/** * @file llvolume.cpp * * $LicenseInfo:firstyear=2002&license=viewergpl$ * * Copyright (c) 2002-2009, Linden Research, Inc. * * Second Life Viewer Source Code * The source code in this file ("Source Code") is provided by Linden Lab * to you under the terms of the GNU General Public License, version 2.0 * ("GPL"), unless you have obtained a separate licensing agreement * ("Other License"), formally executed by you and Linden Lab. Terms of * the GPL can be found in doc/GPL-license.txt in this distribution, or * online at http://secondlifegrid.net/programs/open_source/licensing/gplv2 * * There are special exceptions to the terms and conditions of the GPL as * it is applied to this Source Code. View the full text of the exception * in the file doc/FLOSS-exception.txt in this software distribution, or * online at * http://secondlifegrid.net/programs/open_source/licensing/flossexception * * By copying, modifying or distributing this software, you acknowledge * that you have read and understood your obligations described above, * and agree to abide by those obligations. * * ALL LINDEN LAB SOURCE CODE IS PROVIDED "AS IS." LINDEN LAB MAKES NO * WARRANTIES, EXPRESS, IMPLIED OR OTHERWISE, REGARDING ITS ACCURACY, * COMPLETENESS OR PERFORMANCE. * $/LicenseInfo$ */ #include "linden_common.h" #include "llmath.h" #include #include "llerror.h" #include "llmemtype.h" #include "llvolumemgr.h" #include "v2math.h" #include "v3math.h" #include "v4math.h" #include "m4math.h" #include "m3math.h" #include "lldarray.h" #include "llvolume.h" #include "llstl.h" #define DEBUG_SILHOUETTE_BINORMALS 0 #define DEBUG_SILHOUETTE_NORMALS 0 // TomY: Use this to display normals using the silhouette #define DEBUG_SILHOUETTE_EDGE_MAP 0 // DaveP: Use this to display edge map using the silhouette const F32 CUT_MIN = 0.f; const F32 CUT_MAX = 1.f; const F32 MIN_CUT_DELTA = 0.02f; const F32 HOLLOW_MIN = 0.f; const F32 HOLLOW_MAX = 0.99f; const F32 HOLLOW_MAX_SQUARE = 0.7f; const F32 TWIST_MIN = -1.f; const F32 TWIST_MAX = 1.f; const F32 RATIO_MIN = 0.f; const F32 RATIO_MAX = 2.f; // Tom Y: Inverted sense here: 0 = top taper, 2 = bottom taper const F32 HOLE_X_MIN= 0.01f; const F32 HOLE_X_MAX= 1.0f; const F32 HOLE_Y_MIN= 0.01f; const F32 HOLE_Y_MAX= 0.5f; const F32 SHEAR_MIN = -0.5f; const F32 SHEAR_MAX = 0.5f; const F32 REV_MIN = 1.f; const F32 REV_MAX = 4.f; const F32 TAPER_MIN = -1.f; const F32 TAPER_MAX = 1.f; const F32 SKEW_MIN = -0.95f; const F32 SKEW_MAX = 0.95f; const F32 SCULPT_MIN_AREA = 0.002f; BOOL check_same_clock_dir( const LLVector3& pt1, const LLVector3& pt2, const LLVector3& pt3, const LLVector3& norm) { LLVector3 test = (pt2-pt1)%(pt3-pt2); //answer if(test * norm < 0) { return FALSE; } else { return TRUE; } } BOOL LLLineSegmentBoxIntersect(const LLVector3& start, const LLVector3& end, const LLVector3& center, const LLVector3& size) { float fAWdU[3]; LLVector3 dir; LLVector3 diff; for (U32 i = 0; i < 3; i++) { dir.mV[i] = 0.5f * (end.mV[i] - start.mV[i]); diff.mV[i] = (0.5f * (end.mV[i] + start.mV[i])) - center.mV[i]; fAWdU[i] = fabsf(dir.mV[i]); if(fabsf(diff.mV[i])>size.mV[i] + fAWdU[i]) return false; } float f; f = dir.mV[1] * diff.mV[2] - dir.mV[2] * diff.mV[1]; if(fabsf(f)>size.mV[1]*fAWdU[2] + size.mV[2]*fAWdU[1]) return false; f = dir.mV[2] * diff.mV[0] - dir.mV[0] * diff.mV[2]; if(fabsf(f)>size.mV[0]*fAWdU[2] + size.mV[2]*fAWdU[0]) return false; f = dir.mV[0] * diff.mV[1] - dir.mV[1] * diff.mV[0]; if(fabsf(f)>size.mV[0]*fAWdU[1] + size.mV[1]*fAWdU[0]) return false; return true; } // intersect test between triangle vert0, vert1, vert2 and a ray from orig in direction dir. // returns TRUE if intersecting and returns barycentric coordinates in intersection_a, intersection_b, // and returns the intersection point along dir in intersection_t. // Moller-Trumbore algorithm BOOL LLTriangleRayIntersect(const LLVector3& vert0, const LLVector3& vert1, const LLVector3& vert2, const LLVector3& orig, const LLVector3& dir, F32* intersection_a, F32* intersection_b, F32* intersection_t, BOOL two_sided) { F32 u, v, t; /* find vectors for two edges sharing vert0 */ LLVector3 edge1 = vert1 - vert0; LLVector3 edge2 = vert2 - vert0;; /* begin calculating determinant - also used to calculate U parameter */ LLVector3 pvec = dir % edge2; /* if determinant is near zero, ray lies in plane of triangle */ F32 det = edge1 * pvec; if (!two_sided) { if (det < F_APPROXIMATELY_ZERO) { return FALSE; } /* calculate distance from vert0 to ray origin */ LLVector3 tvec = orig - vert0; /* calculate U parameter and test bounds */ u = tvec * pvec; if (u < 0.f || u > det) { return FALSE; } /* prepare to test V parameter */ LLVector3 qvec = tvec % edge1; /* calculate V parameter and test bounds */ v = dir * qvec; if (v < 0.f || u + v > det) { return FALSE; } /* calculate t, scale parameters, ray intersects triangle */ t = edge2 * qvec; F32 inv_det = 1.0 / det; t *= inv_det; u *= inv_det; v *= inv_det; } else // two sided { if (det > -F_APPROXIMATELY_ZERO && det < F_APPROXIMATELY_ZERO) { return FALSE; } F32 inv_det = 1.0 / det; /* calculate distance from vert0 to ray origin */ LLVector3 tvec = orig - vert0; /* calculate U parameter and test bounds */ u = (tvec * pvec) * inv_det; if (u < 0.f || u > 1.f) { return FALSE; } /* prepare to test V parameter */ LLVector3 qvec = tvec - edge1; /* calculate V parameter and test bounds */ v = (dir * qvec) * inv_det; if (v < 0.f || u + v > 1.f) { return FALSE; } /* calculate t, ray intersects triangle */ t = (edge2 * qvec) * inv_det; } if (intersection_a != NULL) *intersection_a = u; if (intersection_b != NULL) *intersection_b = v; if (intersection_t != NULL) *intersection_t = t; return TRUE; } //------------------------------------------------------------------- // statics //------------------------------------------------------------------- //---------------------------------------------------- LLProfile::Face* LLProfile::addCap(S16 faceID) { LLMemType m1(LLMemType::MTYPE_VOLUME); Face *face = vector_append(mFaces, 1); face->mIndex = 0; face->mCount = mTotal; face->mScaleU= 1.0f; face->mCap = TRUE; face->mFaceID = faceID; return face; } LLProfile::Face* LLProfile::addFace(S32 i, S32 count, F32 scaleU, S16 faceID, BOOL flat) { LLMemType m1(LLMemType::MTYPE_VOLUME); Face *face = vector_append(mFaces, 1); face->mIndex = i; face->mCount = count; face->mScaleU= scaleU; face->mFlat = flat; face->mCap = FALSE; face->mFaceID = faceID; return face; } // What is the bevel parameter used for? - DJS 04/05/02 // Bevel parameter is currently unused but presumedly would support // filleted and chamfered corners void LLProfile::genNGon(const LLProfileParams& params, S32 sides, F32 offset, F32 bevel, F32 ang_scale, S32 split) { LLMemType m1(LLMemType::MTYPE_VOLUME); // Generate an n-sided "circular" path. // 0 is (1,0), and we go counter-clockwise along a circular path from there. const F32 tableScale[] = { 1, 1, 1, 0.5f, 0.707107f, 0.53f, 0.525f, 0.5f }; F32 scale = 0.5f; F32 t, t_step, t_first, t_fraction, ang, ang_step; LLVector3 pt1,pt2; F32 begin = params.getBegin(); F32 end = params.getEnd(); t_step = 1.0f / sides; ang_step = 2.0f*F_PI*t_step*ang_scale; // Scale to have size "match" scale. Compensates to get object to generally fill bounding box. S32 total_sides = llround(sides / ang_scale); // Total number of sides all around if (total_sides < 8) { scale = tableScale[total_sides]; } t_first = floor(begin * sides) / (F32)sides; // pt1 is the first point on the fractional face. // Starting t and ang values for the first face t = t_first; ang = 2.0f*F_PI*(t*ang_scale + offset); pt1.setVec(cos(ang)*scale,sin(ang)*scale, t); // Increment to the next point. // pt2 is the end point on the fractional face t += t_step; ang += ang_step; pt2.setVec(cos(ang)*scale,sin(ang)*scale,t); t_fraction = (begin - t_first)*sides; // Only use if it's not almost exactly on an edge. if (t_fraction < 0.9999f) { LLVector3 new_pt = lerp(pt1, pt2, t_fraction); mProfile.push_back(new_pt); } // There's lots of potential here for floating point error to generate unneeded extra points - DJS 04/05/02 while (t < end) { // Iterate through all the integer steps of t. pt1.setVec(cos(ang)*scale,sin(ang)*scale,t); if (mProfile.size() > 0) { LLVector3 p = mProfile[mProfile.size()-1]; for (S32 i = 0; i < split && mProfile.size() > 0; i++) { mProfile.push_back(p+(pt1-p) * 1.0f/(float)(split+1) * (float)(i+1)); } } mProfile.push_back(pt1); t += t_step; ang += ang_step; } t_fraction = (end - (t - t_step))*sides; // pt1 is the first point on the fractional face // pt2 is the end point on the fractional face pt2.setVec(cos(ang)*scale,sin(ang)*scale,t); // Find the fraction that we need to add to the end point. t_fraction = (end - (t - t_step))*sides; if (t_fraction > 0.0001f) { LLVector3 new_pt = lerp(pt1, pt2, t_fraction); if (mProfile.size() > 0) { LLVector3 p = mProfile[mProfile.size()-1]; for (S32 i = 0; i < split && mProfile.size() > 0; i++) { mProfile.push_back(p+(new_pt-p) * 1.0f/(float)(split+1) * (float)(i+1)); } } mProfile.push_back(new_pt); } // If we're sliced, the profile is open. if ((end - begin)*ang_scale < 0.99f) { if ((end - begin)*ang_scale > 0.5f) { mConcave = TRUE; } else { mConcave = FALSE; } mOpen = TRUE; if (params.getHollow() <= 0) { // put center point if not hollow. mProfile.push_back(LLVector3(0,0,0)); } } else { // The profile isn't open. mOpen = FALSE; mConcave = FALSE; } mTotal = mProfile.size(); } void LLProfile::genNormals(const LLProfileParams& params) { S32 count = mProfile.size(); S32 outer_count; if (mTotalOut) { outer_count = mTotalOut; } else { outer_count = mTotal / 2; } mEdgeNormals.resize(count * 2); mEdgeCenters.resize(count * 2); mNormals.resize(count); LLVector2 pt0,pt1; BOOL hollow = (params.getHollow() > 0); S32 i0, i1, i2, i3, i4; // Parametrically generate normal for (i2 = 0; i2 < count; i2++) { mNormals[i2].mV[0] = mProfile[i2].mV[0]; mNormals[i2].mV[1] = mProfile[i2].mV[1]; if (hollow && (i2 >= outer_count)) { mNormals[i2] *= -1.f; } if (mNormals[i2].magVec() < 0.001) { // Special case for point at center, get adjacent points. i1 = (i2 - 1) >= 0 ? i2 - 1 : count - 1; i0 = (i1 - 1) >= 0 ? i1 - 1 : count - 1; i3 = (i2 + 1) < count ? i2 + 1 : 0; i4 = (i3 + 1) < count ? i3 + 1 : 0; pt0.setVec(mProfile[i1].mV[VX] + mProfile[i1].mV[VX] - mProfile[i0].mV[VX], mProfile[i1].mV[VY] + mProfile[i1].mV[VY] - mProfile[i0].mV[VY]); pt1.setVec(mProfile[i3].mV[VX] + mProfile[i3].mV[VX] - mProfile[i4].mV[VX], mProfile[i3].mV[VY] + mProfile[i3].mV[VY] - mProfile[i4].mV[VY]); mNormals[i2] = pt0 + pt1; mNormals[i2] *= 0.5f; } mNormals[i2].normVec(); } S32 num_normal_sets = isConcave() ? 2 : 1; for (S32 normal_set = 0; normal_set < num_normal_sets; normal_set++) { S32 point_num; for (point_num = 0; point_num < mTotal; point_num++) { LLVector3 point_1 = mProfile[point_num]; point_1.mV[VZ] = 0.f; LLVector3 point_2; if (isConcave() && normal_set == 0 && point_num == (mTotal - 1) / 2) { point_2 = mProfile[mTotal - 1]; } else if (isConcave() && normal_set == 1 && point_num == mTotal - 1) { point_2 = mProfile[(mTotal - 1) / 2]; } else { LLVector3 delta_pos; S32 neighbor_point = (point_num + 1) % mTotal; while(delta_pos.magVecSquared() < 0.01f * 0.01f) { point_2 = mProfile[neighbor_point]; delta_pos = point_2 - point_1; neighbor_point = (neighbor_point + 1) % mTotal; if (neighbor_point == point_num) { break; } } } point_2.mV[VZ] = 0.f; LLVector3 face_normal = (point_2 - point_1) % LLVector3::z_axis; face_normal.normVec(); mEdgeNormals[normal_set * count + point_num] = face_normal; mEdgeCenters[normal_set * count + point_num] = lerp(point_1, point_2, 0.5f); } } } // Hollow is percent of the original bounding box, not of this particular // profile's geometry. Thus, a swept triangle needs lower hollow values than // a swept square. LLProfile::Face* LLProfile::addHole(const LLProfileParams& params, BOOL flat, F32 sides, F32 offset, F32 box_hollow, F32 ang_scale, S32 split) { // Note that addHole will NOT work for non-"circular" profiles, if we ever decide to use them. // Total add has number of vertices on outside. mTotalOut = mTotal; // Why is the "bevel" parameter -1? DJS 04/05/02 genNGon(params, llfloor(sides),offset,-1, ang_scale, split); Face *face = addFace(mTotalOut, mTotal-mTotalOut,0,LL_FACE_INNER_SIDE, flat); std::vector pt; pt.resize(mTotal) ; for (S32 i=mTotalOut;i end - 0.01f) { llwarns << "LLProfile::generate() assertion failed (begin >= end)" << llendl; return FALSE; } S32 face_num = 0; switch (params.getCurveType() & LL_PCODE_PROFILE_MASK) { case LL_PCODE_PROFILE_SQUARE: { genNGon(params, 4,-0.375, 0, 1, split); if (path_open) { addCap (LL_FACE_PATH_BEGIN); } for (i = llfloor(begin * 4.f); i < llfloor(end * 4.f + .999f); i++) { addFace((face_num++) * (split +1), split+2, 1, LL_FACE_OUTER_SIDE_0 << i, TRUE); } for (i = 0; i <(S32) mProfile.size(); i++) { // Scale by 4 to generate proper tex coords. mProfile[i].mV[2] *= 4.f; } if (hollow) { switch (params.getCurveType() & LL_PCODE_HOLE_MASK) { case LL_PCODE_HOLE_TRIANGLE: // This offset is not correct, but we can't change it now... DK 11/17/04 addHole(params, TRUE, 3, -0.375f, hollow, 1.f, split); break; case LL_PCODE_HOLE_CIRCLE: // TODO: Compute actual detail levels for cubes addHole(params, FALSE, MIN_DETAIL_FACES * detail, -0.375f, hollow, 1.f); break; case LL_PCODE_HOLE_SAME: case LL_PCODE_HOLE_SQUARE: default: addHole(params, TRUE, 4, -0.375f, hollow, 1.f, split); break; } } if (path_open) { mFaces[0].mCount = mTotal; } } break; case LL_PCODE_PROFILE_ISOTRI: