/* =========================================================================== Doom 3 BFG Edition GPL Source Code Copyright (C) 1993-2012 id Software LLC, a ZeniMax Media company. This file is part of the Doom 3 BFG Edition GPL Source Code ("Doom 3 BFG Edition Source Code"). Doom 3 BFG Edition Source Code is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. Doom 3 BFG Edition Source Code is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with Doom 3 BFG Edition Source Code. If not, see . In addition, the Doom 3 BFG Edition Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 BFG Edition Source Code. If not, please request a copy in writing from id Software at the address below. If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA. =========================================================================== */ #pragma hdrstop #include "../idlib/precompiled.h" #include "tr_local.h" #include "Model_local.h" static const __m128 vector_float_posInfinity = { idMath::INFINITY, idMath::INFINITY, idMath::INFINITY, idMath::INFINITY }; static const __m128 vector_float_negInfinity = { -idMath::INFINITY, -idMath::INFINITY, -idMath::INFINITY, -idMath::INFINITY }; static const char *MD5_SnapshotName = "_MD5_Snapshot_"; static const byte MD5B_VERSION = 106; static const unsigned int MD5B_MAGIC = ( '5' << 24 ) | ( 'D' << 16 ) | ( 'M' << 8 ) | MD5B_VERSION; idCVar r_useGPUSkinning( "r_useGPUSkinning", "1", CVAR_INTEGER, "animate normals and tangents instead of deriving" ); /*********************************************************************** idMD5Mesh ***********************************************************************/ static int c_numVerts = 0; static int c_numWeights = 0; static int c_numWeightJoints = 0; struct vertexWeight_t { int joint; idVec3 offset; float jointWeight; }; /* ==================== idMD5Mesh::idMD5Mesh ==================== */ idMD5Mesh::idMD5Mesh() { shader = NULL; numVerts = 0; numTris = 0; meshJoints = NULL; numMeshJoints = 0; maxJointVertDist = 0.0f; deformInfo = NULL; surfaceNum = 0; } /* ==================== idMD5Mesh::~idMD5Mesh ==================== */ idMD5Mesh::~idMD5Mesh() { if ( meshJoints != NULL ) { Mem_Free( meshJoints ); meshJoints = NULL; } if ( deformInfo != NULL ) { R_FreeDeformInfo( deformInfo ); deformInfo = NULL; } } /* ==================== idMD5Mesh::ParseMesh ==================== */ void idMD5Mesh::ParseMesh( idLexer &parser, int numJoints, const idJointMat *joints ) { idToken token; idToken name; parser.ExpectTokenString( "{" ); // // parse name // if ( parser.CheckTokenString( "name" ) ) { parser.ReadToken( &name ); } // // parse shader // parser.ExpectTokenString( "shader" ); parser.ReadToken( &token ); idStr shaderName = token; shader = declManager->FindMaterial( shaderName ); // // parse texture coordinates // parser.ExpectTokenString( "numverts" ); int count = parser.ParseInt(); if ( count < 0 ) { parser.Error( "Invalid size: %s", token.c_str() ); } this->numVerts = count; idList texCoords; idList firstWeightForVertex; idList numWeightsForVertex; texCoords.SetNum( count ); firstWeightForVertex.SetNum( count ); numWeightsForVertex.SetNum( count ); int numWeights = 0; int maxweight = 0; for ( int i = 0; i < texCoords.Num(); i++ ) { parser.ExpectTokenString( "vert" ); parser.ParseInt(); parser.Parse1DMatrix( 2, texCoords[ i ].ToFloatPtr() ); firstWeightForVertex[ i ] = parser.ParseInt(); numWeightsForVertex[ i ] = parser.ParseInt(); if ( !numWeightsForVertex[ i ] ) { parser.Error( "Vertex without any joint weights." ); } numWeights += numWeightsForVertex[ i ]; if ( numWeightsForVertex[ i ] + firstWeightForVertex[ i ] > maxweight ) { maxweight = numWeightsForVertex[ i ] + firstWeightForVertex[ i ]; } } // // parse tris // parser.ExpectTokenString( "numtris" ); count = parser.ParseInt(); if ( count < 0 ) { parser.Error( "Invalid size: %d", count ); } idList tris; tris.SetNum( count * 3 ); numTris = count; for ( int i = 0; i < count; i++ ) { parser.ExpectTokenString( "tri" ); parser.ParseInt(); tris[ i * 3 + 0 ] = parser.ParseInt(); tris[ i * 3 + 1 ] = parser.ParseInt(); tris[ i * 3 + 2 ] = parser.ParseInt(); } // // parse weights // parser.ExpectTokenString( "numweights" ); count = parser.ParseInt(); if ( count < 0 ) { parser.Error( "Invalid size: %d", count ); } if ( maxweight > count ) { parser.Warning( "Vertices reference out of range weights in model (%d of %d weights).", maxweight, count ); } idList tempWeights; tempWeights.SetNum( count ); assert( numJoints < 256 ); // so we can pack into bytes for ( int i = 0; i < count; i++ ) { parser.ExpectTokenString( "weight" ); parser.ParseInt(); int jointnum = parser.ParseInt(); if ( ( jointnum < 0 ) || ( jointnum >= numJoints ) ) { parser.Error( "Joint Index out of range(%d): %d", numJoints, jointnum ); } tempWeights[ i ].joint = jointnum; tempWeights[ i ].jointWeight = parser.ParseFloat(); parser.Parse1DMatrix( 3, tempWeights[ i ].offset.ToFloatPtr() ); } // create pre-scaled weights and an index for the vertex/joint lookup idVec4 * scaledWeights = (idVec4 *) Mem_Alloc16( numWeights * sizeof( scaledWeights[0] ), TAG_MD5_WEIGHT ); int * weightIndex = (int *) Mem_Alloc16( numWeights * 2 * sizeof( weightIndex[0] ), TAG_MD5_INDEX ); memset( weightIndex, 0, numWeights * 2 * sizeof( weightIndex[0] ) ); count = 0; for ( int i = 0; i < texCoords.Num(); i++ ) { int num = firstWeightForVertex[i]; for( int j = 0; j < numWeightsForVertex[i]; j++, num++, count++ ) { scaledWeights[count].ToVec3() = tempWeights[num].offset * tempWeights[num].jointWeight; scaledWeights[count].w = tempWeights[num].jointWeight; weightIndex[count * 2 + 0] = tempWeights[num].joint * sizeof( idJointMat ); } weightIndex[count * 2 - 1] = 1; } parser.ExpectTokenString( "}" ); // update counters c_numVerts += texCoords.Num(); c_numWeights += numWeights; c_numWeightJoints++; for ( int i = 0; i < numWeights; i++ ) { c_numWeightJoints += weightIndex[i*2+1]; } // // build a base pose that can be used for skinning // idDrawVert * basePose = (idDrawVert *)Mem_ClearedAlloc( texCoords.Num() * sizeof( *basePose ), TAG_MD5_BASE ); for( int j = 0, i = 0; i < texCoords.Num(); i++ ) { idVec3 v = ( *(idJointMat *) ( (byte *)joints + weightIndex[j*2+0] ) ) * scaledWeights[j]; while( weightIndex[j*2+1] == 