ReadAttr(elem, "polycoef", 5, equality->data, text, false, false);
break;
case mjEQ_FLEX:
ReadAttrTxt(elem, "flex", name1, true);
break;
case mjEQ_DISTANCE:
throw mjXError(elem, "support for distance equality constraints was removed in MuJoCo 2.2.2");
break;
default: // SHOULD NOT OCCUR
throw mjXError(elem, "unrecognized equality constraint type");
}
mjs_setString(equality->name1, name1.c_str());
if (!name2.empty()) {
mjs_setString(equality->name2, name2.c_str());
}
}
// read attributes
if (MapValue(elem, "active", &n, bool_map, 2)) {
equality->active = (n == 1);
}
ReadAttr(elem, "solref", mjNREF, equality->solref, text, false, false);
ReadAttr(elem, "solimp", mjNIMP, equality->solimp, text, false, false);
// write error info
mjs_setString(equality->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// tendon element parser
void mjXReader::OneTendon(XMLElement* elem, mjsTendon* tendon) {
string text, name, material;
std::vector<double> userdata;
// read attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(tendon->element, name.c_str());
}
ReadAttrInt(elem, "group", &tendon->group);
if (ReadAttrTxt(elem, "material", material)) {
mjs_setString(tendon->material, material.c_str());
}
MapValue(elem, "limited", &tendon->limited, TFAuto_map, 3);
MapValue(elem, "actuatorfrclimited", &tendon->actfrclimited, TFAuto_map, 3);
ReadAttr(elem, "width", 1, &tendon->width, text);
ReadAttr(elem, "solreflimit", mjNREF, tendon->solref_limit, text, false, false);
ReadAttr(elem, "solimplimit", mjNIMP, tendon->solimp_limit, text, false, false);
ReadAttr(elem, "solreffriction", mjNREF, tendon->solref_friction, text, false, false);
ReadAttr(elem, "solimpfriction", mjNIMP, tendon->solimp_friction, text, false, false);
ReadAttr(elem, "range", 2, tendon->range, text);
ReadAttr(elem, "actuatorfrcrange", 2, tendon->actfrcrange, text);
ReadAttr(elem, "margin", 1, &tendon->margin, text);
ReadAttr(elem, "stiffness", 1, &tendon->stiffness, text);
ReadAttr(elem, "damping", 1, &tendon->damping, text);
ReadAttr(elem, "armature", 1, &tendon->armature, text);
ReadAttr(elem, "frictionloss", 1, &tendon->frictionloss, text);
// read springlength, either one or two values; if one, copy to second value
if (ReadAttr(elem, "springlength", 2, tendon->springlength, text, false, false) == 1) {
tendon->springlength[1] = tendon->springlength[0];
}
ReadAttr(elem, "rgba", 4, tendon->rgba, text);
// read userdata
if (ReadVector(elem, "user", userdata, text)) {
mjs_setDouble(tendon->userdata, userdata.data(), userdata.size());
}
// write error info
mjs_setString(tendon->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// actuator element parser
void mjXReader::OneActuator(XMLElement* elem, mjsActuator* actuator) {
string text, type, name, target, slidersite, refsite;
// common attributes
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(actuator->element, name.c_str());
}
ReadAttrInt(elem, "group", &actuator->group);
MapValue(elem, "ctrllimited", &actuator->ctrllimited, TFAuto_map, 3);
MapValue(elem, "forcelimited", &actuator->forcelimited, TFAuto_map, 3);
MapValue(elem, "actlimited", &actuator->actlimited, TFAuto_map, 3);
ReadAttr(elem, "ctrlrange", 2, actuator->ctrlrange, text);
ReadAttr(elem, "forcerange", 2, actuator->forcerange, text);
ReadAttr(elem, "actrange", 2, actuator->actrange, text);
ReadAttr(elem, "lengthrange", 2, actuator->lengthrange, text);
ReadAttr(elem, "gear", 6, actuator->gear, text, false, false);
// transmission target and type
int cnt = 0;
if (ReadAttrTxt(elem, "joint", target)) {
mjs_setString(actuator->target, target.c_str());
actuator->trntype = mjTRN_JOINT;
cnt++;
}
if (ReadAttrTxt(elem, "jointinparent", target)) {
mjs_setString(actuator->target, target.c_str());
actuator->trntype = mjTRN_JOINTINPARENT;
cnt++;
}
if (ReadAttrTxt(elem, "tendon", target)) {
mjs_setString(actuator->target, target.c_str());
actuator->trntype = mjTRN_TENDON;
cnt++;
}
if (ReadAttrTxt(elem, "cranksite", target)) {
mjs_setString(actuator->target, target.c_str());
actuator->trntype = mjTRN_SLIDERCRANK;
cnt++;
}
if (ReadAttrTxt(elem, "site", target)) {
mjs_setString(actuator->target, target.c_str());
actuator->trntype = mjTRN_SITE;
cnt++;
}
if (ReadAttrTxt(elem, "body", target)) {
mjs_setString(actuator->target, target.c_str());
actuator->trntype = mjTRN_BODY;
cnt++;
}
// check for repeated transmission
if (cnt > 1) {
throw mjXError(elem, "actuator can have at most one of transmission target");
}
// slidercrank-specific parameters
int r1 = ReadAttr(elem, "cranklength", 1, &actuator->cranklength, text);
int r2 = ReadAttrTxt(elem, "slidersite", slidersite);
if (r2) {
mjs_setString(actuator->slidersite, slidersite.c_str());
}
if ((r1 || r2) &&
actuator->trntype != mjTRN_SLIDERCRANK &&
actuator->trntype != mjTRN_UNDEFINED) {
throw mjXError(elem, "cranklength and slidersite can only be used in slidercrank transmission");
}
// site-specific parameters (refsite)
int r3 = ReadAttrTxt(elem, "refsite", refsite);
if (r3) {
mjs_setString(actuator->refsite, refsite.c_str());
}
if (r3 && actuator->trntype != mjTRN_SITE && actuator->trntype != mjTRN_UNDEFINED) {
throw mjXError(elem, "refsite can only be used with site transmission");
}
// get predefined type
type = elem->Value();
// explicit attributes
string err;
if (type == "general") {
// explicit attributes
int n;
if (MapValue(elem, "dyntype", &n, dyn_map, dyn_sz)) {
actuator->dyntype = (mjtDyn)n;
}
if (MapValue(elem, "gaintype", &n, gain_map, gain_sz)) {
actuator->gaintype = (mjtGain)n;
}
if (MapValue(elem, "biastype", &n, bias_map, bias_sz)) {
actuator->biastype = (mjtBias)n;
}
if (MapValue(elem, "actearly", &n, bool_map, 2)) {
actuator->actearly = (n == 1);
}
ReadAttr(elem, "dynprm", mjNDYN, actuator->dynprm, text, false, false);
ReadAttr(elem, "gainprm", mjNGAIN, actuator->gainprm, text, false, false);
ReadAttr(elem, "biasprm", mjNBIAS, actuator->biasprm, text, false, false);
ReadAttrInt(elem, "actdim", &actuator->actdim);
}
// direct drive motor
else if (type == "motor") {
err = mjs_setToMotor(actuator);
}
// position or integrated velocity servo
else if (type == "position" || type == "intvelocity") {
double kp = actuator->gainprm[0];
ReadAttr(elem, "kp", 1, &kp, text);
// read kv
double kv_data;
double *kv = &kv_data;
if (!ReadAttr(elem, "kv", 1, kv, text)) {
kv = nullptr;
}
// read dampratio
double dampratio_data;
double *dampratio = &dampratio_data;
if (!ReadAttr(elem, "dampratio", 1, dampratio, text)) {
dampratio = nullptr;
}
// read timeconst, set dyntype
double timeconst_data;
double *timeconst = &timeconst_data;
if (!ReadAttr(elem, "timeconst", 1, timeconst, text)) {
timeconst = nullptr;
}
// handle inheritrange
double inheritrange = actuator->inheritrange;
ReadAttr(elem, "inheritrange", 1, &inheritrange, text);
if (type == "position") {
err = mjs_setToPosition(actuator, kp, kv, dampratio, timeconst, inheritrange);
} else {
err = mjs_setToIntVelocity(actuator, kp, kv, dampratio, timeconst, inheritrange);
}
}
// velocity servo
else if (type == "velocity") {
double kv = actuator->gainprm[0];
ReadAttr(elem, "kv", 1, &kv, text);
err = mjs_setToVelocity(actuator, kv);
}
// damper
else if (type == "damper") {
double kv = 0;
ReadAttr(elem, "kv", 1, &kv, text);
err = mjs_setToDamper(actuator, kv);
}
// cylinder
else if (type == "cylinder") {
double timeconst = actuator->dynprm[0];
double bias = actuator->biasprm[0];
double area = actuator->gainprm[0];
double diameter = -1;
ReadAttr(elem, "timeconst", 1, &timeconst, text);
ReadAttr(elem, "bias", 3, &bias, text);
ReadAttr(elem, "area", 1, &area, text);
ReadAttr(elem, "diameter", 1, &diameter, text);
err = mjs_setToCylinder(actuator, timeconst, bias, area, diameter);
}
// muscle
else if (type == "muscle") {
double tausmooth = actuator->dynprm[2];
double force = -1, scale = -1, lmin = -1, lmax = -1, vmax = -1, fpmax = -1, fvmax = -1;
double range[2] = {-1, -1}, timeconst[2] = {-1, -1};
ReadAttr(elem, "timeconst", 2, timeconst, text);
ReadAttr(elem, "tausmooth", 1, &tausmooth, text);
ReadAttr(elem, "range", 2, range, text);
ReadAttr(elem, "force", 1, &force, text);