case LL_PCODE_PROFILE_RIGHTTRI: case LL_PCODE_PROFILE_EQUALTRI: { genNGon(params, 3,0, 0, 1, split); for (i = 0; i <(S32) mProfile.size(); i++) { // Scale by 3 to generate proper tex coords. mProfile[i].mV[2] *= 3.f; } if (path_open) { addCap(LL_FACE_PATH_BEGIN); } for (i = llfloor(begin * 3.f); i < llfloor(end * 3.f + .999f); i++) { addFace((face_num++) * (split +1), split+2, 1, LL_FACE_OUTER_SIDE_0 << i, TRUE); } if (hollow) { // Swept triangles need smaller hollowness values, // because the triangle doesn't fill the bounding box. F32 triangle_hollow = hollow / 2.f; switch (params.getCurveType() & LL_PCODE_HOLE_MASK) { case LL_PCODE_HOLE_CIRCLE: // TODO: Actually generate level of detail for triangles addHole(params, FALSE, MIN_DETAIL_FACES * detail, 0, triangle_hollow, 1.f); break; case LL_PCODE_HOLE_SQUARE: addHole(params, TRUE, 4, 0, triangle_hollow, 1.f, split); break; case LL_PCODE_HOLE_SAME: case LL_PCODE_HOLE_TRIANGLE: default: addHole(params, TRUE, 3, 0, triangle_hollow, 1.f, split); break; } } } break; case LL_PCODE_PROFILE_CIRCLE: { // If this has a square hollow, we should adjust the // number of faces a bit so that the geometry lines up. U8 hole_type=0; F32 circle_detail = MIN_DETAIL_FACES * detail; if (hollow) { hole_type = params.getCurveType() & LL_PCODE_HOLE_MASK; if (hole_type == LL_PCODE_HOLE_SQUARE) { // Snap to the next multiple of four sides, // so that corners line up. circle_detail = llceil(circle_detail / 4.0f) * 4.0f; } } S32 sides = (S32)circle_detail; if (is_sculpted) sides = sculpt_size; genNGon(params, sides); if (path_open) { addCap (LL_FACE_PATH_BEGIN); } if (mOpen && !hollow) { addFace(0,mTotal-1,0,LL_FACE_OUTER_SIDE_0, FALSE); } else { addFace(0,mTotal,0,LL_FACE_OUTER_SIDE_0, FALSE); } if (hollow) { switch (hole_type) { case LL_PCODE_HOLE_SQUARE: addHole(params, TRUE, 4, 0, hollow, 1.f, split); break; case LL_PCODE_HOLE_TRIANGLE: addHole(params, TRUE, 3, 0, hollow, 1.f, split); break; case LL_PCODE_HOLE_CIRCLE: case LL_PCODE_HOLE_SAME: default: addHole(params, FALSE, circle_detail, 0, hollow, 1.f); break; } } } break; case LL_PCODE_PROFILE_CIRCLE_HALF: { // If this has a square hollow, we should adjust the // number of faces a bit so that the geometry lines up. U8 hole_type=0; // Number of faces is cut in half because it's only a half-circle. F32 circle_detail = MIN_DETAIL_FACES * detail * 0.5f; if (hollow) { hole_type = params.getCurveType() & LL_PCODE_HOLE_MASK; if (hole_type == LL_PCODE_HOLE_SQUARE) { // Snap to the next multiple of four sides (div 2), // so that corners line up. circle_detail = llceil(circle_detail / 2.0f) * 2.0f; } } genNGon(params, llfloor(circle_detail), 0.5f, 0.f, 0.5f); if (path_open) { addCap(LL_FACE_PATH_BEGIN); } if (mOpen && !params.getHollow()) { addFace(0,mTotal-1,0,LL_FACE_OUTER_SIDE_0, FALSE); } else { addFace(0,mTotal,0,LL_FACE_OUTER_SIDE_0, FALSE); } if (hollow) { switch (hole_type) { case LL_PCODE_HOLE_SQUARE: addHole(params, TRUE, 2, 0.5f, hollow, 0.5f, split); break; case LL_PCODE_HOLE_TRIANGLE: addHole(params, TRUE, 3, 0.5f, hollow, 0.5f, split); break; case LL_PCODE_HOLE_CIRCLE: case LL_PCODE_HOLE_SAME: default: addHole(params, FALSE, circle_detail, 0.5f, hollow, 0.5f); break; } } // Special case for openness of sphere if ((params.getEnd() - params.getBegin()) < 1.f) { mOpen = TRUE; } else if (!hollow) { mOpen = FALSE; mProfile.push_back(mProfile[0]); mTotal++; } } break; default: llerrs << "Unknown profile: getCurveType()=" << params.getCurveType() << llendl; break; }; if (path_open) { addCap(LL_FACE_PATH_END); // bottom } if ( mOpen) // interior edge caps { addFace(mTotal-1, 2,0.5,LL_FACE_PROFILE_BEGIN, TRUE); if (hollow) { addFace(mTotalOut-1, 2,0.5,LL_FACE_PROFILE_END, TRUE); } else { addFace(mTotal-2, 2,0.5,LL_FACE_PROFILE_END, TRUE); } } //genNormals(params); return TRUE; } BOOL LLProfileParams::importFile(LLFILE *fp) { LLMemType m1(LLMemType::MTYPE_VOLUME); const S32 BUFSIZE = 16384; char buffer[BUFSIZE]; /* Flawfinder: ignore */ // *NOTE: changing the size or type of these buffers will require // changing the sscanf below. char keyword[256]; /* Flawfinder: ignore */ char valuestr[256]; /* Flawfinder: ignore */ keyword[0] = 0; valuestr[0] = 0; F32 tempF32; U32 tempU32; while (!feof(fp)) { if (fgets(buffer, BUFSIZE, fp) == NULL) { buffer[0] = '\0'; } sscanf( /* Flawfinder: ignore */ buffer, " %255s %255s", keyword, valuestr); if (!strcmp("{", keyword)) { continue; } if (!strcmp("}",keyword)) { break; } else if (!strcmp("curve", keyword)) { sscanf(valuestr,"%d",&tempU32); setCurveType((U8) tempU32); } else if (!strcmp("begin",keyword)) { sscanf(valuestr,"%g",&tempF32); setBegin(tempF32); } else if (!strcmp("end",keyword)) { sscanf(valuestr,"%g",&tempF32); setEnd(tempF32); } else if (!strcmp("hollow",keyword)) { sscanf(valuestr,"%g",&tempF32); setHollow(tempF32); } else { llwarns << "unknown keyword " << keyword << " in profile import" << llendl; } } return TRUE; } BOOL LLProfileParams::exportFile(LLFILE *fp) const { fprintf(fp,"\t\tprofile 0\n"); fprintf(fp,"\t\t{\n"); fprintf(fp,"\t\t\tcurve\t%d\n", getCurveType()); fprintf(fp,"\t\t\tbegin\t%g\n", getBegin()); fprintf(fp,"\t\t\tend\t%g\n", getEnd()); fprintf(fp,"\t\t\thollow\t%g\n", getHollow()); fprintf(fp, "\t\t}\n"); return TRUE; } BOOL LLProfileParams::importLegacyStream(std::istream& input_stream) { LLMemType m1(LLMemType::MTYPE_VOLUME); const S32 BUFSIZE = 16384; char buffer[BUFSIZE]; /* Flawfinder: ignore */ // *NOTE: changing the size or type of these buffers will require // changing the sscanf below. char keyword[256]; /* Flawfinder: ignore */ char valuestr[256]; /* Flawfinder: ignore */ keyword[0] = 0; valuestr[0] = 0; F32 tempF32; U32 tempU32; while (input_stream.good()) { input_stream.getline(buffer, BUFSIZE); sscanf( /* Flawfinder: ignore */ buffer, " %255s %255s", keyword, valuestr); if (!strcmp("{", keyword)) { continue; } if (!strcmp("}",keyword)) { break; } else if (!strcmp("curve", keyword)) { sscanf(valuestr,"%d",&tempU32); setCurveType((U8) tempU32); } else if (!strcmp("begin",keyword)) { sscanf(valuestr,"%g",&tempF32); setBegin(tempF32); } else if (!strcmp("end",keyword)) { sscanf(valuestr,"%g",&tempF32); setEnd(tempF32); } else if (!strcmp("hollow",keyword)) { sscanf(valuestr,"%g",&tempF32); setHollow(tempF32); } else { llwarns << "unknown keyword " << keyword << " in profile import" << llendl; } } return TRUE; } BOOL LLProfileParams::exportLegacyStream(std::ostream& output_stream) const { output_stream <<"\t\tprofile 0\n"; output_stream <<"\t\t{\n"; output_stream <<"\t\t\tcurve\t" << (S32) getCurveType() << "\n"; output_stream <<"\t\t\tbegin\t" << getBegin() << "\n"; output_stream <<"\t\t\tend\t" << getEnd() << "\n"; output_stream <<"\t\t\thollow\t" << getHollow() << "\n"; output_stream << "\t\t}\n"; return TRUE; } LLSD LLProfileParams::asLLSD() const { LLSD sd; sd["curve"] = getCurveType(); sd["begin"] = getBegin(); sd["end"] = getEnd(); sd["hollow"] = getHollow(); return sd; } bool LLProfileParams::fromLLSD(LLSD& sd) { setCurveType(sd["curve"].asInteger()); setBegin((F32)sd["begin"].asReal()); setEnd((F32)sd["end"].asReal()); setHollow((F32)sd["hollow"].asReal()); return true; } void LLProfileParams::copyParams(const LLProfileParams ¶ms) { LLMemType m1(LLMemType::MTYPE_VOLUME); setCurveType(params.getCurveType()); setBegin(params.getBegin()); setEnd(params.getEnd()); setHollow(params.getHollow()); } LLPath::~LLPath() { } void LLPath::genNGon(const LLPathParams& params, S32 sides, F32 startOff, F32 end_scale, F32 twist_scale) { // Generates a circular path, starting at (1, 0, 0), counterclockwise along the xz plane. const F32 tableScale[] = { 1, 1, 1, 0.5f, 0.707107f, 0.53f, 0.525f, 0.5f }; F32 revolutions = params.getRevolutions(); F32 skew = params.getSkew(); F32 skew_mag = fabs(skew); F32 hole_x = params.getScaleX() * (1.0f - skew_mag); F32 hole_y = params.getScaleY(); // Calculate taper begin/end for x,y (Negative means taper the beginning) F32 taper_x_begin = 1.0f; F32 taper_x_end = 1.0f - params.getTaperX(); F32 taper_y_begin = 1.0f; F32 taper_y_end = 1.0f - params.getTaperY(); if ( taper_x_end > 1.0f ) { // Flip tapering. taper_x_begin = 2.0f - taper_x_end; taper_x_end = 1.0f; } if ( taper_y_end > 1.0f ) { // Flip tapering. taper_y_begin = 2.0f - taper_y_end; taper_y_end = 1.0f; } // For spheres, the radius is usually zero. F32 radius_start = 0.5f; if (sides < 8) { radius_start = tableScale[sides]; } // Scale the radius to take the hole size into account. radius_start *= 1.0f - hole_y; // Now check the radius offset to calculate the start,end radius. (Negative means // decrease the start radius instead). F32 radius_end = radius_start; F32 radius_offset = params.getRadiusOffset(); if (radius_offset < 0.f) { radius_start *= 1.f + radius_offset; } else { radius_end *= 1.f - radius_offset; } // Is the path NOT a closed loop? mOpen = ( (params.getEnd()*end_scale - params.getBegin() < 1.0f) || (skew_mag > 0.001f) || (fabs(taper_x_end - taper_x_begin) > 0.001f) || (fabs(taper_y_end - taper_y_begin) > 0.001f) || (fabs(radius_end - radius_start) > 0.001f) ); F32 ang, c, s; LLQuaternion twist, qang; PathPt *pt; LLVector3 path_axis (1.f, 0.f, 0.f); //LLVector3 twist_axis(0.f, 0.f, 1.f); F32 twist_begin = params.getTwistBegin() * twist_scale; F32 twist_end = params.getTwist() * twist_scale; // We run through this once before the main loop, to make sure // the path begins at the correct cut. F32 step= 1.0f / sides; F32 t = params.getBegin(); pt = vector_append(mPath, 1); ang = 2.0f*F_PI*revolutions * t; s = sin(ang)*lerp(radius_start, radius_end, t); c = cos(ang)*lerp(radius_start, radius_end, t); pt->mPos.setVec(0 + lerp(0,params.getShear().mV[0],s) + lerp(-skew ,skew, t) * 0.5f, c + lerp(0,params.getShear().mV[1],s), s); pt->mScale.mV[VX] = hole_x * lerp(taper_x_begin, taper_x_end, t); pt->mScale.mV[VY] = hole_y * lerp(taper_y_begin, taper_y_end, t); pt->mTexT = t; // Twist rotates the path along the x,y plane (I think) - DJS 04/05/02 twist.setQuat (lerp(twist_begin,twist_end,t) * 2.f * F_PI - F_PI,0,0,1); // Rotate the point around the circle's center. qang.setQuat (ang,path_axis); pt->mRot = twist * qang; t+=step; // Snap to a quantized parameter, so that cut does not // affect most sample points. t = ((S32)(t * sides)) / (F32)sides; // Run through the non-cut dependent points. while (t < params.getEnd()) { pt = vector_append(mPath, 1); ang = 2.0f*F_PI*revolutions * t; c = cos(ang)*lerp(radius_start, radius_end, t); s = sin(ang)*lerp(radius_start, radius_end, t); pt->mPos.setVec(0 + lerp(0,params.getShear().mV[0],s) + lerp(-skew ,skew, t) * 0.5f, c + lerp(0,params.getShear().mV[1],s), s); pt->mScale.mV[VX] = hole_x * lerp(taper_x_begin, taper_x_end, t); pt->mScale.mV[VY] = hole_y * lerp(taper_y_begin, taper_y_end, t); pt->mTexT = t; // Twist rotates the path along the x,y plane (I think) - DJS 04/05/02 twist.setQuat (lerp(twist_begin,twist_end,t) * 2.f * F_PI - F_PI,0,0,1); // Rotate the point around the circle's center. qang.setQuat (ang,path_axis); pt->mRot = twist * qang; t+=step; } // Make one final pass for the end cut. t = params.getEnd(); pt = vector_append(mPath, 1); ang = 2.0f*F_PI*revolutions * t; c = cos(ang)*lerp(radius_start, radius_end, t); s = sin(ang)*lerp(radius_start, radius_end, t); pt->mPos.setVec(0 + lerp(0,params.getShear().mV[0],s) + lerp(-skew ,skew, t) * 0.5f, c + lerp(0,params.getShear().mV[1],s), s); pt->mScale.mV[VX] = hole_x * lerp(taper_x_begin, taper_x_end, t); pt->mScale.mV[VY] = hole_y * lerp(taper_y_begin, taper_y_end, t); pt->mTexT = t; // Twist rotates the path along the x,y plane (I think) - DJS 04/05/02 twist.setQuat (lerp(twist_begin,twist_end,t) * 2.f * F_PI - F_PI,0,0,1); // Rotate the point around the circle's center. qang.setQuat (ang,path_axis); pt->mRot = twist * qang; mTotal = mPath.size(); } const LLVector2 LLPathParams::getBeginScale() const { LLVector2 begin_scale(1.f, 1.f); if (getScaleX() > 1) { begin_scale.mV[0] = 2-getScaleX(); } if (getScaleY() > 1) { begin_scale.mV[1] = 2-getScaleY(); } return begin_scale; } const LLVector2 LLPathParams::getEndScale() const { LLVector2 end_scale(1.f, 1.f); if (getScaleX() < 1) { end_scale.mV[0] = getScaleX(); } if (getScaleY() < 1) { end_scale.mV[1] = getScaleY(); } return end_scale; } BOOL LLPath::generate(const LLPathParams& params, F32 detail, S32 split, BOOL is_sculpted, S32 sculpt_size) { LLMemType m1(LLMemType::MTYPE_VOLUME); if ((!mDirty) && (!is_sculpted)) { return FALSE; } if (detail < MIN_LOD) { llinfos << "Generating path with LOD < MIN! Clamping to 1" << llendl; detail = MIN_LOD; } mDirty = FALSE; S32 np = 2; // hardcode for line mPath.clear(); mOpen = TRUE; // Is this 0xf0 mask really necessary? DK 03/02/05 switch (params.getCurveType() & 0xf0) { default: case LL_PCODE_PATH_LINE: { // Take the begin/end twist into account for detail. np = llfloor(fabs(params.getTwistBegin() - params.getTwist()) * 3.5f * (detail-0.5f)) + 2; if (np < split+2) { np = split+2; } mStep = 1.0f / (np-1); mPath.resize(np); LLVector2 start_scale = params.getBeginScale(); LLVector2 end_scale = params.getEndScale(); for (S32 i=0;i= 0.99f && params.getScaleX() >= .99f) { mOpen = FALSE; } //genNGon(params, llfloor(MIN_DETAIL_FACES * detail), 4.f, 0.f); genNGon(params, llfloor(MIN_DETAIL_FACES * detail)); F32 t = 0.f; F32 tStep = 1.0f / mPath.size(); F32 toggle = 0.5f; for (S32 i=0;i<(S32)mPath.size();i++) { mPath[i].mPos.mV[0] = toggle; if (toggle == 0.5f) toggle = -0.5f; else toggle = 0.5f; t += tStep; } } break; case LL_PCODE_PATH_TEST: np = 5; mStep = 1.0f / (np-1); mPath.resize(np); for (S32 i=0;iresizePath(length); mVolumeFaces.clear(); } void LLVolume::regen() { generate(); createVolumeFaces(); } void LLVolume::genBinormals(S32 face) { mVolumeFaces[face].createBinormals(); } LLVolume::~LLVolume() { sNumMeshPoints -= mMesh.size(); delete mPathp; profile_delete_lock = 0 ; delete mProfilep; profile_delete_lock = 1 ; mPathp = NULL; mProfilep = NULL; mVolumeFaces.clear(); } BOOL LLVolume::generate() { LLMemType m1(LLMemType::MTYPE_VOLUME); llassert_always(mProfilep); //Added 10.03.05 Dave Parks // Split is a parameter to LLProfile::generate that tesselates edges on the profile // to prevent lighting and texture interpolation errors on triangles that are // stretched due to twisting or scaling on the path. S32 split = (S32) ((mDetail)*0.66f); if (mParams.getPathParams().getCurveType() == LL_PCODE_PATH_LINE && (mParams.getPathParams().getScale().mV[0] != 1.0f || mParams.getPathParams().getScale().mV[1] != 1.0f) && (mParams.getProfileParams().getCurveType() == LL_PCODE_PROFILE_SQUARE || mParams.getProfileParams().getCurveType() == LL_PCODE_PROFILE_ISOTRI || mParams.getProfileParams().getCurveType() == LL_PCODE_PROFILE_EQUALTRI || mParams.getProfileParams().getCurveType() == LL_PCODE_PROFILE_RIGHTTRI)) { split = 0; } mLODScaleBias.setVec(0.5f, 0.5f, 0.5f); F32 profile_detail = mDetail; F32 path_detail = mDetail; U8 path_type = mParams.getPathParams().getCurveType(); U8 profile_type = mParams.getProfileParams().getCurveType(); if (path_type == LL_PCODE_PATH_LINE && profile_type == LL_PCODE_PROFILE_CIRCLE) { //cylinders don't care about Z-Axis mLODScaleBias.setVec(0.6f, 0.6f, 0.0f); } else if (path_type == LL_PCODE_PATH_CIRCLE) { mLODScaleBias.setVec(0.6f, 0.6f, 0.6f); } //******************************************************************** //debug info, to be removed if((U32)(mPathp->mPath.size() * mProfilep->mProfile.size()) > (1u << 20)) { llinfos << "sizeS: " << mPathp->mPath.size() << " sizeT: " << mProfilep->mProfile.size() << llendl ; llinfos << "path_detail : " << path_detail << " split: " << split << " profile_detail: " << profile_detail << llendl ; llinfos << mParams << llendl ; llinfos << "more info to check if mProfilep is deleted or not." << llendl ; llinfos << mProfilep->mNormals.size() << " : " << mProfilep->mFaces.size() << " : " << mProfilep->mEdgeNormals.size() << " : " << mProfilep->mEdgeCenters.size() << llendl ; llerrs << "LLVolume corrupted!" << llendl ; } //******************************************************************** BOOL regenPath = mPathp->generate(mParams.getPathParams(), path_detail, split); BOOL regenProf = mProfilep->generate(mParams.getProfileParams(), mPathp->isOpen(),profile_detail, split); if (regenPath || regenProf ) { S32 sizeS = mPathp->mPath.size(); S32 sizeT = mProfilep->mProfile.size(); //******************************************************************** //debug info, to be removed if((U32)(sizeS * sizeT) > (1u << 20)) { llinfos << "regenPath: " << (S32)regenPath << " regenProf: " << (S32)regenProf << llendl ; llinfos << "sizeS: " << sizeS << " sizeT: " << sizeT << llendl ; llinfos << "path_detail : " << path_detail << " split: " << split << " profile_detail: " << profile_detail << llendl ; llinfos << mParams << llendl ; llinfos << "more info to check if mProfilep is deleted or not." << llendl ; llinfos << mProfilep->mNormals.size() << " : " << mProfilep->mFaces.size() << " : " << mProfilep->mEdgeNormals.size() << " : " << mProfilep->mEdgeCenters.size() << llendl ; llerrs << "LLVolume corrupted!" << llendl ; } //******************************************************************** sNumMeshPoints -= mMesh.size(); mMesh.resize(sizeT * sizeS); sNumMeshPoints += mMesh.size(); //generate vertex positions // Run along the path. for (S32 s = 0; s < sizeS; ++s) { LLVector2 scale = mPathp->mPath[s].mScale; LLQuaternion rot = mPathp->mPath[s].mRot; // Run along the profile. for (S32 t = 0; t < sizeT; ++t) { S32 m = s*sizeT + t; Point& pt = mMesh[m]; pt.mPos.mV[0] = mProfilep->mProfile[t].mV[0] * scale.mV[0]; pt.mPos.mV[1] = mProfilep->mProfile[t].mV[1] * scale.mV[1]; pt.mPos.mV[2] = 0.0f; pt.mPos = pt.mPos * rot; pt.mPos += mPathp->mPath[s].mPos; } } for (std::vector::iterator iter = mProfilep->mFaces.begin(); iter != mProfilep->mFaces.end(); ++iter) { LLFaceID id = iter->mFaceID; mFaceMask |= id; } return TRUE; } return FALSE; } void LLVolume::createVolumeFaces() { LLMemType m1(LLMemType::MTYPE_VOLUME); if (mGenerateSingleFace) { // do nothing } else { S32 num_faces = getNumFaces(); BOOL partial_build = TRUE; if (num_faces != mVolumeFaces.size()) { partial_build = FALSE; mVolumeFaces.resize(num_faces); } // Initialize volume faces with parameter data for (S32 i = 0; i < (S32)mVolumeFaces.size(); i++) { LLVolumeFace& vf = mVolumeFaces[i]; LLProfile::Face& face = mProfilep->mFaces[i]; vf.mBeginS = face.mIndex; vf.mNumS = face.mCount; vf.mBeginT = 0; vf.mNumT= getPath().mPath.size(); vf.mID = i; // Set the type mask bits correctly if (mParams.getProfileParams().getHollow() > 0) { vf.mTypeMask |= LLVolumeFace::HOLLOW_MASK; } if (mProfilep->isOpen()) { vf.mTypeMask |= LLVolumeFace::OPEN_MASK; } if (face.mCap) { vf.mTypeMask |= LLVolumeFace::CAP_MASK; if (face.mFaceID == LL_FACE_PATH_BEGIN) { vf.mTypeMask |= LLVolumeFace::TOP_MASK; } else { llassert(face.mFaceID == LL_FACE_PATH_END); vf.mTypeMask |= LLVolumeFace::BOTTOM_MASK; } } else if (face.mFaceID & (LL_FACE_PROFILE_BEGIN | LL_FACE_PROFILE_END)) { vf.mTypeMask |= LLVolumeFace::FLAT_MASK | LLVolumeFace::END_MASK; } else { vf.mTypeMask |= LLVolumeFace::SIDE_MASK; if (face.mFlat) { vf.mTypeMask |= LLVolumeFace::FLAT_MASK; } if (face.mFaceID & LL_FACE_INNER_SIDE) { vf.mTypeMask |= LLVolumeFace::INNER_MASK; if (face.mFlat && vf.mNumS > 2) { //flat inner faces have to copy vert normals vf.mNumS = vf.mNumS*2; } } else { vf.mTypeMask |= LLVolumeFace::OUTER_MASK; } } } for (face_list_t::iterator iter = mVolumeFaces.begin(); iter != mVolumeFaces.end(); ++iter) { (*iter).create(this, partial_build); } } } inline LLVector3 sculpt_rgb_to_vector(U8 r, U8 g, U8 b) { // maps RGB values to vector values [0..255] -> [-0.5..0.5] LLVector3 value; value.mV[VX] = r / 255.f - 0.5f; value.mV[VY] = g / 255.f - 0.5f; value.mV[VZ] = b / 255.f - 0.5f; return value; } inline U32 sculpt_xy_to_index(U32 x, U32 y, U16 sculpt_width, U16 sculpt_height, S8 sculpt_components) { U32 index = (x + y * sculpt_width) * sculpt_components; return index; } inline U32 sculpt_st_to_index(S32 s, S32 t, S32 size_s, S32 size_t, U16 sculpt_width, U16 sculpt_height, S8 sculpt_components) { U32 x = (U32) ((F32)s/(size_s) * (F32) sculpt_width); U32 y = (U32) ((F32)t/(size_t) * (F32) sculpt_height); return sculpt_xy_to_index(x, y, sculpt_width, sculpt_height, sculpt_components); } inline LLVector3 sculpt_index_to_vector(U32 index, const U8* sculpt_data) { LLVector3 v = sculpt_rgb_to_vector(sculpt_data[index], sculpt_data[index+1], sculpt_data[index+2]); return v; } inline LLVector3 sculpt_st_to_vector(S32 s, S32 t, S32 size_s, S32 size_t, U16 sculpt_width, U16 sculpt_height, S8 sculpt_components, const U8* sculpt_data) { U32 index = sculpt_st_to_index(s, t, size_s, size_t, sculpt_width, sculpt_height, sculpt_components); return sculpt_index_to_vector(index, sculpt_data); } inline LLVector3 sculpt_xy_to_vector(U32 x, U32 y, U16 sculpt_width, U16 sculpt_height, S8 sculpt_components, const U8* sculpt_data) { U32 index = sculpt_xy_to_index(x, y, sculpt_width, sculpt_height, sculpt_components); return sculpt_index_to_vector(index, sculpt_data); } F32 LLVolume::sculptGetSurfaceArea() { // test to see if image has enough variation to create non-degenerate geometry F32 area = 0; S32 sizeS = mPathp->mPath.size(); S32 sizeT = mProfilep->mProfile.size(); for (S32 s = 0; s < sizeS-1; s++) { for (S32 t = 0; t < sizeT-1; t++) { // get four corners of quad LLVector3 p1 = mMesh[(s )*sizeT + (t )].mPos; LLVector3 p2 = mMesh[(s+1)*sizeT + (t )].mPos; LLVector3 p3 = mMesh[(s )*sizeT + (t+1)].mPos; LLVector3 p4 = mMesh[(s+1)*sizeT + (t+1)].mPos; // compute the area of the quad by taking the length of the cross product of the two triangles LLVector3 cross1 = (p1 - p2) % (p1 - p3); LLVector3 cross2 = (p4 - p2) % (p4 - p3); area += (cross1.magVec() + cross2.magVec()) / 2.0; } } return area; } // create placeholder shape void LLVolume::sculptGeneratePlaceholder() { LLMemType m1(LLMemType::MTYPE_VOLUME); S32 sizeS = mPathp->mPath.size(); S32 sizeT = mProfilep->mProfile.size(); S32 line = 0; // for now, this is a sphere. for (S32 s = 0; s < sizeS; s++) { for (S32 t = 0; t < sizeT; t++) { S32 i = t + line; Point& pt = mMesh[i]; F32 u = (F32)s/(sizeS-1); F32 v = (F32)t/(sizeT-1); const F32 RADIUS = (F32) 0.3; pt.mPos.mV[0] = (F32)(sin(F_PI * v) * cos(2.0 * F_PI * u) * RADIUS); pt.mPos.mV[1] = (F32)(sin(F_PI * v) * sin(2.0 * F_PI * u) * RADIUS); pt.mPos.mV[2] = (F32)(cos(F_PI * v) * RADIUS); } line += sizeT; } } // create the vertices from the map void LLVolume::sculptGenerateMapVertices(U16 sculpt_width, U16 sculpt_height, S8 sculpt_components, const U8* sculpt_data, U8 sculpt_type) { U8 sculpt_stitching = sculpt_type & LL_SCULPT_TYPE_MASK; BOOL sculpt_invert = sculpt_type & LL_SCULPT_FLAG_INVERT; BOOL sculpt_mirror = sculpt_type & LL_SCULPT_FLAG_MIRROR; BOOL reverse_horizontal = (sculpt_invert ? !sculpt_mirror : sculpt_mirror); // XOR LLMemType m1(LLMemType::MTYPE_VOLUME); S32 sizeS = mPathp->mPath.size(); S32 sizeT = mProfilep->mProfile.size(); S32 line = 0; for (S32 s = 0; s < sizeS; s++) { // Run along the profile. for (S32 t = 0; t < sizeT; t++) { S32 i = t + line; Point& pt = mMesh[i]; S32 reversed_t = t; if (reverse_horizontal) { reversed_t = sizeT - t - 1; } U32 x = (U32) ((F32)reversed_t/(sizeT-1) * (F32) sculpt_width); U32 y = (U32) ((F32)s/(sizeS-1) * (F32) sculpt_height); if (y == 0) // top row stitching { // pinch? if (sculpt_stitching == LL_SCULPT_TYPE_SPHERE) { x = sculpt_width / 2; } } if (y == sculpt_height) // bottom row stitching { // wrap? if (sculpt_stitching == LL_SCULPT_TYPE_TORUS) { y = 0; } else { y = sculpt_height - 1; } // pinch? if (sculpt_stitching == LL_SCULPT_TYPE_SPHERE) { x = sculpt_width / 2; } } if (x == sculpt_width) // side stitching { // wrap? if ((sculpt_stitching == LL_SCULPT_TYPE_SPHERE) || (sculpt_stitching == LL_SCULPT_TYPE_TORUS) || (sculpt_stitching == LL_SCULPT_TYPE_CYLINDER)) { x = 0; } else { x = sculpt_width - 1; } } pt.mPos = sculpt_xy_to_vector(x, y, sculpt_width, sculpt_height, sculpt_components, sculpt_data); if (sculpt_mirror) { pt.mPos.mV[VX] *= -1.f; } } line += sizeT; } } const S32 SCULPT_REZ_1 = 6; // changed from 4 to 6 - 6 looks round whereas 4 looks square const S32 SCULPT_REZ_2 = 8; const S32 SCULPT_REZ_3 = 16; const S32 SCULPT_REZ_4 = 32; S32 sculpt_sides(F32 detail) { // detail is usually one of: 1, 1.5, 2.5, 4.0. if (detail <= 1.0) { return SCULPT_REZ_1; } if (detail <= 2.0) { return SCULPT_REZ_2; } if (detail <= 3.0) { return SCULPT_REZ_3; } else { return SCULPT_REZ_4; } } // determine the number of vertices in both s and t direction for this sculpt void sculpt_calc_mesh_resolution(U16 width, U16 height, U8 type, F32 detail, S32& s, S32& t) { // this code has the following properties: // 1) the aspect ratio of the mesh is as close as possible to the ratio of the map // while still using all available verts // 2) the mesh cannot have more verts than is allowed by LOD // 3) the mesh cannot have more verts than is allowed by the map S32 max_vertices_lod = (S32)pow((double)sculpt_sides(detail), 2.0); S32 max_vertices_map = width * height / 4; S32 vertices; if (max_vertices_map > 0) vertices = llmin(max_vertices_lod, max_vertices_map); else vertices = max_vertices_lod; F32 ratio; if ((width == 0) || (height == 0)) ratio = 1.f; else ratio = (F32) width / (F32) height; s = (S32)fsqrtf(((F32)vertices / ratio)); s = llmax(s, 4); // no degenerate sizes, please t = vertices / s; t = llmax(t, 4); // no degenerate sizes, please s = vertices / t; } // sculpt replaces generate() for sculpted surfaces void LLVolume::sculpt(U16 sculpt_width, U16 sculpt_height, S8 sculpt_components, const U8* sculpt_data, S32 sculpt_level) { LLMemType m1(LLMemType::MTYPE_VOLUME); U8 sculpt_type = mParams.getSculptType(); BOOL data_is_empty = FALSE; if (sculpt_width == 0 || sculpt_height == 0 || sculpt_components < 3 || sculpt_data == NULL) { sculpt_level = -1; data_is_empty = TRUE; } S32 requested_sizeS = 0; S32 requested_sizeT = 0; // create oblong sculpties with high LOD always F32 sculpt_detail = mDetail; if (sculpt_width != sculpt_height && sculpt_detail < 4.0) { sculpt_detail = 4.0; } sculpt_calc_mesh_resolution(sculpt_width, sculpt_height, sculpt_type, sculpt_detail, requested_sizeS, requested_sizeT); mPathp->generate(mParams.getPathParams(), sculpt_detail, 0, TRUE, requested_sizeS); mProfilep->generate(mParams.getProfileParams(), mPathp->isOpen(), sculpt_detail, 0, TRUE, requested_sizeT); S32 sizeS = mPathp->mPath.size(); // we requested a specific size, now see what we really got S32 sizeT = mProfilep->mProfile.size(); // we requested a specific size, now see what we really got // weird crash bug - DEV-11158 - trying to collect more data: if ((sizeS == 0) || (sizeT == 0)) { llwarns << "sculpt bad mesh size " << sizeS << " " << sizeT << llendl; } sNumMeshPoints -= mMesh.size(); mMesh.resize(sizeS * sizeT); sNumMeshPoints += mMesh.size(); //generate vertex positions if (!data_is_empty) { sculptGenerateMapVertices(sculpt_width, sculpt_height, sculpt_components, sculpt_data, sculpt_type); if (sculptGetSurfaceArea() < SCULPT_MIN_AREA) { data_is_empty = TRUE; } } if (data_is_empty) { sculptGeneratePlaceholder(); } for (S32 i = 0; i < (S32)mProfilep->mFaces.size(); i++) { mFaceMask |= mProfilep->mFaces[i].mFaceID; } mSculptLevel = sculpt_level; // Delete any existing faces so that they get regenerated mVolumeFaces.clear(); createVolumeFaces(); } BOOL LLVolume::isCap(S32 face) { return mProfilep->mFaces[face].mCap; } BOOL LLVolume::isFlat(S32 face) { return mProfilep->mFaces[face].mFlat; } bool LLVolumeParams::operator==(const LLVolumeParams ¶ms) const { return ( (getPathParams() == params.getPathParams()) && (getProfileParams() == params.getProfileParams()) && (mSculptID == params.mSculptID) && (mSculptType == params.mSculptType) ); } bool LLVolumeParams::operator!