0 ) { j++; v += ( *(idJointMat *) ( (byte *)joints + weightIndex[j*2+0] ) ) * scaledWeights[j]; } j++; basePose[i].Clear(); basePose[i].xyz = v; basePose[i].SetTexCoord( texCoords[i] ); } // build the weights and bone indexes into the verts, so they will be duplicated // as necessary at mirror seems static int maxWeightsPerVert; static float maxResidualWeight; const int MAX_VERTEX_WEIGHTS = 4; idList< bool > jointIsUsed; jointIsUsed.SetNum( numJoints ); for ( int i = 0; i < jointIsUsed.Num(); i++ ) { jointIsUsed[i] = false; } numMeshJoints = 0; maxJointVertDist = 0.0f; //----------------------------------------- // new-style setup for fixed four weights and normal / tangent deformation // // Several important models have >25% residual weight in joints after the // first four, which is worrisome for using a fixed four joint deformation. //----------------------------------------- for ( int i = 0; i < texCoords.Num(); i++ ) { idDrawVert & dv = basePose[i]; // some models do have >4 joint weights, so it is necessary to sort and renormalize // sort the weights and take the four largest int weights[256]; const int numWeights = numWeightsForVertex[ i ]; for ( int j = 0; j < numWeights; j++ ) { weights[j] = firstWeightForVertex[i] + j; } // bubble sort for ( int j = 0; j < numWeights; j++ ) { for ( int k = 0; k < numWeights - 1 - j; k++ ) { if ( tempWeights[weights[k]].jointWeight < tempWeights[weights[k+1]].jointWeight ) { SwapValues( weights[k], weights[k+1] ); } } } if ( numWeights > maxWeightsPerVert ) { maxWeightsPerVert = numWeights; } const int usedWeights = Min( MAX_VERTEX_WEIGHTS, numWeights ); float totalWeight = 0; for ( int j = 0; j < numWeights; j++ ) { totalWeight += tempWeights[weights[j]].jointWeight; } assert( totalWeight > 0.999f && totalWeight < 1.001f ); float usedWeight = 0; for ( int j = 0; j < usedWeights; j++ ) { usedWeight += tempWeights[weights[j]].jointWeight; } const float residualWeight = totalWeight - usedWeight; if ( residualWeight > maxResidualWeight ) { maxResidualWeight = residualWeight; } byte finalWeights[MAX_VERTEX_WEIGHTS] = { 0 }; byte finalJointIndecies[MAX_VERTEX_WEIGHTS] = { 0 }; for ( int j = 0; j < usedWeights; j++ ) { const vertexWeight_t & weight = tempWeights[weights[j]]; const int jointIndex = weight.joint; const float fw = weight.jointWeight; assert( fw >= 0.0f && fw <= 1.0f ); const float normalizedWeight = fw / usedWeight; finalWeights[j] = idMath::Ftob( normalizedWeight * 255.0f); finalJointIndecies[j] = jointIndex; } // Sort the weights and indices for hardware skinning for ( int k = 0; k < 3; ++k ) { for ( int l = k + 1; l < 4; ++l ) { if ( finalWeights[l] > finalWeights[k] ) { SwapValues( finalWeights[k], finalWeights[l] ); SwapValues( finalJointIndecies[k], finalJointIndecies[l] ); } } } // Give any left over to the biggest weight finalWeights[0] += Max( 255 - finalWeights[0] - finalWeights[1] - finalWeights[2] - finalWeights[3], 0 ); dv.color[0] = finalJointIndecies[0]; dv.color[1] = finalJointIndecies[1]; dv.color[2] = finalJointIndecies[2]; dv.color[3] = finalJointIndecies[3]; dv.color2[0] = finalWeights[0]; dv.color2[1] = finalWeights[1]; dv.color2[2] = finalWeights[2]; dv.color2[3] = finalWeights[3]; for ( int j = usedWeights; j < 4; j++ ) { assert( dv.color2[j] == 0 ); } for ( int j = 0; j < usedWeights; j++ ) { if ( !jointIsUsed[finalJointIndecies[j]] ) { jointIsUsed[finalJointIndecies[j]] = true; numMeshJoints++; } const idJointMat & joint = joints[finalJointIndecies[j]]; float dist = ( dv.xyz - joint.GetTranslation() ).Length(); if ( dist > maxJointVertDist ) { maxJointVertDist = dist; } } } meshJoints = (byte *) Mem_Alloc( numMeshJoints * sizeof( meshJoints[0] ), TAG_MODEL ); numMeshJoints = 0; for ( int i = 0; i < numJoints; i++ ) { if ( jointIsUsed[i] ) { meshJoints[numMeshJoints++] = i; } } // build the deformInfo and collect a final base pose with the mirror // seam verts properly including the bone weights deformInfo = R_BuildDeformInfo( texCoords.Num(), basePose, tris.Num(), tris.Ptr(), shader->UseUnsmoothedTangents() ); for ( int i = 0; i < deformInfo->numOutputVerts; i++ ) { for ( int j = 0; j < 4; j++ ) { if ( deformInfo->verts[i].color[j] >= numJoints ) { idLib::FatalError( "Bad joint index" ); } } } Mem_Free( basePose ); } /* ============ TransformVertsAndTangents ============ */ void TransformVertsAndTangents( idDrawVert * targetVerts, const int numVerts, const idDrawVert *baseVerts, const idJointMat *joints ) { for( int i = 0; i < numVerts; i++ ) { const idDrawVert & base = baseVerts[i]; const idJointMat & j0 = joints[base.color[0]]; const idJointMat & j1 = joints[base.color[1]]; const idJointMat & j2 = joints[base.color[2]]; const idJointMat & j3 = joints[base.color[3]]; const float w0 = base.color2[0] * ( 1.0f / 255.0f ); const float w1 = base.color2[1] * ( 1.0f / 255.0f ); const float w2 = base.color2[2] * ( 1.0f / 255.0f ); const float w3 = base.color2[3] * ( 1.0f / 255.0f ); idJointMat accum; idJointMat::Mul( accum, j0, w0 ); idJointMat::Mad( accum, j1, w1 ); idJointMat::Mad( accum, j2, w2 ); idJointMat::Mad( accum, j3, w3 ); targetVerts[i].xyz = accum * idVec4( base.xyz.x, base.xyz.y, base.xyz.z, 1.0f ); targetVerts[i].SetNormal( accum * base.GetNormal() ); targetVerts[i].SetTangent( accum * base.GetTangent() ); targetVerts[i].tangent[3] = base.tangent[3]; } } /* ==================== idMD5Mesh::UpdateSurface ==================== */ void idMD5Mesh::UpdateSurface( const struct renderEntity_s *ent, const idJointMat *entJoints, const idJointMat *entJointsInverted, modelSurface_t *surf ) { tr.pc.c_deformedSurfaces++; tr.pc.c_deformedVerts += deformInfo->numOutputVerts; tr.pc.c_deformedIndexes += deformInfo->numIndexes; surf->shader = shader; if ( surf->geometry != NULL ) { // if the number of verts and indexes are the same we can re-use the triangle surface if ( surf->geometry->numVerts == deformInfo->numOutputVerts && surf->geometry->numIndexes == deformInfo->numIndexes ) { R_FreeStaticTriSurfVertexCaches( surf->geometry ); } else { R_FreeStaticTriSurf( surf->geometry ); surf->geometry = R_AllocStaticTriSurf(); } } else { surf->geometry = R_AllocStaticTriSurf(); } srfTriangles_t * tri = surf->geometry; // note that some of the data is referenced, and should not