ReadAttr(elem, "scale", 1, &scale, text);
ReadAttr(elem, "lmin", 1, &lmin, text);
ReadAttr(elem, "lmax", 1, &lmax, text);
ReadAttr(elem, "vmax", 1, &vmax, text);
ReadAttr(elem, "fpmax", 1, &fpmax, text);
ReadAttr(elem, "fvmax", 1, &fvmax, text);
err = mjs_setToMuscle(actuator, timeconst, tausmooth, range, force, scale,
lmin, lmax, vmax, fpmax, fvmax);
}
// adhesion
else if (type == "adhesion") {
double gain = actuator->gainprm[0];
ReadAttr(elem, "gain", 1, &gain, text);
ReadAttr(elem, "ctrlrange", 2, actuator->ctrlrange, text);
err = mjs_setToAdhesion(actuator, gain);
}
else if (type == "plugin") {
OnePlugin(elem, &actuator->plugin);
int n;
if (MapValue(elem, "dyntype", &n, dyn_map, dyn_sz)) {
actuator->dyntype = (mjtDyn)n;
}
if (MapValue(elem, "actearly", &n, bool_map, 2)) {
actuator->actearly = (n == 1);
}
ReadAttr(elem, "dynprm", mjNDYN, actuator->dynprm, text, false, false);
ReadAttrInt(elem, "actdim", &actuator->actdim);
}
else { // SHOULD NOT OCCUR
throw mjXError(elem, "unrecognized actuator type: %s", type.c_str());
}
// throw error if any of the above failed
if (!err.empty()) {
throw mjXError(elem, err.c_str());
}
// read userdata
std::vector<double> userdata;
if (ReadVector(elem, "user", userdata, text)) {
mjs_setDouble(actuator->userdata, userdata.data(), userdata.size());
}
// write info
mjs_setString(actuator->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
}
// make composite
void mjXReader::OneComposite(XMLElement* elem, mjsBody* body, mjsFrame* frame, const mjsDefault* def) {
string text;
int n;
// create out-of-DOM element
mjCComposite comp;
// common properties
ReadAttrTxt(elem, "prefix", comp.prefix);
if (MapValue(elem, "type", &n, comp_map, mjNCOMPTYPES, true)) {
comp.type = (mjtCompType)n;
}
ReadAttr(elem, "count", 3, comp.count, text, false, false);
ReadAttr(elem, "offset", 3, comp.offset, text);
ReadAttr(elem, "quat", 4, comp.quat, text);
comp.frame = frame;
// plugin
XMLElement* eplugin = FirstChildElement(elem, "plugin");
if (eplugin) {
OnePlugin(eplugin, &comp.plugin);
}
// cable
string curves;
ReadAttrTxt(elem, "curve", curves);
ReadAttrTxt(elem, "initial", comp.initial);
ReadAttr(elem, "size", 3, comp.size, text, false, false);
auto uservert = ReadAttrVec<float>(elem, "vertex");
if (uservert.has_value()) {
comp.uservert = std::move(uservert.value());
}
// process curve string
std::istringstream iss(curves);
int i = 0;
while (iss) {
if (curves.empty()) {
break;
}
iss >> text;
if (i > 2) {
throw mjXError(elem, "The curve array must have a maximum of 3 components");
}
comp.curve[i++] = (mjtCompShape)FindKey(shape_map, mjNCOMPSHAPES, text);
if (comp.curve[i-1] == -1) {
throw mjXError(elem, "The curve array contains an invalid shape");
}
if (iss.eof()){
break;
}
};
// skin
XMLElement* eskin = FirstChildElement(elem, "skin");
if (eskin) {
comp.skin = true;
if (MapValue(eskin, "texcoord", &n, bool_map, 2)) {
comp.skintexcoord = (n == 1);
}
ReadAttrTxt(eskin, "material", comp.skinmaterial);
ReadAttr(eskin, "rgba", 4, comp.skinrgba, text);
ReadAttr(eskin, "inflate", 1, &comp.skininflate, text);
ReadAttrInt(eskin, "subgrid", &comp.skinsubgrid);
ReadAttrInt(eskin, "group", &comp.skingroup, 0);
if (comp.skingroup < 0 || comp.skingroup >= mjNGROUP) {
throw mjXError(eskin, "skin group must be between 0 and 5");
}
}
// set type-specific defaults
comp.SetDefault();
// geom
XMLElement* egeom = FirstChildElement(elem, "geom");
if (egeom) {
string material;
mjsGeom& dgeom = *comp.def[0].spec.geom;
if (MapValue(egeom, "type", &n, geom_map, mjNGEOMTYPES)) {
dgeom.type = (mjtGeom)n;
}
ReadAttr(egeom, "size", 3, dgeom.size, text, false, false);
ReadAttrInt(egeom, "contype", &dgeom.contype);
ReadAttrInt(egeom, "conaffinity", &dgeom.conaffinity);
ReadAttrInt(egeom, "condim", &dgeom.condim);
ReadAttrInt(egeom, "group", &dgeom.group);
ReadAttrInt(egeom, "priority", &dgeom.priority);
ReadAttr(egeom, "friction", 3, dgeom.friction, text, false, false);
ReadAttr(egeom, "solmix", 1, &dgeom.solmix, text);
ReadAttr(egeom, "solref", mjNREF, dgeom.solref, text, false, false);
ReadAttr(egeom, "solimp", mjNIMP, dgeom.solimp, text, false, false);
ReadAttr(egeom, "margin", 1, &dgeom.margin, text);
ReadAttr(egeom, "gap", 1, &dgeom.gap, text);
if (ReadAttrTxt(egeom, "material", material)) {
mjs_setString(dgeom.material, material.c_str());
}
ReadAttr(egeom, "rgba", 4, dgeom.rgba, text);
ReadAttr(egeom, "mass", 1, &dgeom.mass, text);
ReadAttr(egeom, "density", 1, &dgeom.density, text);
}
// site
XMLElement* esite = FirstChildElement(elem, "site");
if (esite) {
string material;
mjsSite& dsite = *comp.def[0].spec.site;
ReadAttr(esite, "size", 3, dsite.size, text, false, false);
ReadAttrInt(esite, "group", &dsite.group);
ReadAttrTxt(esite, "material", material);
ReadAttr(esite, "rgba", 4, dsite.rgba, text);
mjs_setString(dsite.material, material.c_str());
}
// joint
XMLElement* ejnt = FirstChildElement(elem, "joint");
while (ejnt) {
// kind
int kind;
MapValue(ejnt, "kind", &kind, jkind_map, 1, true);
// create a new element if this kind already exists
if (comp.add[kind]) {
char error[200];
if (!comp.AddDefaultJoint(error, 200)) {
throw mjXError(elem, "%s", error);
}
}
comp.add[kind] = true;
// get element
mjsDefault* dspec = &comp.defjoint[(mjtCompKind)kind].back().spec;
mjsJoint& djoint = *dspec->joint;
mjsEquality& dequality = *dspec->equality;
// particle joint
if (MapValue(ejnt, "type", &n, joint_map, joint_sz)) {
djoint.type = (mjtJoint)n;
}
ReadAttr(ejnt, "axis", 3, djoint.axis, text);
// solreffix, solimpfix
ReadAttr(ejnt, "solreffix", mjNREF, dequality.solref, text, false, false);
ReadAttr(ejnt, "solimpfix", mjNIMP, dequality.solimp, text, false, false);
// joint attributes
MapValue(elem, "limited", &djoint.limited, TFAuto_map, 3);
ReadAttrInt(ejnt, "group", &djoint.group);
ReadAttr(ejnt, "solreflimit", mjNREF, djoint.solref_limit, text, false, false);
ReadAttr(ejnt, "solimplimit", mjNIMP, djoint.solimp_limit, text, false, false);
ReadAttr(ejnt,
"solreffriction", mjNREF, djoint.solref_friction, text, false, false);
ReadAttr(ejnt,
"solimpfriction", mjNIMP, djoint.solimp_friction, text, false, false);
ReadAttr(ejnt, "stiffness", 1, &djoint.stiffness, text);
ReadAttr(ejnt, "range", 2, djoint.range, text);
ReadAttr(ejnt, "margin", 1, &djoint.margin, text);
ReadAttr(ejnt, "armature", 1, &djoint.armature, text);
ReadAttr(ejnt, "damping", 1, &djoint.damping, text);
ReadAttr(ejnt, "frictionloss", 1, &djoint.frictionloss, text);
// advance
ejnt = NextSiblingElement(ejnt, "joint");
}
// make composite
char error[200];
bool res = comp.Make(spec, body, error, 200);
// throw error
if (!res) {
throw mjXError(elem, "%s", error);
}
}
// make flexcomp
void mjXReader::OneFlexcomp(XMLElement* elem, mjsBody* body, const mjVFS* vfs) {
string text, material;
int n;
// create out-of-DOM element
mjCFlexcomp fcomp;
mjsFlex& dflex = *fcomp.def.spec.flex;
// common properties
ReadAttrTxt(elem, "name", fcomp.name, true);
if (MapValue(elem, "type", &n, fcomp_map, mjNFCOMPTYPES)) {
fcomp.type = (mjtFcompType)n;
}
ReadAttr(elem, "count", 3, fcomp.count, text);
ReadAttr(elem, "spacing", 3, fcomp.spacing, text);
ReadAttr(elem, "scale", 3, fcomp.scale, text);
ReadAttr(elem, "mass", 1, &fcomp.mass, text);
ReadAttr(elem, "inertiabox", 1, &fcomp.inertiabox, text);
auto maybe_file = ReadAttrFile(elem, "file", vfs, modelfiledir_);
if (maybe_file.has_value()) {
fcomp.file = std::move(maybe_file.value().Str());
} else {
fcomp.file = "";
}
if (ReadAttrTxt(elem, "material", material)) {
mjs_setString(dflex.material, material.c_str());
}
ReadAttr(elem, "rgba", 4, dflex.rgba, text);
if (MapValue(elem, "flatskin", &n, bool_map, 2)) {
dflex.flatskin = (n == 1);
}
ReadAttrInt(elem, "dim", &dflex.dim);
ReadAttr(elem, "radius", 1, &dflex.radius, text);
ReadAttrInt(elem, "group", &dflex.group);
if (!ReadAttr(elem, "origin", 3, fcomp.origin, text) &&
fcomp.type == mjFCOMPTYPE_MESH && dflex.dim == 3) {
throw mjXError(elem, "origin must be specified for mesh flexcomps if dim=3");
}
// pose
ReadAttr(elem, "pos", 3, fcomp.pos, text);
ReadAttr(elem, "quat", 4, fcomp.quat, text);