=(const LLVolumeParams ¶ms) const { return ( (getPathParams() != params.getPathParams()) || (getProfileParams() != params.getProfileParams()) || (mSculptID != params.mSculptID) || (mSculptType != params.mSculptType) ); } bool LLVolumeParams::operator<(const LLVolumeParams ¶ms) const { if( getPathParams() != params.getPathParams() ) { return getPathParams() < params.getPathParams(); } if (getProfileParams() != params.getProfileParams()) { return getProfileParams() < params.getProfileParams(); } if (mSculptID != params.mSculptID) { return mSculptID < params.mSculptID; } return mSculptType < params.mSculptType; } void LLVolumeParams::copyParams(const LLVolumeParams ¶ms) { LLMemType m1(LLMemType::MTYPE_VOLUME); mProfileParams.copyParams(params.mProfileParams); mPathParams.copyParams(params.mPathParams); mSculptID = params.getSculptID(); mSculptType = params.getSculptType(); } // Less restricitve approx 0 for volumes const F32 APPROXIMATELY_ZERO = 0.001f; bool approx_zero( F32 f, F32 tolerance = APPROXIMATELY_ZERO) { return (f >= -tolerance) && (f <= tolerance); } // return true if in range (or nearly so) static bool limit_range(F32& v, F32 min, F32 max, F32 tolerance = APPROXIMATELY_ZERO) { F32 min_delta = v - min; if (min_delta < 0.f) { v = min; if (!approx_zero(min_delta, tolerance)) return false; } F32 max_delta = max - v; if (max_delta < 0.f) { v = max; if (!approx_zero(max_delta, tolerance)) return false; } return true; } bool LLVolumeParams::setBeginAndEndS(const F32 b, const F32 e) { bool valid = true; // First, clamp to valid ranges. F32 begin = b; valid &= limit_range(begin, 0.f, 1.f - MIN_CUT_DELTA); F32 end = e; if (end >= .0149f && end < MIN_CUT_DELTA) end = MIN_CUT_DELTA; // eliminate warning for common rounding error valid &= limit_range(end, MIN_CUT_DELTA, 1.f); valid &= limit_range(begin, 0.f, end - MIN_CUT_DELTA, .01f); // Now set them. mProfileParams.setBegin(begin); mProfileParams.setEnd(end); return valid; } bool LLVolumeParams::setBeginAndEndT(const F32 b, const F32 e) { bool valid = true; // First, clamp to valid ranges. F32 begin = b; valid &= limit_range(begin, 0.f, 1.f - MIN_CUT_DELTA); F32 end = e; valid &= limit_range(end, MIN_CUT_DELTA, 1.f); valid &= limit_range(begin, 0.f, end - MIN_CUT_DELTA, .01f); // Now set them. mPathParams.setBegin(begin); mPathParams.setEnd(end); return valid; } bool LLVolumeParams::setHollow(const F32 h) { // Validate the hollow based on path and profile. U8 profile = mProfileParams.getCurveType() & LL_PCODE_PROFILE_MASK; U8 hole_type = mProfileParams.getCurveType() & LL_PCODE_HOLE_MASK; F32 max_hollow = HOLLOW_MAX; // Only square holes have trouble. if (LL_PCODE_HOLE_SQUARE == hole_type) { switch(profile) { case LL_PCODE_PROFILE_CIRCLE: case LL_PCODE_PROFILE_CIRCLE_HALF: case LL_PCODE_PROFILE_EQUALTRI: max_hollow = HOLLOW_MAX_SQUARE; } } F32 hollow = h; bool valid = limit_range(hollow, HOLLOW_MIN, max_hollow); mProfileParams.setHollow(hollow); return valid; } bool LLVolumeParams::setTwistBegin(const F32 b) { F32 twist_begin = b; bool valid = limit_range(twist_begin, TWIST_MIN, TWIST_MAX); mPathParams.setTwistBegin(twist_begin); return valid; } bool LLVolumeParams::setTwistEnd(const F32 e) { F32 twist_end = e; bool valid = limit_range(twist_end, TWIST_MIN, TWIST_MAX); mPathParams.setTwistEnd(twist_end); return valid; } bool LLVolumeParams::setRatio(const F32 x, const F32 y) { F32 min_x = RATIO_MIN; F32 max_x = RATIO_MAX; F32 min_y = RATIO_MIN; F32 max_y = RATIO_MAX; // If this is a circular path (and not a sphere) then 'ratio' is actually hole size. U8 path_type = mPathParams.getCurveType(); U8 profile_type = mProfileParams.getCurveType() & LL_PCODE_PROFILE_MASK; if ( LL_PCODE_PATH_CIRCLE == path_type && LL_PCODE_PROFILE_CIRCLE_HALF != profile_type) { // Holes are more restricted... min_x = HOLE_X_MIN; max_x = HOLE_X_MAX; min_y = HOLE_Y_MIN; max_y = HOLE_Y_MAX; } F32 ratio_x = x; bool valid = limit_range(ratio_x, min_x, max_x); F32 ratio_y = y; valid &= limit_range(ratio_y, min_y, max_y); mPathParams.setScale(ratio_x, ratio_y); return valid; } bool LLVolumeParams::setShear(const F32 x, const F32 y) { F32 shear_x = x; bool valid = limit_range(shear_x, SHEAR_MIN, SHEAR_MAX); F32 shear_y = y; valid &= limit_range(shear_y, SHEAR_MIN, SHEAR_MAX); mPathParams.setShear(shear_x, shear_y); return valid; } bool LLVolumeParams::setTaperX(const F32 v) { F32 taper = v; bool valid = limit_range(taper, TAPER_MIN, TAPER_MAX); mPathParams.setTaperX(taper); return valid; } bool LLVolumeParams::setTaperY(const F32 v) { F32 taper = v; bool valid = limit_range(taper, TAPER_MIN, TAPER_MAX); mPathParams.setTaperY(taper); return valid; } bool LLVolumeParams::setRevolutions(const F32 r) { F32 revolutions = r; bool valid = limit_range(revolutions, REV_MIN, REV_MAX); mPathParams.setRevolutions(revolutions); return valid; } bool LLVolumeParams::setRadiusOffset(const F32 offset) { bool valid = true; // If this is a sphere, just set it to 0 and get out. U8 path_type = mPathParams.getCurveType(); U8 profile_type = mProfileParams.getCurveType() & LL_PCODE_PROFILE_MASK; if ( LL_PCODE_PROFILE_CIRCLE_HALF == profile_type || LL_PCODE_PATH_CIRCLE != path_type ) { mPathParams.setRadiusOffset(0.f); return true; } // Limit radius offset, based on taper and hole size y. F32 radius_offset = offset; F32 taper_y = getTaperY(); F32 radius_mag = fabs(radius_offset); F32 hole_y_mag = fabs(getRatioY()); F32 taper_y_mag = fabs(taper_y); // Check to see if the taper effects us. if ( (radius_offset > 0.f && taper_y < 0.f) || (radius_offset < 0.f && taper_y > 0.f) ) { // The taper does not help increase the radius offset range. taper_y_mag = 0.f; } F32 max_radius_mag = 1.f - hole_y_mag * (1.f - taper_y_mag) / (1.f - hole_y_mag); // Enforce the maximum magnitude. F32 delta = max_radius_mag - radius_mag; if (delta < 0.f) { // Check radius offset sign. if (radius_offset < 0.f) { radius_offset = -max_radius_mag; } else { radius_offset = max_radius_mag; } valid = approx_zero(delta, .1f); } mPathParams.setRadiusOffset(radius_offset); return valid; } bool LLVolumeParams::setSkew(const F32 skew_value) { bool valid = true; // Check the skew value against the revolutions. F32 skew = llclamp(skew_value, SKEW_MIN, SKEW_MAX); F32 skew_mag = fabs(skew); F32 revolutions = getRevolutions(); F32 scale_x = getRatioX(); F32 min_skew_mag = 1.0f - 1.0f / (revolutions * scale_x + 1.0f); // Discontinuity; A revolution of 1 allows skews below 0.5. if ( fabs(revolutions - 1.0f) < 0.001) min_skew_mag = 0.0f; // Clip skew. F32 delta = skew_mag - min_skew_mag; if (delta < 0.f) { // Check skew sign. if (skew < 0.0f) { skew = -min_skew_mag; } else { skew = min_skew_mag; } valid = approx_zero(delta, .01f); } mPathParams.setSkew(skew); return valid; } bool LLVolumeParams::setSculptID(const LLUUID sculpt_id, U8 sculpt_type) { mSculptID = sculpt_id; mSculptType = sculpt_type; return true; } bool LLVolumeParams::setType(U8 profile, U8 path) { bool result = true; // First, check profile and path for validity. U8 profile_type = profile & LL_PCODE_PROFILE_MASK; U8 hole_type = (profile & LL_PCODE_HOLE_MASK) >> 4; U8 path_type = path >> 4; if (profile_type > LL_PCODE_PROFILE_MAX) { // Bad profile. Make it square. profile = LL_PCODE_PROFILE_SQUARE; result = false; llwarns << "LLVolumeParams::setType changing bad profile type (" << profile_type << ") to be LL_PCODE_PROFILE_SQUARE" << llendl; } else if (hole_type > LL_PCODE_HOLE_MAX) { // Bad hole. Make it the same. profile = profile_type; result = false; llwarns << "LLVolumeParams::setType changing bad hole type (" << hole_type << ") to be LL_PCODE_HOLE_SAME" << llendl; } if (path_type < LL_PCODE_PATH_MIN || path_type > LL_PCODE_PATH_MAX) { // Bad path. Make it linear. result = false; llwarns << "LLVolumeParams::setType changing bad path (" << path << ") to be LL_PCODE_PATH_LINE" << llendl; path = LL_PCODE_PATH_LINE; } mProfileParams.setCurveType(profile); mPathParams.setCurveType(path); return result; } // static bool LLVolumeParams::validate(U8 prof_curve, F32 prof_begin, F32 prof_end, F32 hollow, U8 path_curve, F32 path_begin, F32 path_end, F32 scx, F32 scy, F32 shx, F32 shy, F32 twistend, F32 twistbegin, F32 radiusoffset, F32 tx, F32 ty, F32 revolutions, F32 skew) { LLVolumeParams test_params; if (!test_params.setType (prof_curve, path_curve)) { return false; } if (!test_params.setBeginAndEndS (prof_begin, prof_end)) { return false; } if (!test_params.setBeginAndEndT (path_begin, path_end)) { return false; } if (!test_params.setHollow (hollow)) { return false; } if (!test_params.setTwistBegin (twistbegin)) { return false; } if (!test_params.setTwistEnd (twistend)) { return false; } if (!test_params.setRatio (scx, scy)) { return false; } if (!test_params.setShear (shx, shy)) { return false; } if (!test_params.setTaper (tx, ty)) { return false; } if (!test_params.setRevolutions (revolutions)) { return false; } if (!test_params.setRadiusOffset (radiusoffset)) { return false; } if (!test_params.setSkew (skew)) { return false; } return true; } S32 *LLVolume::getTriangleIndices(U32 &num_indices) const { LLMemType m1(LLMemType::MTYPE_VOLUME); S32 expected_num_triangle_indices = getNumTriangleIndices(); if (expected_num_triangle_indices > MAX_VOLUME_TRIANGLE_INDICES) { // we don't allow LLVolumes with this many vertices llwarns << "Couldn't allocate triangle indices" << llendl; num_indices = 0; return NULL; } S32* index = new S32[expected_num_triangle_indices]; S32 count = 0; // Let's do this totally diffently, as we don't care about faces... // Counter-clockwise triangles are forward facing... BOOL open = getProfile().isOpen(); BOOL hollow = (mParams.getProfileParams().getHollow() > 0); BOOL path_open = getPath().isOpen(); S32 size_s, size_s_out, size_t; S32 s, t, i; size_s = getProfile().getTotal(); size_s_out = getProfile().getTotalOut(); size_t = getPath().mPath.size(); // NOTE -- if the construction of the triangles below ever changes // then getNumTriangleIndices() method may also have to be updated. if (open) /* Flawfinder: ignore */ { if (hollow) { // Open hollow -- much like the closed solid, except we // we need to stitch up the gap between s=0 and s=size_s-1 for (t = 0; t < size_t - 1; t++) { // The outer face, first cut, and inner face for (s = 0; s < size_s - 1; s++) { i = s + t*size_s; index[count++] = i; // x,y index[count++] = i + 1; // x+1,y index[count++] = i + size_s; // x,y+1 index[count++] = i + size_s; // x,y+1 index[count++] = i + 1; // x+1,y index[count++] = i + size_s + 1; // x+1,y+1 } // The other cut face index[count++] = s + t*size_s; // x,y index[count++] = 0 + t*size_s; // x+1,y index[count++] = s + (t+1)*size_s; // x,y+1 index[count++] = s + (t+1)*size_s; // x,y+1 index[count++] = 0 + t*size_s; // x+1,y index[count++] = 0 + (t+1)*size_s; // x+1,y+1 } // Do the top and bottom caps, if necessary if (path_open) { // Top cap S32 pt1 = 0; S32 pt2 = size_s-1; S32 i = (size_t - 1)*size_s; while (pt2 - pt1 > 1) { // Use the profile points instead of the mesh, since you want // the un-transformed profile distances. LLVector3 p1 = getProfile().mProfile[pt1]; LLVector3 p2 = getProfile().mProfile[pt2]; LLVector3 pa = getProfile().mProfile[pt1+1]; LLVector3 pb = getProfile().mProfile[pt2-1]; p1.mV[VZ] = 0.f; p2.mV[VZ] = 0.f; pa.mV[VZ] = 0.f; pb.mV[VZ] = 0.f; // Use area of triangle to determine backfacing F32 area_1a2, area_1ba, area_21b, area_2ab; area_1a2 = (p1.mV[0]*pa.mV[1] - pa.mV[0]*p1.mV[1]) + (pa.mV[0]*p2.mV[1] - p2.mV[0]*pa.mV[1]) + (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]); area_1ba = (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*pa.mV[1] - pa.mV[0]*pb.mV[1]) + (pa.mV[0]*p1.mV[1] - p1.mV[0]*pa.mV[1]); area_21b = (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]) + (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); area_2ab = (p2.mV[0]*pa.mV[1] - pa.mV[0]*p2.mV[1]) + (pa.mV[0]*pb.mV[1] - pb.mV[0]*pa.