static void printBox (PrintingContext &c, dxGeom *g) { dVector3 sides; dGeomBoxGetLengths (g,sides); c.print ("type","box"); c.print ("sides",sides); }
static void printCapsule (PrintingContext &c, dxGeom *g) { dReal radius,length; dGeomCapsuleGetParams (g,&radius,&length); c.print ("type","capsule"); c.print ("radius",radius); c.print ("length",length); }
static void printCylinder (PrintingContext &c, dxGeom *g) { dReal radius,length; dGeomCylinderGetParams (g,&radius,&length); c.print ("type","cylinder"); c.print ("radius",radius); c.print ("length",length); }
static void printSlider (PrintingContext &c, dxJoint *j) { dxJointSlider *s = (dxJointSlider*) j; c.print ("axis1",s->axis1); c.print ("qrel",s->qrel,4); c.print ("offset",s->offset); printLimot (c,s->limot,-1); }
static void printPlane (PrintingContext &c, dxGeom *g) { dVector4 e; dGeomPlaneGetParams (g,e); c.print ("type","plane"); c.print ("normal",e); c.print ("d",e[3]); }
static void printHinge (PrintingContext &c, dxJoint *j) { dxJointHinge *h = (dxJointHinge*) j; c.print ("anchor1",h->anchor1); c.print ("anchor2",h->anchor2); c.print ("axis1",h->axis1); c.print ("axis2",h->axis2); c.print ("qrel",h->qrel,4); printLimot (c,h->limot,-1); }
static void printPiston (PrintingContext &c, dxJoint *j) { dxJointPiston *rap = (dxJointPiston*) j; c.print ("anchor1",rap->anchor1); c.print ("anchor2",rap->anchor2); c.print ("axis1",rap->axis1); c.print ("axis2",rap->axis2); c.print ("qrel",rap->qrel,4); printLimot (c,rap->limotP,1); printLimot (c, rap->limotR, 2); }
static void printLMotor (PrintingContext &c, dxJoint *j) { dxJointLMotor *a = (dxJointLMotor*) j; c.print("num", a->num); c.printIndent(); fprintf (c.file,"rel = {%d,%d,%d},\n",a->rel[0],a->rel[1],a->rel[2]); c.print ("axis1",a->axis[0]); c.print ("axis2",a->axis[1]); c.print ("axis3",a->axis[2]); for (int i=0; i<3; i++) printLimot (c,a->limot[i],i+1); }
static void printPR (PrintingContext &c, dxJoint *j) { dxJointPR *pr = (dxJointPR*) j; c.print ("anchor2",pr->anchor2); c.print ("axisR1",pr->axisR1); c.print ("axisR2",pr->axisR2); c.print ("axisP1",pr->axisP1); c.print ("qrel",pr->qrel,4); c.print ("offset",pr->offset); printLimot (c,pr->limotP,1); printLimot (c,pr->limotR,2); }
static void printUniversal (PrintingContext &c, dxJoint *j) { dxJointUniversal *u = (dxJointUniversal*) j; c.print ("anchor1",u->anchor1); c.print ("anchor2",u->anchor2); c.print ("axis1",u->axis1); c.print ("axis2",u->axis2); c.print ("qrel1",u->qrel1,4); c.print ("qrel2",u->qrel2,4); printLimot (c,u->limot1,1); printLimot (c,u->limot2,2); }
static void printPU (PrintingContext &c, dxJoint *j) { dxJointPU *pu = (dxJointPU*) j; c.print ("anchor1",pu->anchor1); c.print ("anchor2",pu->anchor2); c.print ("axis1",pu->axis1); c.print ("axis2",pu->axis2); c.print ("axisP",pu->axisP1); c.print ("qrel1",pu->qrel1,4); c.print ("qrel2",pu->qrel2,4); printLimot (c,pu->limot1,1); printLimot (c,pu->limot2,2); printLimot (c,pu->limotP,3); }
static void printHinge2 (PrintingContext &c, dxJoint *j) { dxJointHinge2 *h = (dxJointHinge2*) j; c.print ("anchor1",h->anchor1); c.print ("anchor2",h->anchor2); c.print ("axis1",h->axis1); c.print ("axis2",h->axis2); c.print ("v1",h->v1); //@@@ much better to write out 'qrel' here, if it's available c.print ("v2",h->v2); c.print ("susp_erp",h->susp_erp); c.print ("susp_cfm",h->susp_cfm); printLimot (c,h->limot1,1); printLimot (c,h->limot2,2); }
static void printGeomTransform (PrintingContext &c, dxGeom *g) { dxGeom *g2 = dGeomTransformGetGeom (g); const dReal *pos = dGeomGetPosition (g2); dQuaternion q; dGeomGetQuaternion (g2,q); c.print ("type","transform"); c.print ("pos",pos); c.print ("q",q,4); c.print ("geometry = {"); c.indent++; printGeom (c,g2); c.indent--; c.print ("}"); }