ReadAlternative(elem, fcomp.alt);
// user or internal
if (MapValue(elem, "rigid", &n, bool_map, 2)) {
fcomp.rigid = (n == 1);
}
auto point = ReadAttrVec<double>(elem, "point");
if (point.has_value()) {
fcomp.point = std::move(point.value());
}
auto element = ReadAttrVec<int>(elem, "element");
if (element.has_value()) {
fcomp.element = std::move(element.value());
}
auto texcoord = ReadAttrVec<float>(elem, "texcoord");
if (texcoord.has_value()) {
fcomp.texcoord = std::move(texcoord.value());
}
// dof type
if (MapValue(elem, "dof", &n, fdof_map, mjNFCOMPDOFS)) {
fcomp.doftype = (mjtDof)n;
}
// edge
XMLElement* edge = FirstChildElement(elem, "edge");
if (edge) {
if (MapValue(edge, "equality", &n, bool_map, 2)) {
fcomp.equality = (n == 1);
}
ReadAttr(edge, "solref", mjNREF, fcomp.def.spec.equality->solref, text, false, false);
ReadAttr(edge, "solimp", mjNIMP, fcomp.def.spec.equality->solimp, text, false, false);
ReadAttr(edge, "stiffness", 1, &dflex.edgestiffness, text);
ReadAttr(edge, "damping", 1, &dflex.edgedamping, text);
}
// elasticity
XMLElement* elasticity = FirstChildElement(elem, "elasticity");
if (elasticity) {
ReadAttr(elasticity, "young", 1, &dflex.young, text);
ReadAttr(elasticity, "poisson", 1, &dflex.poisson, text);
ReadAttr(elasticity, "damping", 1, &dflex.damping, text);
ReadAttr(elasticity, "thickness", 1, &dflex.thickness, text);
MapValue(elasticity, "elastic2d", &dflex.elastic2d, elastic2d_map, 4);
}
// check errors
if (dflex.elastic2d >= 2 && fcomp.equality) {
throw mjXError(elem, "elasticity and edge constraints cannot both be present");
}
// contact
XMLElement* cont = FirstChildElement(elem, "contact");
if (cont) {
ReadAttrInt(cont, "contype", &dflex.contype);
ReadAttrInt(cont, "conaffinity", &dflex.conaffinity);
ReadAttrInt(cont, "condim", &dflex.condim);
ReadAttrInt(cont, "priority", &dflex.priority);
ReadAttr(cont, "friction", 3, dflex.friction, text, false, false);
ReadAttr(cont, "solmix", 1, &dflex.solmix, text);
ReadAttr(cont, "solref", mjNREF, dflex.solref, text, false, false);
ReadAttr(cont, "solimp", mjNIMP, dflex.solimp, text, false, false);
ReadAttr(cont, "margin", 1, &dflex.margin, text);
ReadAttr(cont, "gap", 1, &dflex.gap, text);
if (MapValue(cont, "internal", &n, bool_map, 2)) {
dflex.internal = (n == 1);
}
MapValue(cont, "selfcollide", &dflex.selfcollide, flexself_map, 5);
if (MapValue(cont, "vertcollide", &n, bool_map, 2)) {
dflex.vertcollide = (n == 1);
}
ReadAttrInt(cont, "activelayers", &dflex.activelayers);
}
// pin
XMLElement* epin = FirstChildElement(elem, "pin");
while (epin) {
auto id = ReadAttrVec<int>(epin, "id");
if (id.has_value()) {
fcomp.pinid.insert(fcomp.pinid.end(), id->begin(), id->end());
}
auto range = ReadAttrVec<int>(epin, "range");
if (range.has_value()) {
fcomp.pinrange.insert(fcomp.pinrange.end(), range->begin(), range->end());
}
auto grid = ReadAttrVec<int>(epin, "grid");
if (grid.has_value()) {
fcomp.pingrid.insert(fcomp.pingrid.end(), grid->begin(), grid->end());
}
auto gridrange = ReadAttrVec<int>(epin, "gridrange");
if (gridrange.has_value()) {
fcomp.pingridrange.insert(fcomp.pingridrange.end(),
gridrange->begin(), gridrange->end());
}
// advance
epin = NextSiblingElement(epin, "pin");
}
// plugin
XMLElement* eplugin = FirstChildElement(elem, "plugin");
if (eplugin) {
OnePlugin(eplugin, &fcomp.plugin);
}
// make flexcomp
char error[200];
bool res = fcomp.Make(body, error, 200);
// throw error
if (!res) {
throw mjXError(elem, "%s", error);
}
}
// add plugin
void mjXReader::OnePlugin(XMLElement* elem, mjsPlugin* plugin) {
plugin->active = true;
string name = "";
string instance_name = "";
ReadAttrTxt(elem, "plugin", name);
ReadAttrTxt(elem, "instance", instance_name);
mjs_setString(plugin->plugin_name, name.c_str());
mjs_setString(plugin->name, instance_name.c_str());
if (instance_name.empty()) {
plugin->element = mjs_addPlugin(spec)->element;
ReadPluginConfigs(elem, plugin);
} else {
spec->hasImplicitPluginElem = true;
}
}
//------------------ MJCF-specific sections --------------------------------------------------------
// default section parser
void mjXReader::Default(XMLElement* section, const mjsDefault* def, const mjVFS* vfs) {
XMLElement* elem;
string text, name;
// create new default, except at top level (already added in mjCModel constructor)
text.clear();
ReadAttrTxt(section, "class", text);
if (text.empty()) {
if (def) {
throw mjXError(section, "empty class name");
}
}
if (def) {
def = mjs_addDefault(spec, text.c_str(), def);
if (!def) {
throw mjXError(section, "repeated default class name");
}
} else {
def = mjs_getSpecDefault(spec);
if (!text.empty() && text != "main") {
throw mjXError(section, "top-level default class 'main' cannot be renamed");
}
}
// iterate over elements other than nested defaults
elem = FirstChildElement(section);
while (elem) {
// get element name
name = elem->Value();
// read mesh
if (name == "mesh")OneMesh(elem, def->mesh, vfs);
// read material
else if (name == "material")OneMaterial(elem, def->material);
// read joint
else if (name == "joint")OneJoint(elem, def->joint);
// read geom
else if (name == "geom")OneGeom(elem, def->geom);
// read site
else if (name == "site")OneSite(elem, def->site);
// read camera
else if (name == "camera")OneCamera(elem, def->camera);
// read light
else if (name == "light")OneLight(elem, def->light);
// read pair
else if (name == "pair")OnePair(elem, def->pair);
// read equality
else if (name == "equality")OneEquality(elem, def->equality);
// read tendon
else if (name == "tendon")OneTendon(elem, def->tendon);
// read actuator
else if (name == "general" ||
name == "motor" ||
name == "position" ||
name == "velocity" ||
name == "damper" ||
name == "intvelocity" ||
name == "cylinder" ||
name == "muscle" ||
name == "adhesion") {
OneActuator(elem, def->actuator);
}
// advance
elem = NextSiblingElement(elem);
}
// iterate over nested defaults
elem = FirstChildElement(section);
while (elem) {
// get element name
name = elem->Value();
// read default
if (name == "default") {
Default(elem, def, vfs);
}
// advance
elem = NextSiblingElement(elem);
}
}
// extension section parser
void mjXReader::Extension(XMLElement* section) {
XMLElement* elem = FirstChildElement(section);
while (elem) {
// get sub-element name
string_view name = elem->Value();
if (name == "plugin") {
string plugin_name;
ReadAttrTxt(elem, "plugin", plugin_name, /* required = */ true);
if (mjs_activatePlugin(spec, plugin_name.c_str())) {
throw mjXError(elem, "plugin %s not found", plugin_name.c_str());
}
XMLElement* child = FirstChildElement(elem);
while (child) {
if (string(child->Value()) == "instance") {
if (spec->hasImplicitPluginElem) {
throw mjXError(
child, "explicit plugin instance must appear before implicit plugin elements");
}
string name;
mjsPlugin* p = mjs_addPlugin(spec);
mjs_setString(p->plugin_name, plugin_name.c_str());
mjs_setString(p->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
ReadAttrTxt(child, "name", name, /* required = */ true);
mjs_setString(p->name, name.c_str());
if (!p->name) {
throw mjXError(child, "plugin instance must have a name");
}
ReadPluginConfigs(child, p);
}
child = NextSiblingElement(child);
}
}
// advance to next element
elem = NextSiblingElement(elem);
}
}
// custom section parser
void mjXReader::Custom(XMLElement* section) {
string str, name;
XMLElement* elem;
double data[500];
// iterate over child elements
elem = FirstChildElement(section);
while (elem) {
// get sub-element name
name = elem->Value();
string elname;
// numeric
if (name == "numeric") {
// create custom
mjsNumeric* numeric = mjs_addNumeric(spec);
// write error info
mjs_setString(numeric->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
// read attributes
ReadAttrTxt(elem, "name", elname, true);
mjs_setName(numeric->element, elname.c_str());
if (ReadAttrInt(elem, "size", &numeric->size)) {
int sz = numeric->size < 500 ? numeric->size : 500;
for (int i=0; i < sz; i++) {
data[i] = 0;
}
} else {
numeric->size = 501;
}
int len = ReadAttr(elem, "data", numeric->size, data, str, false, false);
if (numeric->size == 501) {