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); BOOL use_tri1a2 = TRUE; BOOL tri_1a2 = TRUE; BOOL tri_21b = TRUE; if (area_1a2 < 0) { tri_1a2 = FALSE; } if (area_2ab < 0) { // Can't use, because it contains point b tri_1a2 = FALSE; } if (area_21b < 0) { tri_21b = FALSE; } if (area_1ba < 0) { // Can't use, because it contains point b tri_21b = FALSE; } if (!tri_1a2) { use_tri1a2 = FALSE; } else if (!tri_21b) { use_tri1a2 = TRUE; } else { LLVector3 d1 = p1 - pa; LLVector3 d2 = p2 - pb; if (d1.magVecSquared() < d2.magVecSquared()) { use_tri1a2 = TRUE; } else { use_tri1a2 = FALSE; } } if (use_tri1a2) { index[count++] = pt1 + i; index[count++] = pt1 + 1 + i; index[count++] = pt2 + i; pt1++; } else { index[count++] = pt1 + i; index[count++] = pt2 - 1 + i; index[count++] = pt2 + i; pt2--; } } // Bottom cap pt1 = 0; pt2 = size_s-1; while (pt2 - pt1 > 1) { // Use the profile points instead of the mesh, since you want // the un-transformed profile distances. LLVector3 p1 = getProfile().mProfile[pt1]; LLVector3 p2 = getProfile().mProfile[pt2]; LLVector3 pa = getProfile().mProfile[pt1+1]; LLVector3 pb = getProfile().mProfile[pt2-1]; p1.mV[VZ] = 0.f; p2.mV[VZ] = 0.f; pa.mV[VZ] = 0.f; pb.mV[VZ] = 0.f; // Use area of triangle to determine backfacing F32 area_1a2, area_1ba, area_21b, area_2ab; area_1a2 = (p1.mV[0]*pa.mV[1] - pa.mV[0]*p1.mV[1]) + (pa.mV[0]*p2.mV[1] - p2.mV[0]*pa.mV[1]) + (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]); area_1ba = (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*pa.mV[1] - pa.mV[0]*pb.mV[1]) + (pa.mV[0]*p1.mV[1] - p1.mV[0]*pa.mV[1]); area_21b = (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]) + (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); area_2ab = (p2.mV[0]*pa.mV[1] - pa.mV[0]*p2.mV[1]) + (pa.mV[0]*pb.mV[1] - pb.mV[0]*pa.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); BOOL use_tri1a2 = TRUE; BOOL tri_1a2 = TRUE; BOOL tri_21b = TRUE; if (area_1a2 < 0) { tri_1a2 = FALSE; } if (area_2ab < 0) { // Can't use, because it contains point b tri_1a2 = FALSE; } if (area_21b < 0) { tri_21b = FALSE; } if (area_1ba < 0) { // Can't use, because it contains point b tri_21b = FALSE; } if (!tri_1a2) { use_tri1a2 = FALSE; } else if (!tri_21b) { use_tri1a2 = TRUE; } else { LLVector3 d1 = p1 - pa; LLVector3 d2 = p2 - pb; if (d1.magVecSquared() < d2.magVecSquared()) { use_tri1a2 = TRUE; } else { use_tri1a2 = FALSE; } } if (use_tri1a2) { index[count++] = pt1; index[count++] = pt2; index[count++] = pt1 + 1; pt1++; } else { index[count++] = pt1; index[count++] = pt2; index[count++] = pt2 - 1; pt2--; } } } } else { // Open solid for (t = 0; t < size_t - 1; t++) { // Outer face + 1 cut face for (s = 0; s < size_s - 1; s++) { i = s + t*size_s; index[count++] = i; // x,y index[count++] = i + 1; // x+1,y index[count++] = i + size_s; // x,y+1 index[count++] = i + size_s; // x,y+1 index[count++] = i + 1; // x+1,y index[count++] = i + size_s + 1; // x+1,y+1 } // The other cut face index[count++] = (size_s - 1) + (t*size_s); // x,y index[count++] = 0 + t*size_s; // x+1,y index[count++] = (size_s - 1) + (t+1)*size_s; // x,y+1 index[count++] = (size_s - 1) + (t+1)*size_s; // x,y+1 index[count++] = 0 + (t*size_s); // x+1,y index[count++] = 0 + (t+1)*size_s; // x+1,y+1 } // Do the top and bottom caps, if necessary if (path_open) { for (s = 0; s < size_s - 2; s++) { index[count++] = s+1; index[count++] = s; index[count++] = size_s - 1; } // We've got a top cap S32 offset = (size_t - 1)*size_s; for (s = 0; s < size_s - 2; s++) { // Inverted ordering from bottom cap. index[count++] = offset + size_s - 1; index[count++] = offset + s; index[count++] = offset + s + 1; } } } } else if (hollow) { // Closed hollow // Outer face for (t = 0; t < size_t - 1; t++) { for (s = 0; s < size_s_out - 1; s++) { i = s + t*size_s; index[count++] = i; // x,y index[count++] = i + 1; // x+1,y index[count++] = i + size_s; // x,y+1 index[count++] = i + size_s; // x,y+1 index[count++] = i + 1; // x+1,y index[count++] = i + 1 + size_s; // x+1,y+1 } } // Inner face // Invert facing from outer face for (t = 0; t < size_t - 1; t++) { for (s = size_s_out; s < size_s - 1; s++) { i = s + t*size_s; index[count++] = i; // x,y index[count++] = i + 1; // x+1,y index[count++] = i + size_s; // x,y+1 index[count++] = i + size_s; // x,y+1 index[count++] = i + 1; // x+1,y index[count++] = i + 1 + size_s; // x+1,y+1 } } // Do the top and bottom caps, if necessary if (path_open) { // Top cap S32 pt1 = 0; S32 pt2 = size_s-1; S32 i = (size_t - 1)*size_s; while (pt2 - pt1 > 1) { // Use the profile points instead of the mesh, since you want // the un-transformed profile distances. LLVector3 p1 = getProfile().mProfile[pt1]; LLVector3 p2 = getProfile().mProfile[pt2]; LLVector3 pa = getProfile().mProfile[pt1+1]; LLVector3 pb = getProfile().mProfile[pt2-1]; p1.mV[VZ] = 0.f; p2.mV[VZ] = 0.f; pa.mV[VZ] = 0.f; pb.mV[VZ] = 0.f; // Use area of triangle to determine backfacing F32 area_1a2, area_1ba, area_21b, area_2ab; area_1a2 = (p1.mV[0]*pa.mV[1] - pa.mV[0]*p1.mV[1]) + (pa.mV[0]*p2.mV[1] - p2.mV[0]*pa.mV[1]) + (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]); area_1ba = (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*pa.mV[1] - pa.mV[0]*pb.mV[1]) + (pa.mV[0]*p1.mV[1] - p1.mV[0]*pa.mV[1]); area_21b = (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]) + (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); area_2ab = (p2.mV[0]*pa.mV[1] - pa.mV[0]*p2.mV[1]) + (pa.mV[0]*pb.mV[1] - pb.mV[0]*pa.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); BOOL use_tri1a2 = TRUE; BOOL tri_1a2 = TRUE; BOOL tri_21b = TRUE; if (area_1a2 < 0) { tri_1a2 = FALSE; } if (area_2ab < 0) { // Can't use, because it contains point b tri_1a2 = FALSE; } if (area_21b < 0) { tri_21b = FALSE; } if (area_1ba < 0) { // Can't use, because it contains point b tri_21b = FALSE; } if (!tri_1a2) { use_tri1a2 = FALSE; } else if (!tri_21b) { use_tri1a2 = TRUE; } else { LLVector3 d1 = p1 - pa; LLVector3 d2 = p2 - pb; if (d1.magVecSquared() < d2.magVecSquared()) { use_tri1a2 = TRUE; } else { use_tri1a2 = FALSE; } } if (use_tri1a2) { index[count++] = pt1 + i; index[count++] = pt1 + 1 + i; index[count++] = pt2 + i; pt1++; } else { index[count++] = pt1 + i; index[count++] = pt2 - 1 + i; index[count++] = pt2 + i; pt2--; } } // Bottom cap pt1 = 0; pt2 = size_s-1; while (pt2 - pt1 > 1) { // Use the profile points instead of the mesh, since you want // the un-transformed profile distances. LLVector3 p1 = getProfile().mProfile[pt1]; LLVector3 p2 = getProfile().mProfile[pt2]; LLVector3 pa = getProfile().mProfile[pt1+1]; LLVector3 pb = getProfile().mProfile[pt2-1]; p1.mV[VZ] = 0.f; p2.mV[VZ] = 0.f; pa.mV[VZ] = 0.f; pb.mV[VZ] = 0.f; // Use area of triangle to determine backfacing F32 area_1a2, area_1ba, area_21b, area_2ab; area_1a2 = (p1.mV[0]*pa.mV[1] - pa.mV[0]*p1.mV[1]) + (pa.mV[0]*p2.mV[1] - p2.mV[0]*pa.mV[1]) + (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]); area_1ba = (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*pa.mV[1] - pa.mV[0]*pb.mV[1]) + (pa.mV[0]*p1.mV[1] - p1.mV[0]*pa.mV[1]); area_21b = (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]) + (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); area_2ab = (p2.mV[0]*pa.mV[1] - pa.mV[0]*p2.mV[1]) + (pa.mV[0]*pb.mV[1] - pb.mV[0]*pa.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); BOOL use_tri1a2 = TRUE; BOOL tri_1a2 = TRUE; BOOL tri_21b = TRUE; if (area_1a2 < 0) { tri_1a2 = FALSE; } if (area_2ab < 0) { // Can't use, because it contains point b tri_1a2 = FALSE; } if (area_21b < 0) { tri_21b = FALSE; } if (area_1ba < 0) { // Can't use, because it contains point b tri_21b = FALSE; } if (!tri_1a2) { use_tri1a2 = FALSE; } else if (!tri_21b) { use_tri1a2 = TRUE; } else { LLVector3 d1 = p1 - pa; LLVector3 d2 = p2 - pb; if (d1.magVecSquared() < d2.magVecSquared()) { use_tri1a2 = TRUE; } else { use_tri1a2 = FALSE; } } if (use_tri1a2) { index[count++] = pt1; index[count++] = pt2; index[count++] = pt1 + 1; pt1++; } else { index[count++] = pt1; index[count++] = pt2; index[count++] = pt2 - 1; pt2--; } } } } else { // Closed solid. Easy case. for (t = 0; t < size_t - 1; t++) { for (s = 0; s < size_s - 1; s++) { // Should wrap properly, but for now... i = s + t*size_s; index[count++] = i; // x,y index[count++] = i + 1; // x+1,y index[count++] = i + size_s; // x,y+1 index[count++] = i + size_s; // x,y+1 index[count++] = i + 1; // x+1,y index[count++] = i + size_s + 1; // x+1,y+1 } } // Do the top and bottom caps, if necessary if (path_open) { // bottom cap for (s = 1; s < size_s - 2; s++) { index[count++] = s+1; index[count++] = s; index[count++] = 0; } // top cap S32 offset = (size_t - 1)*size_s; for (s = 1; s < size_s - 2; s++) { // Inverted ordering from bottom cap. index[count++] = offset; index[count++] = offset + s; index[count++] = offset + s + 1; } } } #ifdef LL_DEBUG // assert that we computed the correct number of indices if (count != expected_num_triangle_indices ) { llerrs << "bad index count prediciton:" << " expected=" << expected_num_triangle_indices << " actual=" << count << llendl; } #endif #if 0 // verify that each index does not point beyond the size of the mesh S32 num_vertices = mMesh.size(); for (i = 0; i < count; i+=3) { llinfos << index[i] << ":" << index[i+1] << ":" << index[i+2] << llendl; llassert(index[i] < num_vertices); llassert(index[i+1] < num_vertices); llassert(index[i+2] < num_vertices); } #endif num_indices = count; return index; } S32 LLVolume::getNumTriangleIndices() const { BOOL profile_open = getProfile().isOpen(); BOOL hollow = (mParams.getProfileParams().getHollow() > 0); BOOL path_open = getPath().isOpen(); S32 size_s, size_s_out, size_t; size_s = getProfile().getTotal(); size_s_out = getProfile().getTotalOut(); size_t = getPath().mPath.size(); S32 count = 0; if (profile_open) /* Flawfinder: ignore */ { if (hollow) { // Open hollow -- much like the closed solid, except we // we need to stitch up the gap between s=0 and s=size_s-1 count = (size_t - 1) * (((size_s -1) * 6) + 6); } else { count = (size_t - 1) * (((size_s -1) * 6) + 6); } } else if (hollow) { // Closed hollow // Outer face count = (size_t - 1) * (size_s_out - 1) * 6; // Inner face count += (size_t - 1) * ((size_s - 1) - size_s_out) * 6; } else { // Closed solid. Easy case. count = (size_t - 1) * (size_s - 1) * 6; } if (path_open) { S32 cap_triangle_count = size_s - 3; if ( profile_open || hollow ) { cap_triangle_count = size_s - 2; } if ( cap_triangle_count > 0 ) { // top and bottom caps count += cap_triangle_count * 2 * 3; } } return count; } //----------------------------------------------------------------------------- // generateSilhouetteVertices() //----------------------------------------------------------------------------- void LLVolume::generateSilhouetteVertices(std::vector &vertices, std::vector &normals, std::vector &segments, const LLVector3& obj_cam_vec, const LLMatrix4& mat, const LLMatrix3& norm_mat, S32 face_mask) { LLMemType m1(LLMemType::MTYPE_VOLUME); vertices.clear(); normals.clear(); segments.clear(); S32 cur_index = 0; //for each face for (face_list_t::iterator iter = mVolumeFaces.begin(); iter != mVolumeFaces.end(); ++iter) { const LLVolumeFace& face = *iter; if (!(face_mask & (0x1 << cur_index++))) { continue; } if (face.mTypeMask & (LLVolumeFace::CAP_MASK)) { } else { //============================================== //DEBUG draw edge map instead of silhouette edge //============================================== #if DEBUG_SILHOUETTE_EDGE_MAP //for each triangle U32 count = face.mIndices.size(); for (U32 j = 0; j < count/3; j++) { //get vertices S32 v1 = face.mIndices[j*3+0]; S32 v2 = face.mIndices[j*3+1]; S32 v3 = face.mIndices[j*3+2]; //get current face center LLVector3 cCenter = (face.mVertices[v1].mPosition + face.mVertices[v2].mPosition + face.mVertices[v3].mPosition) / 3.0f; //for each edge for (S32 k = 0; k < 3; k++) { S32 nIndex = face.mEdge[j*3+k]; if (nIndex <= -1) { continue; } if (nIndex >= (S32) count/3) { continue; } //get neighbor vertices v1 = face.mIndices[nIndex*3+0]; v2 = face.mIndices[nIndex*3+1]; v3 = face.mIndices[nIndex*3+2]; //get neighbor face center LLVector3 nCenter = (face.mVertices[v1].mPosition + face.mVertices[v2].mPosition + face.mVertices[v3].mPosition) / 3.0f; //draw line vertices.push_back(cCenter); vertices.push_back(nCenter); normals.push_back(LLVector3(1,1,1)); normals.push_back(LLVector3(1,1,1)); segments.push_back(vertices.size()); } } continue; //============================================== //DEBUG //============================================== //============================================== //DEBUG draw normals instead of silhouette edge //============================================== #elif DEBUG_SILHOUETTE_NORMALS //for each vertex for (U32 j = 0; j < face.mVertices.size(); j++) { vertices.push_back(face.mVertices[j].mPosition); vertices.push_back(face.mVertices[j].mPosition + face.mVertices[j].mNormal*0.1f); normals.push_back(LLVector3(0,0,1)); normals.push_back(LLVector3(0,0,1)); segments.push_back(vertices.size()); #if DEBUG_SILHOUETTE_BINORMALS vertices.push_back(face.mVertices[j].mPosition); vertices.push_back(face.mVertices[j].mPosition + face.mVertices[j].mBinormal*0.1f); normals.push_back(LLVector3(0,0,1)); normals.push_back(LLVector3(0,0,1)); segments.push_back(vertices.size()); #endif } continue; #else //============================================== //DEBUG //============================================== static const U8 AWAY = 0x01, TOWARDS = 0x02; //for each triangle std::vector fFacing; vector_append(fFacing, face.mIndices.size()/3); for (U32 j = 0; j < face.mIndices.size()/3; j++) { //approximate normal S32 v1 = face.mIndices[j*3+0]; S32 v2 = face.mIndices[j*3+1]; S32 v3 = face.mIndices[j*3+2]; LLVector3 norm = (face.mVertices[v1].mPosition - face.mVertices[v2].mPosition) % (face.mVertices[v2].mPosition - face.mVertices[v3].mPosition); if (norm.magVecSquared() < 0.00000001f) { fFacing[j] = AWAY | TOWARDS; } else { //get view vector LLVector3 view = (obj_cam_vec-face.mVertices[v1].mPosition); bool away = view * norm > 0.0f; if (away) { fFacing[j] = AWAY; } else { fFacing[j] = TOWARDS; } } } //for each triangle for (U32 j = 0; j < face.mIndices.size()/3; j++) { if (fFacing[j] == (AWAY | TOWARDS)) { //this is a degenerate triangle //take neighbor facing (degenerate faces get facing of one of their neighbors) // *FIX IF NEEDED: this does not deal with neighboring degenerate faces for (S32 k = 0; k < 3; k++) { S32 index = face.mEdge[j*3+k]; if (index != -1) { fFacing[j] = fFacing[index]; break; } } continue; //skip degenerate face } //for each edge for (S32 k = 0; k < 3; k++) { S32 index = face.mEdge[j*3+k]; if (index != -1 && fFacing[index] == (AWAY | TOWARDS)) { //our neighbor is degenerate, make him face our direction fFacing[face.mEdge[j*3+k]] = fFacing[j]; continue; } if (index == -1 || //edge has no neighbor, MUST be a silhouette edge (fFacing[index] & fFacing[j]) == 0) { //we found a silhouette edge S32 v1 = face.mIndices[j*3+k]; S32 v2 = face.mIndices[j*3+((k+1)%3)]; vertices.push_back(face.mVertices[v1].mPosition*mat); LLVector3 norm1 = face.mVertices[v1].mNormal * norm_mat; norm1.normVec(); normals.push_back(norm1); vertices.push_back(face.mVertices[v2].mPosition*mat); LLVector3 norm2 = face.mVertices[v2].mNormal * norm_mat; norm2.normVec(); normals.push_back(norm2); segments.push_back(vertices.size()); } } } #endif } } } S32 LLVolume::lineSegmentIntersect(const LLVector3& start, const LLVector3& end, S32 face, LLVector3* intersection,LLVector2* tex_coord, LLVector3* normal, LLVector3* bi_normal) { S32 hit_face = -1; S32 start_face; S32 end_face; if (face == -1) // ALL_SIDES { start_face = 0; end_face = getNumFaces() - 1; } else { start_face = face; end_face = face; } LLVector3 dir = end - start; F32 closest_t = 2.f; // must be larger than 1 for (S32 i = start_face; i <= end_face; i++) { const LLVolumeFace &face = getVolumeFace((U32)i); LLVector3 box_center = (face.mExtents[0] + face.mExtents[1]) / 2.f; LLVector3 box_size = face.mExtents[1] - face.mExtents[0]; if (LLLineSegmentBoxIntersect(start, end, box_center, box_size)) { if (bi_normal != NULL) // if the caller wants binormals, we may need to generate them { genBinormals(i); } for (U32 tri = 0; tri < face.mIndices.size()/3; tri++) { S32 index1 = face.mIndices[tri*3+0]; S32 index2 = face.mIndices[tri*3+1]; S32 index3 = face.mIndices[tri*3+2]; F32 a, b, t; if (LLTriangleRayIntersect(face.mVertices[index1].mPosition, face.mVertices[index2].mPosition, face.mVertices[index3].mPosition, start, dir, &a, &b, &t, FALSE)) { if ((t >= 0.f) && // if hit is after start (t <= 1.f) && // and before end (t < closest_t)) // and this hit is closer { closest_t = t; hit_face = i; if (intersection != NULL) { *intersection = start + dir * closest_t; } if (tex_coord != NULL) { *tex_coord = ((1.f - a - b) * face.mVertices[index1].mTexCoord + a * face.mVertices[index2].mTexCoord + b * face.mVertices[index3].mTexCoord); } if (normal != NULL) { *normal = ((1.f - a - b) * face.mVertices[index1].mNormal + a * face.mVertices[index2].mNormal + b * face.mVertices[index3].mNormal); } if (bi_normal != NULL) { *bi_normal = ((1.f - a - b) * face.mVertices[index1].mBinormal + a * face.mVertices[index2].mBinormal + b * face.mVertices[index3].mBinormal); } } } } } } return hit_face; } class LLVertexIndexPair { public: LLVertexIndexPair(const LLVector3 &vertex, const S32 index); LLVector3 mVertex; S32 mIndex; }; LLVertexIndexPair::LLVertexIndexPair(const LLVector3 &vertex, const S32 index) { mVertex = vertex; mIndex = index; } const F32 VERTEX_SLOP = 0.00001f; const F32 VERTEX_SLOP_SQRD = VERTEX_SLOP * VERTEX_SLOP; struct lessVertex { bool operator()(const LLVertexIndexPair *a, const LLVertexIndexPair *b) { const F32 slop = VERTEX_SLOP; if (a->mVertex.mV[0] + slop < b->mVertex.mV[0]) { return TRUE; } else if (a->mVertex.mV[0] - slop > b->mVertex.mV[0]) { return FALSE; } if (a->mVertex.mV[1] + slop < b->mVertex.mV[1]) { return TRUE; } else if (a->mVertex.mV[1] - slop > b->mVertex.mV[1]) { return FALSE; } if (a->mVertex.mV[2] + slop < b->mVertex.mV[2]) { return TRUE; } else if (a->mVertex.mV[2] - slop > b->mVertex.mV[2]) { return FALSE; } return FALSE; } }; struct lessTriangle { bool operator()(const S32 *a, const S32 *b) { if (*a < *b) { return TRUE; } else if (*a > *b) { return FALSE; } if (*(a+1) < *(b+1)) { return TRUE; } else if (*(a+1) > *(b+1)) { return FALSE; } if (*(a+2) < *(b+2)) { return TRUE; } else if (*(a+2) > *(b+2)) { return FALSE; } return FALSE; } }; BOOL equalTriangle(const S32 *a, const S32 *b) { if ((*a == *b) && (*(a+1) == *(b+1)) && (*(a+2) == *(b+2))) { return TRUE; } return FALSE; } BOOL LLVolume::cleanupTriangleData( const S32 num_input_vertices, const std::vector& input_vertices, const S32 num_input_triangles, S32 *input_triangles, S32 &num_output_vertices, LLVector3 **output_vertices, S32 &num_output_triangles, S32 **output_triangles) { LLMemType m1(LLMemType::MTYPE_VOLUME); /* Testing: avoid any cleanup static BOOL skip_cleanup = TRUE; if ( skip_cleanup ) { num_output_vertices = num_input_vertices; num_output_triangles = num_input_triangles; *output_vertices = new LLVector3[num_input_vertices]; for (S32 index = 0; index < num_input_vertices; index++) { (*output_vertices)[index] = input_vertices[index].mPos; } *output_triangles = new S32[num_input_triangles*3]; memcpy(*output_triangles, input_triangles, 3*num_input_triangles*sizeof(S32)); // Flawfinder: ignore return TRUE; } */ // Here's how we do this: // Create a structure which contains the original vertex index and the // LLVector3 data. // "Sort" the data by the vectors // Create an array the size of the old vertex list, with a mapping of // old indices to new indices. // Go through triangles, shift so the lowest index is first // Sort triangles by first index // Remove duplicate triangles // Allocate and pack new triangle data. //LLTimer cleanupTimer; //llinfos << "In vertices: " << num_input_vertices << llendl; //llinfos << "In triangles: " << num_input_triangles << llendl; S32 i; typedef std::multiset vertex_set_t; vertex_set_t vertex_list; LLVertexIndexPair *pairp = NULL; for (i = 0; i < num_input_vertices; i++) { LLVertexIndexPair *new_pairp = new LLVertexIndexPair(input_vertices[i].mPos, i); vertex_list.insert(new_pairp); } // Generate the vertex mapping and the list of vertices without // duplicates. This will crash if there are no vertices. S32 *vertex_mapping = new S32[num_input_vertices]; LLVector3 *new_vertices = new LLVector3[num_input_vertices]; LLVertexIndexPair *prev_pairp = NULL; S32 new_num_vertices; new_num_vertices = 0; for (vertex_set_t::iterator iter = vertex_list.begin(), end = vertex_list.end(); iter != end; iter++) { pairp = *iter; if (!prev_pairp || ((pairp->mVertex - prev_pairp->mVertex).magVecSquared() >= VERTEX_SLOP_SQRD)) { new_vertices[new_num_vertices] = pairp->mVertex; //llinfos << "Added vertex " << new_num_vertices << " : " << pairp->mVertex << llendl; new_num_vertices++; // Update the previous prev_pairp = pairp; } else { //llinfos << "Removed duplicate vertex " << pairp->mVertex << ", distance magVecSquared() is " << (pairp->mVertex - prev_pairp->mVertex).magVecSquared() << llendl; } vertex_mapping[pairp->mIndex] = new_num_vertices - 1; } // Iterate through triangles and remove degenerates, re-ordering vertices // along the way. S32 *new_triangles = new S32[num_input_triangles * 3]; S32 new_num_triangles = 0; for (i = 0; i < num_input_triangles; i++) { S32 v1 = i*3; S32 v2 = v1 + 1; S32 v3 = v1 + 2; //llinfos << "Checking triangle " << input_triangles[v1] << ":" << input_triangles[v2] << ":" << input_triangles[v3] << llendl; input_triangles[v1] = vertex_mapping[input_triangles[v1]]; input_triangles[v2] = vertex_mapping[input_triangles[v2]]; input_triangles[v3] = vertex_mapping[input_triangles[v3]]; if ((input_triangles[v1] == input_triangles[v2]) || (input_triangles[v1] == input_triangles[v3]) || (input_triangles[v2] == input_triangles[v3])) { //llinfos << "Removing degenerate triangle " << input_triangles[v1] << ":" << input_triangles[v2] << ":" << input_triangles[v3] << llendl; // Degenerate triangle, skip continue; } if (input_triangles[v1] < input_triangles[v2]) { if (input_triangles[v1] < input_triangles[v3]) { // (0 < 1) && (0 < 2) new_triangles[new_num_triangles*3] = input_triangles[v1]; new_triangles[new_num_triangles*3+1] = input_triangles[v2]; new_triangles[new_num_triangles*3+2] = input_triangles[v3]; } else { // (0 < 1) && (2 < 0) new_triangles[new_num_triangles*3] = input_triangles[v3]; new_triangles[new_num_triangles*3+1] = input_triangles[v1]; new_triangles[new_num_triangles*3+2] = input_triangles[v2]; } } else if (input_triangles[v2] < input_triangles[v3]) { // (1 < 0) && (1 < 2) new_triangles[new_num_triangles*3] = input_triangles[v2]; new_triangles[new_num_triangles*3+1] = input_triangles[v3]; new_triangles[new_num_triangles*3+2] = input_triangles[v1]; } else { // (1 < 0) && (2 < 1) new_triangles[new_num_triangles*3] = input_triangles[v3]; new_triangles[new_num_triangles*3+1] = input_triangles[v1]; new_triangles[new_num_triangles*3+2] = input_triangles[v2]; } new_num_triangles++; } if (new_num_triangles == 0) { llwarns << "Created volume object with 0 faces." << llendl; delete[] new_triangles; delete[] vertex_mapping; delete[] new_vertices; return FALSE; } typedef std::set triangle_set_t; triangle_set_t triangle_list; for (i = 0; i < new_num_triangles; i++) { triangle_list.insert(&new_triangles[i*3]); } // Sort through the triangle list, and delete duplicates S32 *prevp = NULL; S32 *curp = NULL; S32 *sorted_tris = new S32[new_num_triangles*3]; S32 cur_tri = 0; for (triangle_set_t::iterator iter = triangle_list.begin(), end = triangle_list.end(); iter != end; iter++) { curp = *iter; if (!prevp || !equalTriangle(prevp, curp)) { //llinfos << "Added triangle " << *curp << ":" << *(curp+1) << ":" << *(curp+2) << llendl; sorted_tris[cur_tri*3] = *curp; sorted_tris[cur_tri*3+1] = *(curp+1); sorted_tris[cur_tri*3+2] = *(curp+2); cur_tri++; prevp = curp; } else { //llinfos << "Skipped triangle " << *curp << ":" << *(curp+1) << ":" << *(curp+2) << llendl; } } *output_vertices = new LLVector3[new_num_vertices]; num_output_vertices = new_num_vertices; for (i = 0; i < new_num_vertices; i++) { (*output_vertices)[i] = new_vertices[i]; } *output_triangles = new S32[cur_tri*3]; num_output_triangles = cur_tri; memcpy(*output_triangles, sorted_tris, 3*cur_tri*sizeof(S32)); /* Flawfinder: ignore */ /* llinfos << "Out vertices: " << num_output_vertices << llendl; llinfos << "Out triangles: " << num_output_triangles << llendl; for (i = 0; i < num_output_vertices; i++) { llinfos << i << ":" << (*output_vertices)[i] << llendl; } for (i = 0; i < num_output_triangles; i++) { llinfos << i << ":" << (*output_triangles)[i*3] << ":" << (*output_triangles)[i*3+1] << ":" << (*output_triangles)[i*3+2] << llendl; } */ //llinfos << "Out vertices: " << num_output_vertices << llendl; //llinfos << "Out triangles: " << num_output_triangles << llendl; delete[] vertex_mapping; vertex_mapping = NULL; delete[] new_vertices; new_vertices = NULL; delete[] new_triangles; new_triangles = NULL; delete[] sorted_tris; sorted_tris = NULL; triangle_list.clear(); std::for_each(vertex_list.begin(), vertex_list.end(), DeletePointer()); vertex_list.clear(); return TRUE; } BOOL LLVolumeParams::importFile(LLFILE *fp) { LLMemType m1(LLMemType::MTYPE_VOLUME); //llinfos << "importing volume" << llendl; const S32 BUFSIZE = 16384; char buffer[BUFSIZE]; /* Flawfinder: ignore */ // *NOTE: changing the size or type of this buffer will require // changing the sscanf below. char keyword[256]; /* Flawfinder: ignore */ keyword[0] = 0; while (!feof(fp)) { if (fgets(buffer, BUFSIZE, fp) == NULL) { buffer[0] = '\0'; } sscanf(buffer, " %255s", keyword); /* Flawfinder: ignore */ if (!strcmp("{", keyword)) { continue; } if (!strcmp("}",keyword)) { break; } else if (!strcmp("profile", keyword)) { mProfileParams.importFile(fp); } else if (!strcmp("path",keyword)) { mPathParams.importFile(fp); } else { llwarns << "unknown keyword " << keyword << " in volume import" << llendl; } } return TRUE; } BOOL LLVolumeParams::exportFile(LLFILE *fp) const { fprintf(fp,"\tshape 0\n"); fprintf(fp,"\t{\n"); mPathParams.exportFile(fp); mProfileParams.exportFile(fp); fprintf(fp, "\t}\n"); return TRUE; } BOOL LLVolumeParams::importLegacyStream(std::istream& input_stream) { LLMemType m1(LLMemType::MTYPE_VOLUME); //llinfos << "importing volume" << llendl; const S32 BUFSIZE = 16384; // *NOTE: changing the size or type of this buffer will require // changing the sscanf below. char buffer[BUFSIZE]; /* Flawfinder: ignore */ char keyword[256]; /* Flawfinder: ignore */ keyword[0] = 0; while (input_stream.good()) { input_stream.getline(buffer, BUFSIZE); sscanf(buffer, " %255s", keyword); if (!strcmp("{", keyword)) { continue; } if (!strcmp("}",keyword)) { break; } else if (!strcmp("profile", keyword)) { mProfileParams.importLegacyStream(input_stream); } else if (!strcmp("path",keyword)) { mPathParams.importLegacyStream(input_stream); } else { llwarns << "unknown keyword " << keyword << " in volume import" << llendl; } } return TRUE; } BOOL LLVolumeParams::exportLegacyStream(std::ostream& output_stream) const { LLMemType m1(LLMemType::MTYPE_VOLUME); output_stream <<"\tshape 0\n"; output_stream <<"\t{\n"; mPathParams.exportLegacyStream(output_stream); mProfileParams.exportLegacyStream(output_stream); output_stream << "\t}\n"; return TRUE; } LLSD LLVolumeParams::asLLSD() const { LLSD sd = LLSD(); sd["path"] = mPathParams; sd["profile"] = mProfileParams; return sd; } bool LLVolumeParams::fromLLSD(LLSD& sd) { mPathParams.fromLLSD(sd["path"]); mProfileParams.fromLLSD(sd["profile"]); return true; } void LLVolumeParams::reduceS(F32 begin, F32 