static void printGeom (PrintingContext &c, dxGeom *g) { unsigned long category = dGeomGetCategoryBits (g); if (category != (unsigned long)(~0)) { c.printIndent(); fprintf (c.file,"category_bits = %lu\n",category); } unsigned long collide = dGeomGetCollideBits (g); if (collide != (unsigned long)(~0)) { c.printIndent(); fprintf (c.file,"collide_bits = %lu\n",collide); } if (!dGeomIsEnabled (g)) { c.print ("disabled",1); } switch (g->type) { case dSphereClass: printSphere (c,g); break; case dBoxClass: printBox (c,g); break; case dCapsuleClass: printCapsule (c,g); break; case dCylinderClass: printCylinder (c,g); break; case dPlaneClass: printPlane (c,g); break; case dRayClass: printRay (c,g); break; case dConvexClass: printConvex (c,g); break; case dTriMeshClass: printTriMesh (c,g); break; case dHeightfieldClass: printHeightfieldClass (c,g); break; } }
static void printTriMesh (PrintingContext &c, dxGeom * /*g*/) { c.print ("type","trimesh"); //@@@ i don't think that the trimesh accessor functions are really // sufficient to read out all the triangle data, and anyway we // should have a method of not duplicating trimesh data that is // shared. }
static void printLimot (PrintingContext &c, dxJointLimitMotor &limot, int num) { if (num >= 0) { c.printIndent(); fprintf (c.file,"limit%d = {\n",num); } else { c.print ("limit = {"); } c.indent++; c.print ("low_stop",limot.lostop); c.print ("high_stop",limot.histop); c.printNonzero ("bounce",limot.bounce); c.print ("ODE = {"); c.indent++; c.printNonzero ("stop_erp",limot.stop_erp); c.printNonzero ("stop_cfm",limot.stop_cfm); c.indent--; c.print ("},"); c.indent--; c.print ("},"); if (num >= 0) { c.printIndent(); fprintf (c.file,"motor%d = {\n",num); } else { c.print ("motor = {"); } c.indent++; c.printNonzero ("vel",limot.vel); c.printNonzero ("fmax",limot.fmax); c.print ("ODE = {"); c.indent++; c.printNonzero ("fudge_factor",limot.fudge_factor); c.printNonzero ("normal_cfm",limot.normal_cfm); c.indent--; c.print ("},"); c.indent--; c.print ("},"); }
void dWorldExportDIF (dWorldID w, FILE *file, const char *prefix) { PrintingContext c; c.file = file; #if defined(dSINGLE) c.precision = 7; #else c.precision = 15; #endif c.indent = 1; fprintf (file,"-- Dynamics Interchange Format v0.1\n\n%sworld = dynamics.world {\n",prefix); c.print ("gravity",w->gravity); c.print ("ODE = {"); c.indent++; c.print ("ERP",w->global_erp); c.print ("CFM",w->global_cfm); c.print ("auto_disable = {"); c.indent++; c.print ("linear_threshold",w->adis.linear_average_threshold); c.print ("angular_threshold",w->adis.angular_average_threshold); c.print ("average_samples",(int)w->adis.average_samples); c.print ("idle_time",w->adis.idle_time); c.print ("idle_steps",w->adis.idle_steps); fprintf (file,"\t\t},\n\t},\n}\n"); c.indent -= 3; // bodies int num = 0; fprintf (file,"%sbody = {}\n",prefix); for (dxBody *b=w->firstbody; b; b=(dxBody*)b->next) { b->tag = num; fprintf (file,"%sbody[%d] = dynamics.body {\n\tworld = %sworld,\n",prefix,num,prefix); c.indent++; c.print ("pos",b->posr.pos); c.print ("q",b->q,4); c.print ("lvel",b->lvel); c.print ("avel",b->avel); c.print ("mass",b->mass.mass); fprintf (file,"\tI = {{"); for (int i=0; i<3; i++) { for (int j=0; j<3; j++) { c.printReal (b->mass.I[i*4+j]); if (j < 2) fputc (',',file); } if (i < 2) fprintf (file,"},{"); } fprintf (file,"}},\n"); c.printNonzero ("com",b->mass.c); c.print ("ODE = {"); c.indent++; if (b->flags & dxBodyFlagFiniteRotation) c.print ("finite_rotation",1); if (b->flags & dxBodyDisabled) c.print ("disabled",1); if (b->flags & dxBodyNoGravity) c.print ("no_gravity",1); if (b->flags & dxBodyAutoDisable) { c.print ("auto_disable = {"); c.indent++; c.print ("linear_threshold",b->adis.linear_average_threshold); c.print ("angular_threshold",b->adis.angular_average_threshold); c.print ("average_samples",(int)b->adis.average_samples); c.print ("idle_time",b->adis.idle_time); c.print ("idle_steps",b->adis.idle_steps); c.print ("time_left",b->adis_timeleft); c.print ("steps_left",b->adis_stepsleft); c.indent--; c.print ("},"); } c.printNonzero ("facc",b->facc); c.printNonzero ("tacc",b->tacc); if (b->flags & dxBodyFlagFiniteRotationAxis) { c.print ("finite_rotation_axis",b->finite_rot_axis); } c.indent--; c.print ("},"); if (b->geom) { c.print ("geometry = {"); c.indent++; for (dxGeom *g=b->geom; g; g=g->body_next) { c.print ("{"); c.indent++; printGeom (c,g); c.indent--; c.print ("},"); } c.indent--; c.print ("},"); } c.indent--; c.print ("}"); num++; } // joints num = 0; fprintf (file,"%sjoint = {}\n",prefix); for (dxJoint *j=w->firstjoint; j; j=(dxJoint*)j->next) { c.indent++; const char *name = getJointName (j); fprintf (file, "%sjoint[%d] = dynamics.%s_joint {\n" "\tworld = %sworld,\n" "\tbody = {" ,prefix,num,name,prefix); if ( j->node[0].body ) fprintf (file,"%sbody[%d]",prefix,j->node[0].body->tag); if ( j->node[1].body ) fprintf (file,",%sbody[%d]",prefix,j->node[1].body->tag); fprintf (file,"}\n"); switch (j->type()) { case dJointTypeBall: printBall (c,j); break; case dJointTypeHinge: printHinge (c,j); break; case dJointTypeSlider: printSlider (c,j); break; case dJointTypeContact: printContact (c,j); break; case dJointTypeUniversal: printUniversal (c,j); break; case dJointTypeHinge2: printHinge2 (c,j); break; case dJointTypeFixed: printFixed (c,j); break; case dJointTypeAMotor: printAMotor (c,j); break; case dJointTypeLMotor: printLMotor (c,j); break; case dJointTypePR: printPR (c,j); break; case dJointTypePU: printPU (c,j); break; case dJointTypePiston: printPiston (c,j); break; default: c.print("unknown joint"); } c.indent--; c.print ("}"); num++; } }
static void printHeightfieldClass (PrintingContext &c, dxGeom * /*g*/) { c.print ("type","heightfield"); ///@todo Print information about heightfield }
static void printConvex (PrintingContext &c, dxGeom * /*g*/) { c.print ("type","convex"); ///@todo Print information about convex hull }
static void printRay (PrintingContext &c, dxGeom *g) { dReal length = dGeomRayGetLength (g); c.print ("type","ray"); c.print ("length",length); }
static void printBall (PrintingContext &c, dxJoint *j) { dxJointBall *b = (dxJointBall*) j; c.print ("anchor1",b->anchor1); c.print ("anchor2",b->anchor2); }
static void printContact (PrintingContext &c, dxJoint *j) { dxJointContact *ct = (dxJointContact*) j; int mode = ct->contact.surface.mode; c.print ("pos",ct->contact.geom.pos); c.print ("normal",ct->contact.geom.normal); c.print ("depth",ct->contact.geom.depth); //@@@ may want to write the geoms g1 and g2 that are involved, for debugging. // to do this we must have written out all geoms in all spaces, not just // geoms that are attached to bodies. c.print ("mu",ct->contact.surface.mu); if (mode & dContactMu2) c.print ("mu2",ct->contact.surface.mu2); if (mode & dContactBounce) c.print ("bounce",ct->contact.surface.bounce); if (mode & dContactBounce) c.print ("bounce_vel",ct->contact.surface.bounce_vel); if (mode & dContactSoftERP) c.print ("soft_ERP",ct->contact.surface.soft_erp); if (mode & dContactSoftCFM) c.print ("soft_CFM",ct->contact.surface.soft_cfm); if (mode & dContactMotion1) c.print ("motion1",ct->contact.surface.motion1); if (mode & dContactMotion2) c.print ("motion2",ct->contact.surface.motion2); if (mode & dContactSlip1) c.print ("slip1",ct->contact.surface.slip1); if (mode & dContactSlip2) c.print ("slip2",ct->contact.surface.slip2); int fa = 0; // friction approximation code if (mode & dContactApprox1_1) fa |= 1; if (mode & dContactApprox1_2) fa |= 2; if (fa) c.print ("friction_approximation",fa); if (mode & dContactFDir1) c.print ("fdir1",ct->contact.fdir1); }
static void printFixed (PrintingContext &c, dxJoint *j) { dxJointFixed *f = (dxJointFixed*) j; c.print ("qrel",f->qrel); c.print ("offset",f->offset); }
static void printSphere (PrintingContext &c, dxGeom *g) { c.print ("type","sphere"); c.print ("radius",dGeomSphereGetRadius (g)); }