numeric->size = len;
}
if (numeric->size < 1 || numeric->size > 500) {
throw mjXError(elem, "custom field size must be between 1 and 500");
}
// copy data
mjs_setDouble(numeric->data, data, numeric->size);
}
// text
else if (name == "text") {
// create custom
mjsText* text = mjs_addText(spec);
// write error info
mjs_setString(text->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
// read attributes
ReadAttrTxt(elem, "name", elname, true);
mjs_setName(text->element, elname.c_str());
ReadAttrTxt(elem, "data", str, true);
if (str.empty()) {
throw mjXError(elem, "text field cannot be empty");
}
// copy data
mjs_setString(text->data, str.c_str());
}
// tuple
else if (name == "tuple") {
// create custom
mjsTuple* tuple = mjs_addTuple(spec);
// write error info
mjs_setString(tuple->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
// read attributes
ReadAttrTxt(elem, "name", elname, true);
mjs_setName(tuple->element, elname.c_str());
// read objects and add
XMLElement* obj = FirstChildElement(elem);
std::vector<int> objtype;
string objname = "";
std::vector<double> objprm;
while (obj) {
// get sub-element name
name = obj->Value();
// new object
if (name == "element") {
// read type, check and assign
ReadAttrTxt(obj, "objtype", str, true);
mjtObj otype = (mjtObj)mju_str2Type(str.c_str());
if (otype == mjOBJ_UNKNOWN) {
throw mjXError(obj, "unknown object type");
}
objtype.push_back(otype);
// read name and assign
ReadAttrTxt(obj, "objname", str, true);
objname += " " + str;
// read parameter and assign
double oprm = 0;
ReadAttr(obj, "prm", 1, &oprm, str);
objprm.push_back(oprm);
}
// advance to next object
obj = NextSiblingElement(obj);
}
mjs_setInt(tuple->objtype, objtype.data(), objtype.size());
mjs_setStringVec(tuple->objname, objname.c_str());
mjs_setDouble(tuple->objprm, objprm.data(), objprm.size());
}
// advance to next element
elem = NextSiblingElement(elem);
}
}
// visual section parser
void mjXReader::Visual(XMLElement* section) {
string text, name;
XMLElement* elem;
mjVisual* vis = &spec->visual;
int n;
// iterate over child elements
elem = FirstChildElement(section);
while (elem) {
// get sub-element name
name = elem->Value();
// global sub-element
if (name == "global") {
ReadAttrInt(elem, "cameraid", &vis->global.cameraid);
if (MapValue(elem, "orthographic", &n, bool_map, 2)) {
vis->global.orthographic = (n == 1);
}
ReadAttr(elem, "fovy", 1, &vis->global.fovy, text);
ReadAttr(elem, "ipd", 1, &vis->global.ipd, text);
ReadAttr(elem, "azimuth", 1, &vis->global.azimuth, text);
ReadAttr(elem, "elevation", 1, &vis->global.elevation, text);
ReadAttr(elem, "linewidth", 1, &vis->global.linewidth, text);
ReadAttr(elem, "glow", 1, &vis->global.glow, text);
ReadAttrInt(elem, "offwidth", &vis->global.offwidth);
ReadAttrInt(elem, "offheight", &vis->global.offheight);
if (ReadAttr(elem, "realtime", 1, &vis->global.realtime, text)) {
if (vis->global.realtime <= 0) {
throw mjXError(elem, "realtime must be greater than 0");
}
}
if (MapValue(elem, "ellipsoidinertia", &n, bool_map, 2)) {
vis->global.ellipsoidinertia = (n == 1);
}
if (MapValue(elem, "bvactive", &n, bool_map, 2)) {
vis->global.bvactive = (n == 1);
}
}
// quality sub-element
else if (name == "quality") {
ReadAttrInt(elem, "shadowsize", &vis->quality.shadowsize);
ReadAttrInt(elem, "offsamples", &vis->quality.offsamples);
ReadAttrInt(elem, "numslices", &vis->quality.numslices);
ReadAttrInt(elem, "numstacks", &vis->quality.numstacks);
ReadAttrInt(elem, "numquads", &vis->quality.numquads);
}
// headlight sub-element
else if (name == "headlight") {
ReadAttr(elem, "ambient", 3, vis->headlight.ambient, text);
ReadAttr(elem, "diffuse", 3, vis->headlight.diffuse, text);
ReadAttr(elem, "specular", 3, vis->headlight.specular, text);
ReadAttrInt(elem, "active", &vis->headlight.active);
}
// map sub-element
else if (name == "map") {
ReadAttr(elem, "stiffness", 1, &vis->map.stiffness, text);
ReadAttr(elem, "stiffnessrot", 1, &vis->map.stiffnessrot, text);
ReadAttr(elem, "force", 1, &vis->map.force, text);
ReadAttr(elem, "torque", 1, &vis->map.torque, text);
ReadAttr(elem, "alpha", 1, &vis->map.alpha, text);
ReadAttr(elem, "fogstart", 1, &vis->map.fogstart, text);
ReadAttr(elem, "fogend", 1, &vis->map.fogend, text);
ReadAttr(elem, "znear", 1, &vis->map.znear, text);
if (vis->map.znear <= 0) {
throw mjXError(elem, "znear must be strictly positive");
}
ReadAttr(elem, "zfar", 1, &vis->map.zfar, text);
ReadAttr(elem, "haze", 1, &vis->map.haze, text);
ReadAttr(elem, "shadowclip", 1, &vis->map.shadowclip, text);
ReadAttr(elem, "shadowscale", 1, &vis->map.shadowscale, text);
ReadAttr(elem, "actuatortendon", 1, &vis->map.actuatortendon, text);
}
// scale sub-element
else if (name == "scale") {
ReadAttr(elem, "forcewidth", 1, &vis->scale.forcewidth, text);
ReadAttr(elem, "contactwidth", 1, &vis->scale.contactwidth, text);
ReadAttr(elem, "contactheight", 1, &vis->scale.contactheight, text);
ReadAttr(elem, "connect", 1, &vis->scale.connect, text);
ReadAttr(elem, "com", 1, &vis->scale.com, text);
ReadAttr(elem, "camera", 1, &vis->scale.camera, text);
ReadAttr(elem, "light", 1, &vis->scale.light, text);
ReadAttr(elem, "selectpoint", 1, &vis->scale.selectpoint, text);
ReadAttr(elem, "jointlength", 1, &vis->scale.jointlength, text);
ReadAttr(elem, "jointwidth", 1, &vis->scale.jointwidth, text);
ReadAttr(elem, "actuatorlength", 1, &vis->scale.actuatorlength, text);
ReadAttr(elem, "actuatorwidth", 1, &vis->scale.actuatorwidth, text);
ReadAttr(elem, "framelength", 1, &vis->scale.framelength, text);
ReadAttr(elem, "framewidth", 1, &vis->scale.framewidth, text);
ReadAttr(elem, "constraint", 1, &vis->scale.constraint, text);
ReadAttr(elem, "slidercrank", 1, &vis->scale.slidercrank, text);
ReadAttr(elem, "frustum", 1, &vis->scale.frustum, text);
}
// rgba sub-element
else if (name == "rgba") {
ReadAttr(elem, "fog", 4, vis->rgba.fog, text);
ReadAttr(elem, "haze", 4, vis->rgba.haze, text);
ReadAttr(elem, "force", 4, vis->rgba.force, text);
ReadAttr(elem, "inertia", 4, vis->rgba.inertia, text);
ReadAttr(elem, "joint", 4, vis->rgba.joint, text);
ReadAttr(elem, "actuator", 4, vis->rgba.actuator, text);
ReadAttr(elem, "actuatornegative", 4, vis->rgba.actuatornegative, text);
ReadAttr(elem, "actuatorpositive", 4, vis->rgba.actuatorpositive, text);
ReadAttr(elem, "com", 4, vis->rgba.com, text);
ReadAttr(elem, "camera", 4, vis->rgba.camera, text);
ReadAttr(elem, "light", 4, vis->rgba.light, text);
ReadAttr(elem, "selectpoint", 4, vis->rgba.selectpoint, text);
ReadAttr(elem, "connect", 4, vis->rgba.connect, text);
ReadAttr(elem, "contactpoint", 4, vis->rgba.contactpoint, text);
ReadAttr(elem, "contactforce", 4, vis->rgba.contactforce, text);
ReadAttr(elem, "contactfriction", 4, vis->rgba.contactfriction, text);
ReadAttr(elem, "contacttorque", 4, vis->rgba.contacttorque, text);
ReadAttr(elem, "contactgap", 4, vis->rgba.contactgap, text);
ReadAttr(elem, "rangefinder", 4, vis->rgba.rangefinder, text);
ReadAttr(elem, "constraint", 4, vis->rgba.constraint, text);
ReadAttr(elem, "slidercrank", 4, vis->rgba.slidercrank, text);
ReadAttr(elem, "crankbroken", 4, vis->rgba.crankbroken, text);
ReadAttr(elem, "frustum", 4, vis->rgba.frustum, text);
ReadAttr(elem, "bv", 4, vis->rgba.bv, text);
ReadAttr(elem, "bvactive", 4, vis->rgba.bvactive, text);
}
// advance to next element
elem = NextSiblingElement(elem);
}
}
// asset section parser
void mjXReader::Asset(XMLElement* section, const mjVFS* vfs) {
int n;
string text, name, texname, content_type;
XMLElement* elem;
// iterate over child elements
elem = FirstChildElement(section);
while (elem) {
// get sub-element name
name = elem->Value();
// get class if specified, otherwise use default0
const mjsDefault* def = GetClass(elem);
if (!def) {
def = mjs_getSpecDefault(spec);
}
// texture sub-element
if (name == "texture") {
// create texture
mjsTexture* texture = mjs_addTexture(spec);
// write error info
mjs_setString(texture->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
// read attributes
if (MapValue(elem, "type", &n, texture_map, texture_sz)) {