end) { begin = llclampf(begin); end = llclampf(end); if (begin > end) { F32 temp = begin; begin = end; end = temp; } F32 a = mProfileParams.getBegin(); F32 b = mProfileParams.getEnd(); mProfileParams.setBegin(a + begin * (b - a)); mProfileParams.setEnd(a + end * (b - a)); } void LLVolumeParams::reduceT(F32 begin, F32 end) { begin = llclampf(begin); end = llclampf(end); if (begin > end) { F32 temp = begin; begin = end; end = temp; } F32 a = mPathParams.getBegin(); F32 b = mPathParams.getEnd(); mPathParams.setBegin(a + begin * (b - a)); mPathParams.setEnd(a + end * (b - a)); } const F32 MIN_CONCAVE_PROFILE_WEDGE = 0.125f; // 1/8 unity const F32 MIN_CONCAVE_PATH_WEDGE = 0.111111f; // 1/9 unity // returns TRUE if the shape can be approximated with a convex shape // for collison purposes BOOL LLVolumeParams::isConvex() const { F32 path_length = mPathParams.getEnd() - mPathParams.getBegin(); F32 hollow = mProfileParams.getHollow(); U8 path_type = mPathParams.getCurveType(); if ( path_length > MIN_CONCAVE_PATH_WEDGE && ( mPathParams.getTwist() != mPathParams.getTwistBegin() || (hollow > 0.f && LL_PCODE_PATH_LINE != path_type) ) ) { // twist along a "not too short" path is concave return FALSE; } F32 profile_length = mProfileParams.getEnd() - mProfileParams.getBegin(); BOOL same_hole = hollow == 0.f || (mProfileParams.getCurveType() & LL_PCODE_HOLE_MASK) == LL_PCODE_HOLE_SAME; F32 min_profile_wedge = MIN_CONCAVE_PROFILE_WEDGE; U8 profile_type = mProfileParams.getCurveType() & LL_PCODE_PROFILE_MASK; if ( LL_PCODE_PROFILE_CIRCLE_HALF == profile_type ) { // it is a sphere and spheres get twice the minimum profile wedge min_profile_wedge = 2.f * MIN_CONCAVE_PROFILE_WEDGE; } BOOL convex_profile = ( ( profile_length == 1.f || profile_length <= 0.5f ) && hollow == 0.f ) // trivially convex || ( profile_length <= min_profile_wedge && same_hole ); // effectvely convex (even when hollow) if (!convex_profile) { // profile is concave return FALSE; } if ( LL_PCODE_PATH_LINE == path_type ) { // straight paths with convex profile return TRUE; } BOOL concave_path = (path_length < 1.0f) && (path_length > 0.5f); if (concave_path) { return FALSE; } // we're left with spheres, toroids and tubes if ( LL_PCODE_PROFILE_CIRCLE_HALF == profile_type ) { // at this stage all spheres must be convex return TRUE; } // it's a toroid or tube if ( path_length <= MIN_CONCAVE_PATH_WEDGE ) { // effectively convex return TRUE; } return FALSE; } // debug void LLVolumeParams::setCube() { mProfileParams.setCurveType(LL_PCODE_PROFILE_SQUARE); mProfileParams.setBegin(0.f); mProfileParams.setEnd(1.f); mProfileParams.setHollow(0.f); mPathParams.setBegin(0.f); mPathParams.setEnd(1.f); mPathParams.setScale(1.f, 1.f); mPathParams.setShear(0.f, 0.f); mPathParams.setCurveType(LL_PCODE_PATH_LINE); mPathParams.setTwistBegin(0.f); mPathParams.setTwistEnd(0.f); mPathParams.setRadiusOffset(0.f); mPathParams.setTaper(0.f, 0.f); mPathParams.setRevolutions(0.f); mPathParams.setSkew(0.f); } LLFaceID LLVolume::generateFaceMask() { LLFaceID new_mask = 0x0000; switch(mParams.getProfileParams().getCurveType() & LL_PCODE_PROFILE_MASK) { case LL_PCODE_PROFILE_CIRCLE: case LL_PCODE_PROFILE_CIRCLE_HALF: new_mask |= LL_FACE_OUTER_SIDE_0; break; case LL_PCODE_PROFILE_SQUARE: { for(S32 side = (S32)(mParams.getProfileParams().getBegin() * 4.f); side < llceil(mParams.getProfileParams().getEnd() * 4.f); side++) { new_mask |= LL_FACE_OUTER_SIDE_0 << side; } } break; case LL_PCODE_PROFILE_ISOTRI: case LL_PCODE_PROFILE_EQUALTRI: case LL_PCODE_PROFILE_RIGHTTRI: { for(S32 side = (S32)(mParams.getProfileParams().getBegin() * 3.f); side < llceil(mParams.getProfileParams().getEnd() * 3.f); side++) { new_mask |= LL_FACE_OUTER_SIDE_0 << side; } } break; default: llerrs << "Unknown profile!" << llendl; break; } // handle hollow objects if (mParams.getProfileParams().getHollow() > 0) { new_mask |= LL_FACE_INNER_SIDE; } // handle open profile curves if (mProfilep->isOpen()) { new_mask |= LL_FACE_PROFILE_BEGIN | LL_FACE_PROFILE_END; } // handle open path curves if (mPathp->isOpen()) { new_mask |= LL_FACE_PATH_BEGIN | LL_FACE_PATH_END; } return new_mask; } BOOL LLVolume::isFaceMaskValid(LLFaceID face_mask) { LLFaceID test_mask = 0; for(S32 i = 0; i < getNumFaces(); i++) { test_mask |= mProfilep->mFaces[i].mFaceID; } return test_mask == face_mask; } BOOL LLVolume::isConvex() const { // mParams.isConvex() may return FALSE even though the final // geometry is actually convex due to LOD approximations. // TODO -- provide LLPath and LLProfile with isConvex() methods // that correctly determine convexity. -- Leviathan return mParams.isConvex(); } std::ostream& operator<<(std::ostream &s, const LLProfileParams &profile_params) { s << "{type=" << (U32) profile_params.mCurveType; s << ", begin=" << profile_params.mBegin; s << ", end=" << profile_params.mEnd; s << ", hollow=" << profile_params.mHollow; s << "}"; return s; } std::ostream& operator<<(std::ostream &s, const LLPathParams &path_params) { s << "{type=" << (U32) path_params.mCurveType; s << ", begin=" << path_params.mBegin; s << ", end=" << path_params.mEnd; s << ", twist=" << path_params.mTwistEnd; s << ", scale=" << path_params.mScale; s << ", shear=" << path_params.mShear; s << ", twist_begin=" << path_params.mTwistBegin; s << ", radius_offset=" << path_params.mRadiusOffset; s << ", taper=" << path_params.mTaper; s << ", revolutions=" << path_params.mRevolutions; s << ", skew=" << path_params.mSkew; s << "}"; return s; } std::ostream& operator<<(std::ostream &s, const LLVolumeParams &volume_params) { s << "{profileparams = " << volume_params.mProfileParams; s << ", pathparams = " << volume_params.mPathParams; s << "}"; return s; } std::ostream& operator<<(std::ostream &s, const LLProfile &profile) { s << " {open=" << (U32) profile.mOpen; s << ", dirty=" << profile.mDirty; s << ", totalout=" << profile.mTotalOut; s << ", total=" << profile.mTotal; s << "}"; return s; } std::ostream& operator<<(std::ostream &s, const LLPath &path) { s << "{open=" << (U32) path.mOpen; s << ", dirty=" << path.mDirty; s << ", step=" << path.mStep; s << ", total=" << path.mTotal; s << "}"; return s; } std::ostream& operator<<(std::ostream &s, const LLVolume &volume) { s << "{params = " << volume.getParams(); s << ", path = " << *volume.mPathp; s << ", profile = " << *volume.mProfilep; s << "}"; return s; } std::ostream& operator<<(std::ostream &s, const LLVolume *volumep) { s << "{params = " << volumep->getParams(); s << ", path = " << *(volumep->mPathp); s << ", profile = " << *(volumep->mProfilep); s << "}"; return s; } BOOL LLVolumeFace::create(LLVolume* volume, BOOL partial_build) { if (mTypeMask & CAP_MASK) { return createCap(volume, partial_build); } else if ((mTypeMask & END_MASK) || (mTypeMask & SIDE_MASK)) { return createSide(volume, partial_build); } else { llerrs << "Unknown/uninitialized face type!" << llendl; return FALSE; } } void LerpPlanarVertex(LLVolumeFace::VertexData& v0, LLVolumeFace::VertexData& v1, LLVolumeFace::VertexData& v2, LLVolumeFace::VertexData& vout, F32 coef01, F32 coef02) { vout.mPosition = v0.mPosition + ((v1.mPosition-v0.mPosition)*coef01)+((v2.mPosition-v0.mPosition)*coef02); vout.mTexCoord = v0.mTexCoord + ((v1.mTexCoord-v0.mTexCoord)*coef01)+((v2.mTexCoord-v0.mTexCoord)*coef02); vout.mNormal = v0.mNormal; vout.mBinormal = v0.mBinormal; } BOOL LLVolumeFace::createUnCutCubeCap(LLVolume* volume, BOOL partial_build) { LLMemType m1(LLMemType::MTYPE_VOLUME); const std::vector& mesh = volume->getMesh(); const std::vector& profile = volume->getProfile().mProfile; S32 max_s = volume->getProfile().getTotal(); S32 max_t = volume->getPath().mPath.size(); // S32 i; S32 num_vertices = 0, num_indices = 0; S32 grid_size = (profile.size()-1)/4; S32 quad_count = (grid_size * grid_size); num_vertices = (grid_size+1)*(grid_size+1); num_indices = quad_count * 4; LLVector3& min = mExtents[0]; LLVector3& max = mExtents[1]; S32 offset = 0; if (mTypeMask & TOP_MASK) offset = (max_t-1) * max_s; else offset = mBeginS; VertexData corners[4]; VertexData baseVert; for(int t = 0; t < 4; t++){ corners[t].mPosition = mesh[offset + (grid_size*t)].mPos; corners[t].mTexCoord.mV[0] = profile[grid_size*t].mV[0]+0.5f; corners[t].mTexCoord.mV[1] = 0.5f - profile[grid_size*t].mV[1]; } baseVert.mNormal = ((corners[1].mPosition-corners[0].mPosition) % (corners[2].mPosition-corners[1].mPosition)); baseVert.mNormal.normVec(); if(!(mTypeMask & TOP_MASK)){ baseVert.mNormal *= -1.0f; }else{ //Swap the UVs on the U(X) axis for top face LLVector2 swap; swap = corners[0].mTexCoord; corners[0].mTexCoord=corners[3].mTexCoord; corners[3].mTexCoord=swap; swap = corners[1].mTexCoord; corners[1].mTexCoord=corners[2].mTexCoord; corners[2].mTexCoord=swap; } baseVert.mBinormal = calc_binormal_from_triangle( corners[0].mPosition, corners[0].mTexCoord, corners[1].mPosition, corners[1].mTexCoord, corners[2].mPosition, corners[2].mTexCoord); for(int t = 0; t < 4; t++){ corners[t].mBinormal = baseVert.mBinormal; corners[t].mNormal = baseVert.mNormal; } mHasBinormals = TRUE; if (partial_build) { mVertices.clear(); } S32 vtop = mVertices.size(); for(int gx = 0;gx=0;i--)mIndices.push_back(vtop+(gy*(grid_size+1))+gx+idxs[i]); }else{ for(int i=0;i<6;i++)mIndices.push_back(vtop+(gy*(grid_size+1))+gx+idxs[i]); } } } } return TRUE; } BOOL LLVolumeFace::createCap(LLVolume* volume, BOOL partial_build) { LLMemType m1(LLMemType::MTYPE_VOLUME); if (!(mTypeMask & HOLLOW_MASK) && !(mTypeMask & OPEN_MASK) && ((volume->getParams().getPathParams().getBegin()==0.0f)&& (volume->getParams().getPathParams().getEnd()==1.0f))&& (volume->getParams().getProfileParams().getCurveType()==LL_PCODE_PROFILE_SQUARE && volume->getParams().getPathParams().getCurveType()==LL_PCODE_PATH_LINE) ){ return createUnCutCubeCap(volume, partial_build); } S32 num_vertices = 0, num_indices = 0; const std::vector& mesh = volume->getMesh(); const std::vector& profile = volume->getProfile().mProfile; // All types of caps have the same number of vertices and indices num_vertices = profile.size(); num_indices = (profile.size() - 2)*3; mVertices.resize(num_vertices); if (!partial_build) { mIndices.resize(num_indices); } S32 max_s = volume->getProfile().getTotal(); S32 max_t = volume->getPath().mPath.size(); mCenter.clearVec(); S32 offset = 0; if (mTypeMask & TOP_MASK) { offset = (max_t-1) * max_s; } else { offset = mBeginS; } // Figure out the normal, assume all caps are flat faces. // Cross product to get normals. LLVector2 cuv; LLVector2 min_uv, max_uv; LLVector3& min = mExtents[0]; LLVector3& max = mExtents[1]; // Copy the vertices into the array for (S32 i = 0; i < num_vertices; i++) { if (mTypeMask & TOP_MASK) { mVertices[i].mTexCoord.mV[0] = profile[i].mV[0]+0.5f; mVertices[i].mTexCoord.mV[1] = profile[i].mV[1]+0.5f; } else { // Mirror for underside. mVertices[i].mTexCoord.mV[0] = profile[i].mV[0]+0.5f; mVertices[i].mTexCoord.mV[1] = 0.5f - profile[i].mV[1]; } mVertices[i].mPosition = mesh[i + offset].mPos; if (i == 0) { min = max = mVertices[i].mPosition; min_uv = max_uv = mVertices[i].mTexCoord; } else { update_min_max(min,max, mVertices[i].mPosition); update_min_max(min_uv, max_uv, mVertices[i].mTexCoord); } } mCenter = (min+max)*0.5f; cuv = (min_uv + max_uv)*0.5f; LLVector3 binormal = calc_binormal_from_triangle( mCenter, cuv, mVertices[0].mPosition, mVertices[0].mTexCoord, mVertices[1].mPosition, mVertices[1].mTexCoord); binormal.normVec(); LLVector3 d0; LLVector3 d1; LLVector3 normal; d0 = mCenter-mVertices[0].mPosition; d1 = mCenter-mVertices[1].mPosition; normal = (mTypeMask & TOP_MASK) ? (d0%d1) : (d1%d0); normal.normVec(); VertexData vd; vd.mPosition = mCenter; vd.mNormal = normal; vd.mBinormal = binormal; vd.mTexCoord = cuv; if (!(mTypeMask & HOLLOW_MASK) && !(mTypeMask & OPEN_MASK)) { mVertices.push_back(vd); num_vertices++; if (!partial_build) { vector_append(mIndices, 3); } } for (S32 i = 0; i < num_vertices; i++) { mVertices[i].mBinormal = binormal; mVertices[i].mNormal = normal; } mHasBinormals = TRUE; if (partial_build) { return TRUE; } if (mTypeMask & HOLLOW_MASK) { if (mTypeMask & TOP_MASK) { // HOLLOW TOP // Does it matter if it's open or closed? - djs S32 pt1 = 0, pt2 = num_vertices - 1; S32 i = 0; while (pt2 - pt1 > 1) { // Use the profile points instead of the mesh, since you want // the un-transformed profile distances. LLVector3 p1 = profile[pt1]; LLVector3 p2 = profile[pt2]; LLVector3 pa = profile[pt1+1]; LLVector3 pb = profile[pt2-1]; p1.mV[VZ] = 0.f; p2.mV[VZ] = 0.f; pa.mV[VZ] = 0.f; pb.mV[VZ] = 0.f; // Use area of triangle to determine backfacing F32 area_1a2, area_1ba, area_21b, area_2ab; area_1a2 = (p1.mV[0]*pa.mV[1] - pa.mV[0]*p1.mV[1]) + (pa.mV[0]*p2.mV[1] - p2.mV[0]*pa.mV[1]) + (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]); area_1ba = (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*pa.mV[1] - pa.mV[0]*pb.mV[1]) + (pa.mV[0]*p1.mV[1] - p1.mV[0]*pa.mV[1]); area_21b = (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]) + (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); area_2ab = (p2.mV[0]*pa.mV[1] - pa.mV[0]*p2.mV[1]) + (pa.mV[0]*pb.mV[1] - pb.mV[0]*pa.