texture->type = (mjtTexture)n;
}
if (MapValue(elem, "colorspace", &n, colorspace_map, colorspace_sz)) {
texture->colorspace = (mjtColorSpace)n;
}
if (ReadAttrTxt(elem, "name", texname)) {
mjs_setName(texture->element, texname.c_str());
}
if (ReadAttrTxt(elem, "content_type", content_type)) {
mjs_setString(texture->content_type, content_type.c_str());
}
auto file = ReadAttrFile(elem, "file", vfs, TextureDir());
if (file.has_value()) {
mjs_setString(texture->file, file->c_str());
}
ReadAttrInt(elem, "width", &texture->width);
ReadAttrInt(elem, "height", &texture->height);
ReadAttrInt(elem, "nchannel", &texture->nchannel);
ReadAttr(elem, "rgb1", 3, texture->rgb1, text);
ReadAttr(elem, "rgb2", 3, texture->rgb2, text);
ReadAttr(elem, "markrgb", 3, texture->markrgb, text);
ReadAttr(elem, "random", 1, &texture->random, text);
if (MapValue(elem, "builtin", &n, builtin_map, builtin_sz)) {
texture->builtin = (mjtBuiltin)n;
}
if (MapValue(elem, "mark", &n, mark_map, mark_sz)) {
texture->mark = (mjtMark)n;
}
if (MapValue(elem, "hflip", &n, bool_map, 2)) {
texture->hflip = (n != 0);
}
if (MapValue(elem, "vflip", &n, bool_map, 2)) {
texture->vflip = (n != 0);
}
// grid
ReadAttr(elem, "gridsize", 2, texture->gridsize, text);
if (ReadAttrTxt(elem, "gridlayout", text)) {
// check length
if (text.length() > 12) {
throw mjXError(elem, "gridlayout length cannot exceed 12 characters");
}
if (text.length() != texture->gridsize[0]*texture->gridsize[1]) {
throw mjXError(elem, "gridlayout length must match gridsize");
}
memcpy(texture->gridlayout, text.data(), text.length());
}
// separate files
std::vector<string> cubefiles(6);
std::vector<string> cubefile_names = {"fileright", "fileleft",
"fileup", "filedown",
"filefront", "fileback"};
for (int i = 0; i < cubefiles.size(); i++) {
auto maybe_file = ReadAttrFile(elem, cubefile_names[i].c_str(), vfs,
TextureDir());
if (maybe_file.has_value()) {
cubefiles[i] = maybe_file.value().Str();
} else {
cubefiles[i] = "";
}
mjs_setInStringVec(texture->cubefiles, i, cubefiles[i].c_str());
}
}
// material sub-element
else if (name == "material") {
// create material and parse
mjsMaterial* material = mjs_addMaterial(spec, def);
OneMaterial(elem, material);
}
// mesh sub-element
else if (name == "mesh") {
// create mesh and parse
mjsMesh* mesh = mjs_addMesh(spec, def);
OneMesh(elem, mesh, vfs);
}
// skin sub-element... deprecate ???
else if (name == "skin") {
// create skin and parse
mjsSkin* skin = mjs_addSkin(spec);
OneSkin(elem, skin, vfs);
}
// hfield sub-element
else if (name == "hfield") {
// create hfield
mjsHField* hfield = mjs_addHField(spec);
// write error info
mjs_setString(hfield->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
// read attributes
string name, content_type;
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(hfield->element, name.c_str());
}
if (ReadAttrTxt(elem, "content_type", content_type)) {
mjs_setString(hfield->content_type, content_type.c_str());
}
auto file = ReadAttrFile(elem, "file", vfs, AssetDir());
if (file.has_value()) {
mjs_setString(hfield->file, file->c_str());
}
ReadAttrInt(elem, "nrow", &hfield->nrow);
ReadAttrInt(elem, "ncol", &hfield->ncol);
ReadAttr(elem, "size", 4, hfield->size, text, true);
// allocate buffer for dynamic hfield, copy user data if given
if (!file.has_value() && hfield->nrow > 0 && hfield->ncol > 0) {
int nrow = hfield->nrow;
int ncol = hfield->ncol;
// read user data
auto userdata = ReadAttrVec<float>(elem, "elevation");
// user data given, copy into data
if (userdata.has_value()) {
if (userdata->size() != nrow*ncol) {
throw mjXError(elem, "elevation data length must match nrow*ncol");
}
// copy in reverse row order, so XML string is top-to-bottom
std::vector<float> flipped(nrow*ncol);
for (int i = 0; i < nrow; i++) {
int flip = nrow-1-i;
for (int j = 0; j < ncol; j++) {
flipped[flip*ncol + j] = userdata->data()[i*ncol + j];
}
}
mjs_setFloat(hfield->userdata, flipped.data(), flipped.size());
}
// user data not given, set to 0
else {
std::vector<float> zero(nrow*ncol);
mjs_setFloat(hfield->userdata, zero.data(), zero.size());
}
}
}
// model sub-element
else if (name == "model") {
string content_type;
if (!ReadAttrTxt(elem, "content_type", content_type)) {
content_type = "text/xml";
}
// parse the child
mjSpec* child = nullptr;
std::array<char, 1024> error;
auto filename = modelfiledir_ + ReadAttrFile(elem, "file", vfs).value();
if (content_type == "text/xml") {
child = mj_parseXML(filename.c_str(), vfs, error.data(), error.size());
} else {
throw mjXError(elem, "unsupported content_type: %s", content_type.c_str());
}
if (!child) {
throw mjXError(elem, "could not parse model file with error: %s", error.data());
}
// overwrite model name if given
string modelname = "";
if (ReadAttrTxt(elem, "name", modelname)) {
mjs_setString(child->modelname, modelname.c_str());
}
// store child spec in model
mjs_addSpec(spec, child);
}
// advance to next element
elem = NextSiblingElement(elem);
}
}
// body/world section parser; recursive
void mjXReader::Body(XMLElement* section, mjsBody* body, mjsFrame* frame,
const mjVFS* vfs) {
string text, name;
XMLElement* elem;
int n;
// sanity check
if (!body) {
throw mjXError(section, "null body pointer");
}
// no attributes allowed in world body
if (mjs_getId(body->element) == 0 && section->FirstAttribute() && !frame) {
throw mjXError(section, "World body cannot have attributes");
}
// iterate over sub-elements; attributes set while parsing parent body
elem = FirstChildElement(section);
while (elem) {
// get sub-element name
name = elem->Value();
// get class if specified, otherwise use body
const mjsDefault* def = GetClass(elem);
if (!def) {
def = mjs_getDefault(frame ? frame->element : body->element);
}
// inertial sub-element
if (name == "inertial") {
// no inertia allowed in world body
if (mjs_getId(body->element) == 0) {
throw mjXError(elem, "World body cannot have inertia");
}
body->explicitinertial = true;
ReadAttr(elem, "pos", 3, body->ipos, text, true);
ReadQuat(elem, "quat", body->iquat, text);
ReadAttr(elem, "mass", 1, &body->mass, text, true);
ReadAttr(elem, "diaginertia", 3, body->inertia, text);
bool alt = ReadAlternative(elem, body->ialt);
bool full = ReadAttr(elem, "fullinertia", 6, body->fullinertia, text);
if (alt && full) {
throw mjXError(elem, "fullinertia and inertial orientation cannot both be specified");
}
}
// joint sub-element
else if (name == "joint") {
// no joints allowed in world body
if (mjs_getId(body->element) == 0) {
throw mjXError(elem, "World body cannot have joints");
}
// create joint and parse
mjsJoint* joint = mjs_addJoint(body, def);
OneJoint(elem, joint);
mjs_setFrame(joint->element, frame);
}
// freejoint sub-element
else if (name == "freejoint") {
// no joints allowed in world body
if (mjs_getId(body->element) == 0) {
throw mjXError(elem, "World body cannot have joints");
}
// create free joint without defaults
mjsJoint* joint = mjs_addFreeJoint(body);
mjs_setFrame(joint->element, frame);
// save defaults after creation, to make sure writing is ok
mjs_setDefault(joint->element, def);
// read attributes
string name;
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(joint->element, name.c_str());
}
ReadAttrInt(elem, "group", &joint->group);
MapValue(elem, "align", &joint->align, TFAuto_map, 3);
}
// geom sub-element
else if (name == "geom") {
// create geom and parse
mjsGeom* geom = mjs_addGeom(body, def);
OneGeom(elem, geom);
mjs_setFrame(geom->element, frame);
}
// site sub-element
else if (name == "site") {
// create site and parse
mjsSite* site = mjs_addSite(body, def);
OneSite(elem, site);
mjs_setFrame(site->element, frame);
}
// camera sub-element
else if (name == "camera") {
// create camera and parse
mjsCamera* camera = mjs_addCamera(body, def);
OneCamera(elem, camera);
mjs_setFrame(camera->element, frame);
}
// light sub-element
else if (name == "light") {
// create light and parse
mjsLight* light = mjs_addLight(body, def);
OneLight(elem, light);
mjs_setFrame(light->element, frame);
}
// plugin sub-element
else if (name == "plugin") {
OnePlugin(elem, &(body->plugin));
}
// composite sub-element
else if (name == "composite") {
// parse composite
OneComposite(elem, body, frame, def);
}
// flexcomp sub-element
else if (name == "flexcomp") {
// parse flexcomp
OneFlexcomp(elem, body, vfs);
}
// frame sub-element
else if (name == "frame") {
// read childdef
bool has_childclass = ReadAttrTxt(elem, "childclass", text);
const mjsDefault* childdef = has_childclass ? mjs_findDefault(spec, text.c_str()) : nullptr;
if (has_childclass && !childdef) {
throw mjXError(elem, "unknown default childclass");
}
// create frame
mjsFrame* pframe = mjs_addFrame(body, frame);
mjs_setString(pframe->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
mjs_setDefault(pframe->element, childdef ? childdef : def);
// read attributes
string name, childclass;
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(pframe->element, name.c_str());
}
if (ReadAttrTxt(elem, "childclass", childclass)) {
mjs_setString(pframe->childclass, childclass.c_str());
}
ReadAttr(elem, "pos", 3, pframe->pos, text);
ReadQuat(elem, "quat", pframe->quat, text);
ReadAlternative(elem, pframe->alt);
Body(elem, body, pframe, vfs);
}
// replicate sub-element
else if (name == "replicate") {
int count;
double offset[3] = {0, 0, 0};
double euler[3] = {0, 0, 0};
string separator = "";
ReadAttr(elem, "count", 1, &count, text, true);
ReadAttr(elem, "offset", 3, offset, text);
ReadAttr(elem, "euler", 3, euler, text);
ReadAttrTxt(elem, "sep", separator);
// store rotation difference
mjsOrientation alt;
mjs_defaultOrientation(&alt);
alt.type = mjORIENTATION_EULER;
mjuu_copyvec(alt.euler, euler, 3);
double rotation[4] = {1, 0, 0, 0};
mjs_resolveOrientation(rotation, spec->compiler.degree, spec->compiler.eulerseq, &alt);
// read childdef
bool has_childclass = ReadAttrTxt(elem, "childclass", text);
const mjsDefault* childdef = has_childclass ? mjs_findDefault(spec, text.c_str()) : nullptr;
if (has_childclass && !childdef) {
throw mjXError(elem, "unknown default childclass");
}
// create subtree
mjsBody* subtree = mjs_addBody(body, childdef);
double pos[3] = {0, 0, 0};
double quat[4] = {1, 0, 0, 0};
// parent frame that will be used to attach the subtree
mjsFrame* pframe = mjs_addFrame(subtree, frame);
mjs_setDefault(pframe->element, childdef ? childdef : def);
mjs_setString(pframe->info, ("line = " + std::to_string(elem->GetLineNum())).c_str());
// parse subtree
Body(elem, subtree, pframe, vfs);
// update pframe and attach
for (int i = 0; i < count; i++) {
// overwrite orientation to increase precision
alt.euler[0] = i*euler[0];
alt.euler[1] = i*euler[1];
alt.euler[2] = i*euler[2];
mjs_resolveOrientation(quat, spec->compiler.degree, spec->compiler.eulerseq, &alt);
// set position and orientation
mjuu_setvec(pframe->pos, pos[0], pos[1], pos[2]);
mjuu_setvec(pframe->quat, quat[0], quat[1], quat[2], quat[3]);
// accumulate rotation
mjuu_frameaccum(pos, quat, offset, rotation);
// process suffix
string suffix = separator;
UpdateString(suffix, count, i);
// attach to parent
if (!mjs_attach(body->element, pframe->element, /*prefix=*/"", suffix.c_str())) {
throw mjXError(elem, mjs_getError(spec));
}
}
// delete subtree
if (mjs_delete(spec, subtree->element)) {
throw mjXError(elem, mjs_getError(spec));
}
}
// body sub-element
else if (name == "body") {
// read childdef
bool has_childclass = ReadAttrTxt(elem, "childclass", text);
const mjsDefault* childdef = has_childclass ? mjs_findDefault(spec, text.c_str()) : nullptr;
if (has_childclass && !childdef) {
throw mjXError(elem, "unknown default childclass");
}
// create child body
mjsBody* child = mjs_addBody(body, childdef);
mjs_setString(child->info, string("line " + std::to_string(elem->GetLineNum())).c_str());
// set default from class or childclass
mjs_setDefault(child->element, childdef ? childdef : def);
// read attributes
string name, childclass;
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(child->element, name.c_str());
}
if (ReadAttrTxt(elem, "childclass", childclass)) {
mjs_setString(child->childclass, childclass.c_str());
}
ReadAttr(elem, "pos", 3, child->pos, text);
ReadQuat(elem, "quat", child->quat, text);
if (MapValue(elem, "mocap", &n, bool_map, 2)) {
child->mocap = (n == 1);
}
ReadAlternative(elem, child->alt);
// read gravcomp
ReadAttr(elem, "gravcomp", 1, &child->gravcomp, text);
// read userdata
std::vector<double> userdata;
ReadVector(elem, "user", userdata, text);
mjs_setDouble(child->userdata, userdata.data(), userdata.size());
// add frame
mjs_setFrame(child->element, frame);
// make recursive call
Body(elem, child, nullptr, vfs);
}
// attachment
else if (name == "attach") {
string model_name, body_name, prefix;
ReadAttrTxt(elem, "model", model_name, /*required=*/true);
ReadAttrTxt(elem, "body", body_name, /*required=*/false);
ReadAttrTxt(elem, "prefix", prefix, /*required=*/true);
mjsBody* child_body = mjs_findBody(spec, (prefix+body_name).c_str());
mjsFrame* pframe = frame ? frame : mjs_addFrame(body, nullptr);
if (!child_body) {
mjSpec* asset = mjs_findSpec(spec, model_name.c_str());
if (!asset) {
throw mjXError(elem, "could not find model '%s'", model_name.c_str());
}
mjsElement* child;
if (body_name.empty()) {
child = asset->element;
} else {
child_body = mjs_findBody(asset, body_name.c_str());
if (!child_body) {
throw mjXError(elem, "could not find body '%s''%s'", body_name.c_str());
}
child = child_body->element;
}
if (!mjs_attach(pframe->element, child, prefix.c_str(), "")) {
throw mjXError(elem, mjs_getError(spec));
}
} else {
// only set frame to existing body
if (mjs_setFrame(child_body->element, pframe)) {
throw mjXError(elem, mjs_getError(spec));
}
}
}
// no match
else {
throw mjXError(elem, "unrecognized model element '%s'", name.c_str());
}
// advance to next element
elem = NextSiblingElement(elem);
}
}
// contact section parser
void mjXReader::Contact(XMLElement* section) {
string text, name;
XMLElement* elem;
// iterate over child elements
elem = FirstChildElement(section);
while (elem) {
// get sub-element name
name = elem->Value();
// get class if specified, otherwise use default0
const mjsDefault* def = GetClass(elem);
if (!def) {
def = mjs_getSpecDefault(spec);
}
// geom pair to include
if (name == "pair") {
// create pair and parse
mjsPair* pair = mjs_addPair(spec, def);
OnePair(elem, pair);
}
// body pair to exclude
else if (name == "exclude") {
mjsExclude* exclude = mjs_addExclude(spec);
string exname, exbody1, exbody2;
// write error info
mjs_setString(exclude->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
// read name and body names
if (ReadAttrTxt(elem, "name", exname)) {
mjs_setName(exclude->element, exname.c_str());
}
ReadAttrTxt(elem, "body1", exbody1, true);
mjs_setString(exclude->bodyname1, exbody1.c_str());
ReadAttrTxt(elem, "body2", exbody2, true);
mjs_setString(exclude->bodyname2, exbody2.c_str());
}
// advance to next element
elem = NextSiblingElement(elem);
}
}
// constraint section parser
void mjXReader::Equality(XMLElement* section) {
XMLElement* elem;
// iterate over child elements
elem = FirstChildElement(section);
while (elem) {
// get class if specified, otherwise use default0
const mjsDefault* def = GetClass(elem);
if (!def) {
def = mjs_getSpecDefault(spec);
}
// create equality constraint and parse
mjsEquality* equality = mjs_addEquality(spec, def);
OneEquality(elem, equality);
// advance to next element
elem = NextSiblingElement(elem);
}
}
// deformable section parser
void mjXReader::Deformable(XMLElement* section, const mjVFS* vfs) {
string name;
XMLElement* elem;
// iterate over child elements
elem = FirstChildElement(section);
while (elem) {
// get sub-element name
name = elem->Value();
// get class if specified, otherwise use default0
const mjsDefault* def = GetClass(elem);
if (!def) {
def = mjs_getSpecDefault(spec);
}
// flex sub-element
if (name == "flex") {
// create flex and parse
mjsFlex* flex = mjs_addFlex(spec);
OneFlex(elem, flex);
}
// skin sub-element
else if (name == "skin") {
// create skin and parse
mjsSkin* skin = mjs_addSkin(spec);
OneSkin(elem, skin, vfs);
}
// advance to next element