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); BOOL use_tri1a2 = TRUE; BOOL tri_1a2 = TRUE; BOOL tri_21b = TRUE; if (area_1a2 < 0) { tri_1a2 = FALSE; } if (area_2ab < 0) { // Can't use, because it contains point b tri_1a2 = FALSE; } if (area_21b < 0) { tri_21b = FALSE; } if (area_1ba < 0) { // Can't use, because it contains point b tri_21b = FALSE; } if (!tri_1a2) { use_tri1a2 = FALSE; } else if (!tri_21b) { use_tri1a2 = TRUE; } else { LLVector3 d1 = p1 - pa; LLVector3 d2 = p2 - pb; if (d1.magVecSquared() < d2.magVecSquared()) { use_tri1a2 = TRUE; } else { use_tri1a2 = FALSE; } } if (use_tri1a2) { mIndices[i++] = pt1; mIndices[i++] = pt1 + 1; mIndices[i++] = pt2; pt1++; } else { mIndices[i++] = pt1; mIndices[i++] = pt2 - 1; mIndices[i++] = pt2; pt2--; } } } else { // HOLLOW BOTTOM // Does it matter if it's open or closed? - djs llassert(mTypeMask & BOTTOM_MASK); S32 pt1 = 0, pt2 = num_vertices - 1; S32 i = 0; while (pt2 - pt1 > 1) { // Use the profile points instead of the mesh, since you want // the un-transformed profile distances. LLVector3 p1 = profile[pt1]; LLVector3 p2 = profile[pt2]; LLVector3 pa = profile[pt1+1]; LLVector3 pb = profile[pt2-1]; p1.mV[VZ] = 0.f; p2.mV[VZ] = 0.f; pa.mV[VZ] = 0.f; pb.mV[VZ] = 0.f; // Use area of triangle to determine backfacing F32 area_1a2, area_1ba, area_21b, area_2ab; area_1a2 = (p1.mV[0]*pa.mV[1] - pa.mV[0]*p1.mV[1]) + (pa.mV[0]*p2.mV[1] - p2.mV[0]*pa.mV[1]) + (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]); area_1ba = (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*pa.mV[1] - pa.mV[0]*pb.mV[1]) + (pa.mV[0]*p1.mV[1] - p1.mV[0]*pa.mV[1]); area_21b = (p2.mV[0]*p1.mV[1] - p1.mV[0]*p2.mV[1]) + (p1.mV[0]*pb.mV[1] - pb.mV[0]*p1.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); area_2ab = (p2.mV[0]*pa.mV[1] - pa.mV[0]*p2.mV[1]) + (pa.mV[0]*pb.mV[1] - pb.mV[0]*pa.mV[1]) + (pb.mV[0]*p2.mV[1] - p2.mV[0]*pb.mV[1]); BOOL use_tri1a2 = TRUE; BOOL tri_1a2 = TRUE; BOOL tri_21b = TRUE; if (area_1a2 < 0) { tri_1a2 = FALSE; } if (area_2ab < 0) { // Can't use, because it contains point b tri_1a2 = FALSE; } if (area_21b < 0) { tri_21b = FALSE; } if (area_1ba < 0) { // Can't use, because it contains point b tri_21b = FALSE; } if (!tri_1a2) { use_tri1a2 = FALSE; } else if (!tri_21b) { use_tri1a2 = TRUE; } else { LLVector3 d1 = p1 - pa; LLVector3 d2 = p2 - pb; if (d1.magVecSquared() < d2.magVecSquared()) { use_tri1a2 = TRUE; } else { use_tri1a2 = FALSE; } } // Flipped backfacing from top if (use_tri1a2) { mIndices[i++] = pt1; mIndices[i++] = pt2; mIndices[i++] = pt1 + 1; pt1++; } else { mIndices[i++] = pt1; mIndices[i++] = pt2; mIndices[i++] = pt2 - 1; pt2--; } } } } else { // Not hollow, generate the triangle fan. if (mTypeMask & TOP_MASK) { if (mTypeMask & OPEN_MASK) { // SOLID OPEN TOP // Generate indices // This is a tri-fan, so we reuse the same first point for all triangles. for (S32 i = 0; i < (num_vertices - 2); i++) { mIndices[3*i] = num_vertices - 1; mIndices[3*i+1] = i; mIndices[3*i+2] = i + 1; } } else { // SOLID CLOSED TOP for (S32 i = 0; i < (num_vertices - 2); i++) { //MSMSM fix these caps but only for the un-cut case mIndices[3*i] = num_vertices - 1; mIndices[3*i+1] = i; mIndices[3*i+2] = i + 1; } } } else { if (mTypeMask & OPEN_MASK) { // SOLID OPEN BOTTOM // Generate indices // This is a tri-fan, so we reuse the same first point for all triangles. for (S32 i = 0; i < (num_vertices - 2); i++) { mIndices[3*i] = num_vertices - 1; mIndices[3*i+1] = i + 1; mIndices[3*i+2] = i; } } else { // SOLID CLOSED BOTTOM for (S32 i = 0; i < (num_vertices - 2); i++) { //MSMSM fix these caps but only for the un-cut case mIndices[3*i] = num_vertices - 1; mIndices[3*i+1] = i + 1; mIndices[3*i+2] = i; } } } } return TRUE; } void LLVolumeFace::createBinormals() { LLMemType m1(LLMemType::MTYPE_VOLUME); if (!mHasBinormals) { //generate binormals for (U32 i = 0; i < mIndices.size()/3; i++) { //for each triangle const VertexData& v0 = mVertices[mIndices[i*3+0]]; const VertexData& v1 = mVertices[mIndices[i*3+1]]; const VertexData& v2 = mVertices[mIndices[i*3+2]]; //calculate binormal LLVector3 binorm = calc_binormal_from_triangle(v0.mPosition, v0.mTexCoord, v1.mPosition, v1.mTexCoord, v2.mPosition, v2.mTexCoord); for (U32 j = 0; j < 3; j++) { //add triangle normal to vertices mVertices[mIndices[i*3+j]].mBinormal += binorm; // * (weight_sum - d[j])/weight_sum; } //even out quad contributions if (i % 2 == 0) { mVertices[mIndices[i*3+2]].mBinormal += binorm; } else { mVertices[mIndices[i*3+1]].mBinormal += binorm; } } //normalize binormals for (U32 i = 0; i < mVertices.size(); i++) { mVertices[i].mBinormal.normVec(); mVertices[i].mNormal.normVec(); } mHasBinormals = TRUE; } } BOOL LLVolumeFace::createSide(LLVolume* volume, BOOL partial_build) { LLMemType m1(LLMemType::MTYPE_VOLUME); BOOL flat = mTypeMask & FLAT_MASK; U8 sculpt_type = volume->getParams().getSculptType(); U8 sculpt_stitching = sculpt_type & LL_SCULPT_TYPE_MASK; BOOL sculpt_invert = sculpt_type & LL_SCULPT_FLAG_INVERT; BOOL sculpt_mirror = sculpt_type & LL_SCULPT_FLAG_MIRROR; BOOL sculpt_reverse_horizontal = (sculpt_invert ? !sculpt_mirror : sculpt_mirror); // XOR S32 num_vertices, num_indices; const std::vector& mesh = volume->getMesh(); const std::vector& profile = volume->getProfile().mProfile; const std::vector& path_data = volume->getPath().mPath; S32 max_s = volume->getProfile().getTotal(); S32 s, t, i; F32 ss, tt; num_vertices = mNumS*mNumT; num_indices = (mNumS-1)*(mNumT-1)*6; mVertices.resize(num_vertices); if (!partial_build) { mIndices.resize(num_indices); mEdge.resize(num_indices); } else { mHasBinormals = FALSE; } LLVector3& face_min = mExtents[0]; LLVector3& face_max = mExtents[1]; mCenter.clearVec(); S32 begin_stex = llfloor( profile[mBeginS].mV[2] ); S32 num_s = ((mTypeMask & INNER_MASK) && (mTypeMask & FLAT_MASK) && mNumS > 2) ? mNumS/2 : mNumS; S32 cur_vertex = 0; // Copy the vertices into the array for (t = mBeginT; t < mBeginT + mNumT; t++) { tt = path_data[t].mTexT; for (s = 0; s < num_s; s++) { if (mTypeMask & END_MASK) { if (s) { ss = 1.f; } else { ss = 0.f; } } else { // Get s value for tex-coord. if (!flat) { ss = profile[mBeginS + s].mV[2]; } else { ss = profile[mBeginS + s].mV[2] - begin_stex; } } if (sculpt_reverse_horizontal) { ss = 1.f - ss; } // Check to see if this triangle wraps around the array. if (mBeginS + s >= max_s) { // We're wrapping i = mBeginS + s + max_s*(t-1); } else { i = mBeginS + s + max_s*t; } mVertices[cur_vertex].mPosition = mesh[i].mPos; mVertices[cur_vertex].mTexCoord = LLVector2(ss,tt); mVertices[cur_vertex].mNormal = LLVector3(0,0,0); mVertices[cur_vertex].mBinormal = LLVector3(0,0,0); if (cur_vertex == 0) { face_min = face_max = mesh[i].mPos; } else { update_min_max(face_min, face_max, mesh[i].mPos); } cur_vertex++; if ((mTypeMask & INNER_MASK) && (mTypeMask & FLAT_MASK) && mNumS > 2 && s > 0) { mVertices[cur_vertex].mPosition = mesh[i].mPos; mVertices[cur_vertex].mTexCoord = LLVector2(ss,tt); mVertices[cur_vertex].mNormal = LLVector3(0,0,0); mVertices[cur_vertex].mBinormal = LLVector3(0,0,0); cur_vertex++; } } if ((mTypeMask & INNER_MASK) && (mTypeMask & FLAT_MASK) && mNumS > 2) { if (mTypeMask & OPEN_MASK) { s = num_s-1; } else { s = 0; } i = mBeginS + s + max_s*t; ss = profile[mBeginS + s].mV[2] - begin_stex; mVertices[cur_vertex].mPosition = mesh[i].mPos; mVertices[cur_vertex].mTexCoord = LLVector2(ss,tt); mVertices[cur_vertex].mNormal = LLVector3(0,0,0); mVertices[cur_vertex].mBinormal = LLVector3(0,0,0); update_min_max(face_min,face_max,mesh[i].mPos); cur_vertex++; } } mCenter = (face_min + face_max) * 0.5f; S32 cur_index = 0; S32 cur_edge = 0; BOOL flat_face = mTypeMask & FLAT_MASK; if (!partial_build) { // Now we generate the indices. for (t = 0; t < (mNumT-1); t++) { for (s = 0; s < (mNumS-1); s++) { mIndices[cur_index++] = s + mNumS*t; //bottom left mIndices[cur_index++] = s+1 + mNumS*(t+1); //top right mIndices[cur_index++] = s + mNumS*(t+1); //top left mIndices[cur_index++] = s + mNumS*t; //bottom left mIndices[cur_index++] = s+1 + mNumS*t; //bottom right mIndices[cur_index++] = s+1 + mNumS*(t+1); //top right mEdge[cur_edge++] = (mNumS-1)*2*t+s*2+1; //bottom left/top right neighbor face if (t < mNumT-2) { //top right/top left neighbor face mEdge[cur_edge++] = (mNumS-1)*2*(t+1)+s*2+1; } else if (mNumT <= 3 || volume->getPath().isOpen() == TRUE) { //no neighbor mEdge[cur_edge++] = -1; } else { //wrap on T mEdge[cur_edge++] = s*2+1; } if (s > 0) { //top left/bottom left neighbor face mEdge[cur_edge++] = (mNumS-1)*2*t+s*2-1; } else if (flat_face || volume->getProfile().isOpen() == TRUE) { //no neighbor mEdge[cur_edge++] = -1; } else { //wrap on S mEdge[cur_edge++] = (mNumS-1)*2*t+(mNumS-2)*2+1; } if (t > 0) { //bottom left/bottom right neighbor face mEdge[cur_edge++] = (mNumS-1)*2*(t-1)+s*2; } else if (mNumT <= 3 || volume->getPath().isOpen() == TRUE) { //no neighbor mEdge[cur_edge++] = -1; } else { //wrap on T mEdge[cur_edge++] = (mNumS-1)*2*(mNumT-2)+s*2; } if (s < mNumS-2) { //bottom right/top right neighbor face mEdge[cur_edge++] = (mNumS-1)*2*t+(s+1)*2; } else if (flat_face || volume->getProfile().isOpen() == TRUE) { //no neighbor mEdge[cur_edge++] = -1; } else { //wrap on S mEdge[cur_edge++] = (mNumS-1)*2*t; } mEdge[cur_edge++] = (mNumS-1)*2*t+s*2; //top right/bottom left neighbor face } } } //generate normals for (U32 i = 0; i < mIndices.size()/3; i++) //for each triangle { const S32 i0 = mIndices[i*3+0]; const S32 i1 = mIndices[i*3+1]; const S32 i2 = mIndices[i*3+2]; const VertexData& v0 = mVertices[i0]; const VertexData& v1 = mVertices[i1]; const VertexData& v2 = mVertices[i2]; //calculate triangle normal LLVector3 norm = (v0.mPosition-v1.mPosition) % (v0.mPosition-v2.mPosition); for (U32 j = 0; j < 3; j++) { //add triangle normal to vertices const S32 idx = mIndices[i*3+j]; mVertices[idx].mNormal += norm; // * (weight_sum - d[j])/weight_sum; } //even out quad contributions if ((i & 1) == 0) { mVertices[i2].mNormal += norm; } else { mVertices[i1].mNormal += norm; } } // adjust normals based on wrapping and stitching BOOL s_bottom_converges = ((mVertices[0].mPosition - mVertices[mNumS*(mNumT-2)].mPosition).magVecSquared() < 0.000001f); BOOL s_top_converges = ((mVertices[mNumS-1].mPosition - mVertices[mNumS*(mNumT-2)+mNumS-1].mPosition).magVecSquared() < 0.000001f); if (sculpt_stitching == LL_SCULPT_TYPE_NONE) // logic for non-sculpt volumes { if (volume->getPath().isOpen() == FALSE) { //wrap normals on T for (S32 i = 0; i < mNumS; i++) { LLVector3 norm = mVertices[i].mNormal + mVertices[mNumS*(mNumT-1)+i].mNormal; mVertices[i].mNormal = norm; mVertices[mNumS*(mNumT-1)+i].mNormal = norm; } } if ((volume->getProfile().isOpen() == FALSE) && !(s_bottom_converges)) { //wrap normals on S for (S32 i = 0; i < mNumT; i++) { LLVector3 norm = mVertices[mNumS*i].mNormal + mVertices[mNumS*i+mNumS-1].mNormal; mVertices[mNumS * i].mNormal = norm; mVertices[mNumS * i+mNumS-1].mNormal = norm; } } if (volume->getPathType() == LL_PCODE_PATH_CIRCLE && ((volume->getProfileType() & LL_PCODE_PROFILE_MASK) == LL_PCODE_PROFILE_CIRCLE_HALF)) { if (s_bottom_converges) { //all lower S have same normal for (S32 i = 0; i < mNumT; i++) { mVertices[mNumS*i].mNormal = LLVector3(1,0,0); } } if (s_top_converges) { //all upper S have same normal for (S32 i = 0; i < mNumT; i++) { mVertices[mNumS*i+mNumS-1].mNormal = LLVector3(-1,0,0); } } } } else // logic for sculpt volumes { BOOL average_poles = FALSE; BOOL wrap_s = FALSE; BOOL wrap_t = FALSE; if (sculpt_stitching == LL_SCULPT_TYPE_SPHERE) average_poles = TRUE; if ((sculpt_stitching == LL_SCULPT_TYPE_SPHERE) || (sculpt_stitching == LL_SCULPT_TYPE_TORUS) || (sculpt_stitching == LL_SCULPT_TYPE_CYLINDER)) wrap_s = TRUE; if (sculpt_stitching == LL_SCULPT_TYPE_TORUS) wrap_t = TRUE; if (average_poles) { // average normals for north pole LLVector3 average(0.0, 0.0, 0.0); for (S32 i = 0; i < mNumS; i++) { average += mVertices[i].mNormal; } // set average for (S32 i = 0; i < mNumS; i++) { mVertices[i].mNormal = average; } // average normals for south pole average = LLVector3(0.0, 0.0, 0.0); for (S32 i = 0; i < mNumS; i++) { average += mVertices[i + mNumS * (mNumT - 1)].mNormal; } // set average for (S32 i = 0; i < mNumS; i++) { mVertices[i + mNumS * (mNumT - 1)].mNormal = average; } } if (wrap_s) { for (S32 i = 0; i < mNumT; i++) { LLVector3 norm = mVertices[mNumS*i].mNormal + mVertices[mNumS*i+mNumS-1].mNormal; mVertices[mNumS * i].mNormal = norm; mVertices[mNumS * i+mNumS-1].mNormal = norm; } } if (wrap_t) { for (S32 i = 0; i < mNumS; i++) { LLVector3 norm = mVertices[i].mNormal + mVertices[mNumS*(mNumT-1)+i].mNormal; mVertices[i].mNormal = norm; mVertices[mNumS*(mNumT-1)+i].mNormal = norm; } } } return TRUE; } // Finds binormal based on three vertices with texture coordinates. // Fills in dummy values if the triangle has degenerate texture coordinates. LLVector3 calc_binormal_from_triangle( const LLVector3& pos0, const LLVector2& tex0, const LLVector3& pos1, const LLVector2& tex1, const LLVector3& pos2, const LLVector2& tex2) { LLVector3 rx0( pos0.mV[VX], tex0.mV[VX], tex0.mV[VY] ); LLVector3 rx1( pos1.mV[VX], tex1.mV[VX], tex1.mV[VY] ); LLVector3 rx2( pos2.mV[VX], tex2.mV[VX], tex2.mV[VY] ); LLVector3 ry0( pos0.mV[VY], tex0.mV[VX], tex0.mV[VY] ); LLVector3 ry1( pos1.mV[VY], tex1.mV[VX], tex1.mV[VY] ); LLVector3 ry2( pos2.mV[VY], tex2.mV[VX], tex2.mV[VY] ); LLVector3 rz0( pos0.mV[VZ], tex0.mV[VX], tex0.mV[VY] ); LLVector3 rz1( pos1.mV[VZ], tex1.mV[VX], tex1.mV[VY] ); LLVector3 rz2( pos2.mV[VZ], tex2.mV[VX], tex2.mV[VY] ); LLVector3 r0 = (rx0 - rx1) % (rx0 - rx2); LLVector3 r1 = (ry0 - ry1) % (ry0 - ry2); LLVector3 r2 = (rz0 - rz1) % (rz0 - rz2); if( r0.mV[VX] && r1.mV[VX] && r2.mV[VX] ) { LLVector3 binormal( -r0.mV[VZ] / r0.mV[VX], -r1.mV[VZ] / r1.mV[VX], -r2.mV[VZ] / r2.mV[VX]); // binormal.normVec(); return binormal; } else { return LLVector3( 0, 1 , 0 ); } }