elem = NextSiblingElement(elem);
}
}
// tendon section parser
void mjXReader::Tendon(XMLElement* section) {
string text, text1;
XMLElement* elem;
double data;
// iterate over child elements
elem = FirstChildElement(section);
while (elem) {
// get class if specified, otherwise use default0
const mjsDefault* def = GetClass(elem);
if (!def) {
def = mjs_getSpecDefault(spec);
}
// create tendon and parse
mjsTendon* tendon = mjs_addTendon(spec, def);
OneTendon(elem, tendon);
// process wrap sub-elements
XMLElement* sub = FirstChildElement(elem);
while (sub) {
// get wrap type
string type = sub->Value();
mjsWrap* wrap;;
// read attributes depending on type
if (type == "site") {
ReadAttrTxt(sub, "site", text, true);
wrap = mjs_wrapSite(tendon, text.c_str());
}
else if (type == "geom") {
ReadAttrTxt(sub, "geom", text, true);
if (!ReadAttrTxt(sub, "sidesite", text1)) {
text1.clear();
}
wrap = mjs_wrapGeom(tendon, text.c_str(), text1.c_str());
}
else if (type == "pulley") {
ReadAttr(sub, "divisor", 1, &data, text, true);
wrap = mjs_wrapPulley(tendon, data);
}
else if (type == "joint") {
ReadAttrTxt(sub, "joint", text, true);
ReadAttr(sub, "coef", 1, &data, text1, true);
wrap = mjs_wrapJoint(tendon, text.c_str(), data);
}
else {
throw mjXError(sub, "unknown wrap type"); // SHOULD NOT OCCUR
}
mjs_setString(wrap->info, ("line " + std::to_string(sub->GetLineNum())).c_str());
// advance to next sub-element
sub = NextSiblingElement(sub);
}
// advance to next element
elem = NextSiblingElement(elem);
}
}
// actuator section parser
void mjXReader::Actuator(XMLElement* section) {
XMLElement* elem;
// iterate over child elements
elem = FirstChildElement(section);
while (elem) {
// get class if specified, otherwise use default0
const mjsDefault* def = GetClass(elem);
if (!def) {
def = mjs_getSpecDefault(spec);
}
// create actuator and parse
mjsActuator* actuator = mjs_addActuator(spec, def);
OneActuator(elem, actuator);
// advance to next element
elem = NextSiblingElement(elem);
}
}
// sensor section parser
void mjXReader::Sensor(XMLElement* section) {
int n;
XMLElement* elem = FirstChildElement(section);
while (elem) {
// create sensor, get string type
mjsSensor* sensor = mjs_addSensor(spec);
string type = elem->Value();
string text, name, objname, refname;
std::vector<double> userdata;
// read name, noise, userdata
if (ReadAttrTxt(elem, "name", name)) {
mjs_setName(sensor->element, name.c_str());
}
ReadAttr(elem, "cutoff", 1, &sensor->cutoff, text);
ReadAttr(elem, "noise", 1, &sensor->noise, text);
if (ReadVector(elem, "user", userdata, text)) {
mjs_setDouble(sensor->userdata, userdata.data(), userdata.size());
}
// common robotic sensors, attached to a site
if (type == "touch") {
sensor->type = mjSENS_TOUCH;
sensor->objtype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", objname, true);
} else if (type == "accelerometer") {
sensor->type = mjSENS_ACCELEROMETER;
sensor->objtype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", objname, true);
} else if (type == "velocimeter") {
sensor->type = mjSENS_VELOCIMETER;
sensor->objtype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", objname, true);
} else if (type == "gyro") {
sensor->type = mjSENS_GYRO;
sensor->objtype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", objname, true);
} else if (type == "force") {
sensor->type = mjSENS_FORCE;
sensor->objtype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", objname, true);
} else if (type == "torque") {
sensor->type = mjSENS_TORQUE;
sensor->objtype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", objname, true);
} else if (type == "magnetometer") {
sensor->type = mjSENS_MAGNETOMETER;
sensor->objtype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", objname, true);
} else if (type == "camprojection") {
sensor->type = mjSENS_CAMPROJECTION;
sensor->objtype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", objname, true);
ReadAttrTxt(elem, "camera", refname, true);
sensor->reftype = mjOBJ_CAMERA;
} else if (type == "rangefinder") {
sensor->type = mjSENS_RANGEFINDER;
sensor->objtype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", objname, true);
}
// sensors related to scalar joints, tendons, actuators
else if (type == "jointpos") {
sensor->type = mjSENS_JOINTPOS;
sensor->objtype = mjOBJ_JOINT;
ReadAttrTxt(elem, "joint", objname, true);
} else if (type == "jointvel") {
sensor->type = mjSENS_JOINTVEL;
sensor->objtype = mjOBJ_JOINT;
ReadAttrTxt(elem, "joint", objname, true);
} else if (type == "tendonpos") {
sensor->type = mjSENS_TENDONPOS;
sensor->objtype = mjOBJ_TENDON;
ReadAttrTxt(elem, "tendon", objname, true);
} else if (type == "tendonvel") {
sensor->type = mjSENS_TENDONVEL;
sensor->objtype = mjOBJ_TENDON;
ReadAttrTxt(elem, "tendon", objname, true);
} else if (type == "actuatorpos") {
sensor->type = mjSENS_ACTUATORPOS;
sensor->objtype = mjOBJ_ACTUATOR;
ReadAttrTxt(elem, "actuator", objname, true);
} else if (type == "actuatorvel") {
sensor->type = mjSENS_ACTUATORVEL;
sensor->objtype = mjOBJ_ACTUATOR;
ReadAttrTxt(elem, "actuator", objname, true);
} else if (type == "actuatorfrc") {
sensor->type = mjSENS_ACTUATORFRC;
sensor->objtype = mjOBJ_ACTUATOR;
ReadAttrTxt(elem, "actuator", objname, true);
} else if (type == "jointactuatorfrc") {
sensor->type = mjSENS_JOINTACTFRC;
sensor->objtype = mjOBJ_JOINT;
ReadAttrTxt(elem, "joint", objname, true);
} else if (type=="tendonactuatorfrc") {
sensor->type = mjSENS_TENDONACTFRC;
sensor->objtype = mjOBJ_TENDON;
ReadAttrTxt(elem, "tendon", objname, true);
}
// sensors related to ball joints
else if (type == "ballquat") {
sensor->type = mjSENS_BALLQUAT;
sensor->objtype = mjOBJ_JOINT;
ReadAttrTxt(elem, "joint", objname, true);
} else if (type == "ballangvel") {
sensor->type = mjSENS_BALLANGVEL;
sensor->objtype = mjOBJ_JOINT;
ReadAttrTxt(elem, "joint", objname, true);
}
// joint and tendon limit sensors
else if (type == "jointlimitpos") {
sensor->type = mjSENS_JOINTLIMITPOS;
sensor->objtype = mjOBJ_JOINT;
ReadAttrTxt(elem, "joint", objname, true);
} else if (type == "jointlimitvel") {
sensor->type = mjSENS_JOINTLIMITVEL;
sensor->objtype = mjOBJ_JOINT;
ReadAttrTxt(elem, "joint", objname, true);
} else if (type == "jointlimitfrc") {
sensor->type = mjSENS_JOINTLIMITFRC;
sensor->objtype = mjOBJ_JOINT;
ReadAttrTxt(elem, "joint", objname, true);
} else if (type == "tendonlimitpos") {
sensor->type = mjSENS_TENDONLIMITPOS;
sensor->objtype = mjOBJ_TENDON;
ReadAttrTxt(elem, "tendon", objname, true);
} else if (type == "tendonlimitvel") {
sensor->type = mjSENS_TENDONLIMITVEL;
sensor->objtype = mjOBJ_TENDON;
ReadAttrTxt(elem, "tendon", objname, true);
} else if (type == "tendonlimitfrc") {
sensor->type = mjSENS_TENDONLIMITFRC;
sensor->objtype = mjOBJ_TENDON;
ReadAttrTxt(elem, "tendon", objname, true);
}
// sensors attached to an object with spatial frame: (x)body, geom, site, camera
else if (type == "framepos") {
sensor->type = mjSENS_FRAMEPOS;
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
if (ReadAttrTxt(elem, "reftype", text)) {
sensor->reftype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "refname", refname, true);
} else if (ReadAttrTxt(elem, "refname", text)) {
throw mjXError(elem, "refname '%s' given but reftype is missing", text.c_str());
}
} else if (type == "framequat") {
sensor->type = mjSENS_FRAMEQUAT;
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
if (ReadAttrTxt(elem, "reftype", text)) {
sensor->reftype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "refname", refname, true);
} else if (ReadAttrTxt(elem, "refname", text)) {
throw mjXError(elem, "refname '%s' given but reftype is missing", text.c_str());
}
} else if (type == "framexaxis") {
sensor->type = mjSENS_FRAMEXAXIS;
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
if (ReadAttrTxt(elem, "reftype", text)) {
sensor->reftype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "refname", refname, true);
} else if (ReadAttrTxt(elem, "refname", text)) {
throw mjXError(elem, "refname '%s' given but reftype is missing", text.c_str());
}
} else if (type == "frameyaxis") {
sensor->type = mjSENS_FRAMEYAXIS;
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
if (ReadAttrTxt(elem, "reftype", text)) {
sensor->reftype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "refname", refname, true);
} else if (ReadAttrTxt(elem, "refname", text)) {
throw mjXError(elem, "refname '%s' given but reftype is missing", text.c_str());
}
} else if (type == "framezaxis") {
sensor->type = mjSENS_FRAMEZAXIS;
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
if (ReadAttrTxt(elem, "reftype", text)) {
sensor->reftype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "refname", refname, true);
} else if (ReadAttrTxt(elem, "refname", text)) {
throw mjXError(elem, "refname '%s' given but reftype is missing", text.c_str());
}
} else if (type == "framelinvel") {
sensor->type = mjSENS_FRAMELINVEL;
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
if (ReadAttrTxt(elem, "reftype", text)) {
sensor->reftype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "refname", refname, true);
} else if (ReadAttrTxt(elem, "refname", text)) {
throw mjXError(elem, "refname '%s' given but reftype is missing", text.c_str());
}
} else if (type == "frameangvel") {
sensor->type = mjSENS_FRAMEANGVEL;
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
if (ReadAttrTxt(elem, "reftype", text)) {
sensor->reftype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "refname", refname, true);
} else if (ReadAttrTxt(elem, "refname", text)) {
throw mjXError(elem, "refname '%s' given but reftype is missing", text.c_str());
}
} else if (type == "framelinacc") {
sensor->type = mjSENS_FRAMELINACC;
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
} else if (type == "frameangacc") {
sensor->type = mjSENS_FRAMEANGACC;
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
} else if (type == "insidesite") {
sensor->type = mjSENS_INSIDESITE;
sensor->reftype = mjOBJ_SITE;
ReadAttrTxt(elem, "site", refname, true);
ReadAttrTxt(elem, "objtype", text, true);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname, true);
}
// sensors related to kinematic subtrees; attached to a body (which is the subtree root)
else if (type == "subtreecom") {
sensor->type = mjSENS_SUBTREECOM;
sensor->objtype = mjOBJ_BODY;
ReadAttrTxt(elem, "body", objname, true);
} else if (type == "subtreelinvel") {
sensor->type = mjSENS_SUBTREELINVEL;
sensor->objtype = mjOBJ_BODY;
ReadAttrTxt(elem, "body", objname, true);
} else if (type == "subtreeangmom") {
sensor->type = mjSENS_SUBTREEANGMOM;
sensor->objtype = mjOBJ_BODY;
ReadAttrTxt(elem, "body", objname, true);
}
// sensors for geometric distance; attached to geoms or bodies
else if (type == "distance" || type == "normal" || type == "fromto") {
bool has_body1 = ReadAttrTxt(elem, "body1", objname);
bool has_geom1 = ReadAttrTxt(elem, "geom1", objname);
if (has_body1 == has_geom1) {
throw mjXError(elem, "exactly one of (geom1, body1) must be specified");
}
sensor->objtype = has_body1 ? mjOBJ_BODY : mjOBJ_GEOM;
bool has_body2 = ReadAttrTxt(elem, "body2", refname);
bool has_geom2 = ReadAttrTxt(elem, "geom2", refname);
if (has_body2 == has_geom2) {
throw mjXError(elem, "exactly one of (geom2, body2) must be specified");
}
sensor->reftype = has_body2 ? mjOBJ_BODY : mjOBJ_GEOM;
if (type == "distance") {
sensor->type = mjSENS_GEOMDIST;
} else if (type == "normal") {
sensor->type = mjSENS_GEOMNORMAL;
} else {
sensor->type = mjSENS_GEOMFROMTO;
}
}
// global sensors
else if (type == "e_potential") {
sensor->type = mjSENS_E_POTENTIAL;
sensor->objtype = mjOBJ_UNKNOWN;
} else if (type == "e_kinetic") {
sensor->type = mjSENS_E_KINETIC;
sensor->objtype = mjOBJ_UNKNOWN;
} else if (type == "clock") {
sensor->type = mjSENS_CLOCK;
sensor->objtype = mjOBJ_UNKNOWN;
}
// user-defined sensor
else if (type == "user") {
sensor->type = mjSENS_USER;
bool objname_given = ReadAttrTxt(elem, "objname", objname);
if (ReadAttrTxt(elem, "objtype", text)) {
if (!objname_given) {
throw mjXError(elem, "objtype '%s' given but objname is missing", text.c_str());
}
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
} else if (objname_given) {
throw mjXError(elem, "objname '%s' given but objtype is missing", objname.c_str());
}
ReadAttrInt(elem, "dim", &sensor->dim, true);
// keywords
if (MapValue(elem, "needstage", &n, stage_map, stage_sz)) {
sensor->needstage = (mjtStage)n;
}
if (MapValue(elem, "datatype", &n, datatype_map, datatype_sz)) {
sensor->datatype = (mjtDataType)n;
}
}
else if (type == "plugin") {
sensor->type = mjSENS_PLUGIN;
OnePlugin(elem, &sensor->plugin);
ReadAttrTxt(elem, "objtype", text);
sensor->objtype = (mjtObj)mju_str2Type(text.c_str());
ReadAttrTxt(elem, "objname", objname);
if (sensor->objtype != mjOBJ_UNKNOWN && objname.empty()) {
throw mjXError(elem, "objtype is specified but objname is not");
}
if (sensor->objtype == mjOBJ_UNKNOWN && !objname.empty()) {
throw mjXError(elem, "objname is specified but objtype is not");
}
if (ReadAttrTxt(elem, "reftype", text)) {
sensor->reftype = (mjtObj)mju_str2Type(text.c_str());
}
ReadAttrTxt(elem, "refname", refname);
if (sensor->reftype != mjOBJ_UNKNOWN && refname.empty()) {
throw mjXError(elem, "reftype is specified but refname is not");
}
if (sensor->reftype == mjOBJ_UNKNOWN && !refname.empty()) {
throw mjXError(elem, "refname is specified but reftype is not");
}
}
if (!objname.empty()) {
mjs_setString(sensor->objname, objname.c_str());
}
if (!refname.empty()) {
mjs_setString(sensor->refname, refname.c_str());
}
// write info
mjs_setString(sensor->info, ("line " + std::to_string(elem->GetLineNum())).c_str());
// advance to next element
elem = NextSiblingElement(elem);
}
}
// keyframe section parser
void mjXReader::Keyframe(XMLElement* section) {
XMLElement* elem;
// iterate over child elements
elem = FirstChildElement(section);
while (elem) {
string text, name = "";
// add keyframe
mjsKey* key = mjs_addKey(spec);
// read name, time
ReadAttrTxt(elem, "name", name);
mjs_setName(key->element, name.c_str());
ReadAttr(elem, "time", 1, &key->time, text);
// read qpos
auto maybe_data = ReadAttrVec<double>(elem, "qpos", false);
if (maybe_data.has_value()) {
mjs_setDouble(key->qpos, maybe_data->data(), maybe_data->size());
}
// read qvel
maybe_data = ReadAttrVec<double>(elem, "qvel", false);
if (maybe_data.has_value()) {
mjs_setDouble(key->qvel, maybe_data->data(), maybe_data->size());
}
// read act
maybe_data = ReadAttrVec<double>(elem, "act", false);
if (maybe_data.has_value()) {
mjs_setDouble(key->act, maybe_data->data(), maybe_data->size());
}
// read mpos
maybe_data = ReadAttrVec<double>(elem, "mpos", false);
if (maybe_data.has_value()) {
mjs_setDouble(key->mpos, maybe_data->data(), maybe_data->size());
}
// read mquat
maybe_data = ReadAttrVec<double>(elem, "mquat", false);
if (maybe_data.has_value()) {
mjs_setDouble(key->mquat, maybe_data->data(), maybe_data->size());
}
// read ctrl
maybe_data = ReadAttrVec<double>(elem, "ctrl", false);
if (maybe_data.has_value()) {
mjs_setDouble(key->ctrl, maybe_data->data(), maybe_data->size());
}
// advance to next element
elem = NextSiblingElement(elem);
}
}
// get defaults class
const mjsDefault* mjXReader::GetClass(XMLElement* section) {
string text;
if (!ReadAttrTxt(section, "class", text)) {
return nullptr;
}
const mjsDefault* def = mjs_findDefault(spec, text.c_str());
if (!def) {
throw mjXError(
section,
string("unknown default class name '" + text + "'").c_str());
}
return def;
}
void mjXReader::SetModelFileDir(const string& modelfiledir) {
modelfiledir_ = FilePath(modelfiledir);
}
void mjXReader::SetAssetDir(const string& assetdir) {
assetdir_ = FilePath(assetdir);
}
void mjXReader::SetMeshDir(const string& meshdir) {
meshdir_ = FilePath(meshdir);
}
void mjXReader::SetTextureDir(const string& texturedir) {
texturedir_ = FilePath(texturedir);
}
FilePath mjXReader::AssetDir() const {
return modelfiledir_ + assetdir_;
}
FilePath mjXReader::MeshDir() const {
if (meshdir_.empty()) {
return AssetDir();
}
return modelfiledir_ + meshdir_;
}
FilePath mjXReader::TextureDir() const {
if (texturedir_.empty()) {
return AssetDir();
}
return modelfiledir_ + texturedir_;
}