be freed tri->referencedIndexes = true; tri->numIndexes = deformInfo->numIndexes; tri->indexes = deformInfo->indexes; tri->silIndexes = deformInfo->silIndexes; tri->numMirroredVerts = deformInfo->numMirroredVerts; tri->mirroredVerts = deformInfo->mirroredVerts; tri->numDupVerts = deformInfo->numDupVerts; tri->dupVerts = deformInfo->dupVerts; tri->numSilEdges = deformInfo->numSilEdges; tri->silEdges = deformInfo->silEdges; tri->indexCache = deformInfo->staticIndexCache; tri->numVerts = deformInfo->numOutputVerts; if ( r_useGPUSkinning.GetBool() ) { if ( tri->verts != NULL && tri->verts != deformInfo->verts ) { R_FreeStaticTriSurfVerts( tri ); } tri->verts = deformInfo->verts; tri->ambientCache = deformInfo->staticAmbientCache; tri->shadowCache = deformInfo->staticShadowCache; tri->referencedVerts = true; } else { if ( tri->verts == NULL || tri->verts == deformInfo->verts ) { tri->verts = NULL; R_AllocStaticTriSurfVerts( tri, deformInfo->numOutputVerts ); assert( tri->verts != NULL ); // quiet analyze warning memcpy( tri->verts, deformInfo->verts, deformInfo->numOutputVerts * sizeof( deformInfo->verts[0] ) ); // copy over the texture coordinates } TransformVertsAndTangents( tri->verts, deformInfo->numOutputVerts, deformInfo->verts, entJointsInverted ); tri->referencedVerts = false; } tri->tangentsCalculated = true; CalculateBounds( entJoints, tri->bounds ); } /* ==================== idMD5Mesh::CalculateBounds ==================== */ void idMD5Mesh::CalculateBounds( const idJointMat * entJoints, idBounds & bounds ) const { __m128 minX = vector_float_posInfinity; __m128 minY = vector_float_posInfinity; __m128 minZ = vector_float_posInfinity; __m128 maxX = vector_float_negInfinity; __m128 maxY = vector_float_negInfinity; __m128 maxZ = vector_float_negInfinity; for ( int i = 0; i < numMeshJoints; i++ ) { const idJointMat & joint = entJoints[meshJoints[i]]; __m128 x = _mm_load_ps( joint.ToFloatPtr() + 0 * 4 ); __m128 y = _mm_load_ps( joint.ToFloatPtr() + 1 * 4 ); __m128 z = _mm_load_ps( joint.ToFloatPtr() + 2 * 4 ); minX = _mm_min_ps( minX, x ); minY = _mm_min_ps( minY, y ); minZ = _mm_min_ps( minZ, z ); maxX = _mm_max_ps( maxX, x ); maxY = _mm_max_ps( maxY, y ); maxZ = _mm_max_ps( maxZ, z ); } __m128 expand = _mm_splat_ps( _mm_load_ss( & maxJointVertDist ), 0 ); minX = _mm_sub_ps( minX, expand ); minY = _mm_sub_ps( minY, expand ); minZ = _mm_sub_ps( minZ, expand ); maxX = _mm_add_ps( maxX, expand ); maxY = _mm_add_ps( maxY, expand ); maxZ = _mm_add_ps( maxZ, expand ); _mm_store_ss( bounds.ToFloatPtr() + 0, _mm_splat_ps( minX, 3 ) ); _mm_store_ss( bounds.ToFloatPtr() + 1, _mm_splat_ps( minY, 3 ) ); _mm_store_ss( bounds.ToFloatPtr() + 2, _mm_splat_ps( minZ, 3 ) ); _mm_store_ss( bounds.ToFloatPtr() + 3, _mm_splat_ps( maxX, 3 ) ); _mm_store_ss( bounds.ToFloatPtr() + 4, _mm_splat_ps( maxY, 3 ) ); _mm_store_ss( bounds.ToFloatPtr() + 5, _mm_splat_ps( maxZ, 3 ) ); } /* ==================== idMD5Mesh::NearestJoint ==================== */ int idMD5Mesh::NearestJoint( int a, int b, int c ) const { // duplicated vertices might not have weights int vertNum; if ( a >= 0 && a < numVerts ) { vertNum = a; } else if ( b >= 0 && b < numVerts ) { vertNum = b; } else if ( c >= 0 && c < numVerts ) { vertNum = c; } else { // all vertices are duplicates which shouldn't happen return 0; } const idDrawVert & v = deformInfo->verts[vertNum]; int bestWeight = 0; int bestJoint = 0; for ( int i = 0; i < 4; i++ ) { if ( v.color2[i] > bestWeight ) { bestWeight = v.color2[i]; bestJoint = v.color[i]; } } return bestJoint; } /*********************************************************************** idRenderModelMD5 ***********************************************************************/ /* ==================== idRenderModelMD5::ParseJoint ==================== */ void idRenderModelMD5::ParseJoint( idLexer &parser, idMD5Joint *joint, idJointQuat *defaultPose ) { // // parse name // idToken token; parser.ReadToken( &token ); joint->name = token; // // parse parent // int num = parser.ParseInt(); if ( num < 0 ) { joint->parent = NULL; } else { if ( num >= joints.Num() - 1 ) { parser.Error( "Invalid parent for joint '%s'", joint->name.c_str() ); } joint->parent = &joints[ num ]; } // // parse default pose // parser.Parse1DMatrix( 3, defaultPose->t.ToFloatPtr() ); parser.Parse1DMatrix( 3, defaultPose->q.ToFloatPtr() ); defaultPose->q.w = defaultPose->q.CalcW(); } /* ==================== idRenderModelMD5::InitFromFile ==================== */ void idRenderModelMD5::InitFromFile( const char *fileName ) { name = fileName; LoadModel(); } /* ======================== idRenderModelMD5::LoadBinaryModel ======================== */ bool idRenderModelMD5::LoadBinaryModel( idFile * file, const ID_TIME_T sourceTimeStamp ) { if ( !idRenderModelStatic::LoadBinaryModel( file, sourceTimeStamp ) ) { return false; } unsigned int magic = 0; file->ReadBig( magic ); if ( magic != MD5B_MAGIC ) { return false; } int tempNum; file->ReadBig( tempNum ); joints.SetNum( tempNum ); for ( int i = 0; i < joints.Num(); i++ ) { file->ReadString( joints[i].name ); int offset; file->ReadBig( offset ); if ( offset >= 0 ) { joints[i].parent = joints.Ptr() + offset; } else { joints[i].parent = NULL; } } file->ReadBig( tempNum ); defaultPose.SetNum( tempNum ); for ( int i = 0; i < defaultPose.Num(); i++ ) { file->ReadBig( defaultPose[i].q.x ); file->ReadBig( defaultPose[i].q.y ); file->ReadBig( defaultPose[i].q.z ); file->ReadBig( defaultPose[i].q.w ); file->ReadVec3( defaultPose[i].t ); } file->ReadBig( tempNum ); invertedDefaultPose.SetNum( tempNum ); for ( int i = 0; i < invertedDefaultPose.Num(); i++ ) { file->ReadBigArray( invertedDefaultPose[ i ].ToFloatPtr(), JOINTMAT_TYPESIZE ); } SIMD_INIT_LAST_JOINT( invertedDefaultPose.Ptr(), joints.Num() ); file->ReadBig( tempNum ); meshes.SetNum( tempNum ); for ( int i = 0; i < meshes.Num(); i++ ) { idStr materialName; file->ReadString( materialName ); if ( materialName.IsEmpty() ) { meshes[i].shader = NULL; } else { meshes[i].shader = declManager->FindMaterial( materialName ); } file->ReadBig( meshes[i].numVerts ); file->ReadBig( meshes[i].numTris ); file->ReadBig( meshes[i].numMeshJoints ); meshes[i].meshJoints = (byte *) Mem_Alloc( meshes[i].numMeshJoints * sizeof( meshes[i].meshJoints[0] ), TAG_MODEL ); file->ReadBigArray( meshes[i].meshJoints, meshes[i].numMeshJoints ); file->ReadBig( meshes[i].maxJointVertDist ); meshes[i].deformInfo = (deformInfo_t *)R_ClearedStaticAlloc( sizeof( deformInfo_t ) ); deformInfo_t & deform = *meshes[i].deformInfo; file->ReadBig( deform.numSourceVerts ); file->ReadBig( deform.numOutputVerts ); file->ReadBig( deform.numIndexes ); file->ReadBig( deform.numMirroredVerts ); file->ReadBig( deform.numDupVerts ); file->ReadBig( deform.numSilEdges ); srfTriangles_t tri; memset( &tri, 0, sizeof( srfTriangles_t ) ); if ( deform.numOutputVerts > 0 ) { R_AllocStaticTriSurfVerts( &tri, deform.numOutputVerts ); deform.verts = tri.verts; file->ReadBigArray( deform.verts, deform.numOutputVerts ); } if ( deform.numIndexes > 0 ) { R_AllocStaticTriSurfIndexes( &tri, deform.numIndexes ); R_AllocStaticTriSurfSilIndexes( &tri, deform.numIndexes ); deform.indexes = tri.indexes; deform.silIndexes = tri.silIndexes; file->ReadBigArray( deform.indexes, deform.numIndexes ); file->ReadBigArray( deform.silIndexes, deform.numIndexes ); } if ( deform.numMirroredVerts > 0 ) { R_AllocStaticTriSurfMirroredVerts( &tri, deform.numMirroredVerts ); deform.mirroredVerts = tri.mirroredVerts; file->ReadBigArray( deform.mirroredVerts, deform.numMirroredVerts ); } if ( deform.numDupVerts > 0 ) { R_AllocStaticTriSurfDupVerts( &tri, deform.numDupVerts ); deform.dupVerts = tri.dupVerts; file->ReadBigArray( deform.dupVerts, deform.numDupVerts * 2 ); } if ( deform.numSilEdges > 0 ) { R_AllocStaticTriSurfSilEdges( &tri, deform.numSilEdges ); deform.silEdges = tri.silEdges; assert( deform.silEdges != NULL ); for ( int j = 0; j < deform.numSilEdges; j++ ) { file->ReadBig( deform.silEdges[j].p1 ); file->ReadBig( deform.silEdges[j].p2 ); file->ReadBig( deform.silEdges[j].v1 ); file->ReadBig( deform.silEdges[j].v2 ); } } idShadowVertSkinned * shadowVerts = (idShadowVertSkinned *) Mem_Alloc( ALIGN( deform.numOutputVerts * 2 * sizeof( idShadowVertSkinned ), 16 ), TAG_MODEL ); idShadowVertSkinned::CreateShadowCache( shadowVerts, deform.verts, deform.numOutputVerts ); deform.staticAmbientCache = vertexCache.AllocStaticVertex( deform.verts, ALIGN( deform.numOutputVerts * sizeof( idDrawVert ), VERTEX_CACHE_ALIGN ) ); deform.staticIndexCache = vertexCache.AllocStaticIndex( deform.indexes, ALIGN( deform.numIndexes * sizeof( triIndex_t ), INDEX_CACHE_ALIGN ) ); deform.staticShadowCache = vertexCache.AllocStaticVertex( shadowVerts, ALIGN( deform.numOutputVerts * 2 * sizeof( idShadowVertSkinned ), VERTEX_CACHE_ALIGN ) ); Mem_Free( shadowVerts ); file->ReadBig( meshes[i].surfaceNum ); } return true; } /* ======================== idRenderModelMD5::WriteBinaryModel ======================== */ void idRenderModelMD5::WriteBinaryModel( idFile * file, ID_TIME_T *_timeStamp ) const { idRenderModelStatic::WriteBinaryModel( file ); if ( file == NULL ) { return; } file->WriteBig( MD5B_MAGIC ); file->WriteBig( joints.Num() ); for ( int i = 0; i < joints.Num(); i++ ) { file->WriteString( joints[i].name ); int offset = -1; if ( joints[i].parent != NULL ) { offset = joints[i].parent - joints.Ptr(); } file->WriteBig( offset ); } file->WriteBig( defaultPose.Num() ); for ( int i = 0; i < defaultPose.Num(); i++ ) { file->WriteBig( defaultPose[i].q.x ); file->WriteBig( defaultPose[i].q.y ); file->WriteBig( defaultPose[i].q.z ); file->WriteBig( defaultPose[i].q.w ); file->WriteVec3( defaultPose[i].t ); } file->WriteBig( invertedDefaultPose.Num() ); for ( int i = 0; i < invertedDefaultPose.Num(); i++ ) { file->WriteBigArray( invertedDefaultPose[ i ].ToFloatPtr(), JOINTMAT_TYPESIZE ); } file->WriteBig( meshes.Num() ); for ( int i = 0; i < meshes.Num(); i++ ) { if ( meshes[i].shader != NULL && meshes[i].shader->GetName() != NULL ) { file->WriteString( meshes[i].shader->GetName() ); } else { file->WriteString( "" ); } file->WriteBig( meshes[i].numVerts ); file->WriteBig( meshes[i].numTris ); file->WriteBig( meshes[i].numMeshJoints ); file->WriteBigArray( meshes[i].meshJoints, meshes[i].numMeshJoints ); file->WriteBig( meshes[i].maxJointVertDist ); deformInfo_t & deform = *meshes[i].deformInfo; file->WriteBig( deform.numSourceVerts ); file->WriteBig( deform.numOutputVerts ); file->WriteBig( deform.numIndexes ); file->WriteBig( deform.numMirroredVerts ); file->WriteBig( deform.numDupVerts ); file->WriteBig( deform.numSilEdges ); if ( deform.numOutputVerts > 0 ) { file->WriteBigArray( deform.verts, deform.numOutputVerts ); } if ( deform.numIndexes > 0 ) { file->WriteBigArray( deform.indexes, deform.numIndexes ); file->WriteBigArray( deform.silIndexes, deform.numIndexes ); } if ( deform.numMirroredVerts > 0 ) { file->WriteBigArray( deform.mirroredVerts, deform.numMirroredVerts ); } if ( deform.numDupVerts > 0 ) { file->WriteBigArray( deform.dupVerts, deform.numDupVerts * 2 ); } if ( deform.numSilEdges > 0 ) { for ( int j = 0; j < deform.numSilEdges; j++ ) { file->WriteBig( deform.silEdges[j].p1 ); file->WriteBig( deform.silEdges[j].p2 ); file->WriteBig( deform.silEdges[j].v1 ); file->WriteBig( deform.silEdges[j].v2 ); } } file->WriteBig( meshes[i].surfaceNum ); } } /* ==================== idRenderModelMD5::LoadModel used for initial loads, reloadModel, and reloading the data of purged models Upon exit, the model will absolutely be valid, but possibly as a default model ==================== */ void idRenderModelMD5::LoadModel() { int version; int num; int parentNum; idToken token; idLexer parser( LEXFL_ALLOWPATHNAMES | LEXFL_NOSTRINGESCAPECHARS ); if ( !purged ) { PurgeModel(); } purged = false; if ( !parser.LoadFile( name ) ) { MakeDefaultModel(); return; } parser.ExpectTokenString( MD5_VERSION_STRING ); version = parser.ParseInt(); if ( version != MD5_VERSION ) { parser.Error( "Invalid version %d. Should be version %d\n", version, MD5_VERSION ); } // // skip commandline // parser.ExpectTokenString( "commandline" ); parser.ReadToken( &token ); // parse num joints parser.ExpectTokenString( "numJoints" ); num = parser.ParseInt(); joints.SetGranularity( 1 ); joints.SetNum( num ); defaultPose.SetGranularity( 1 ); defaultPose.SetNum( num ); // parse num meshes parser.ExpectTokenString( "numMeshes" ); num = parser.ParseInt(); if ( num < 0 ) { parser.Error( "Invalid size: %d", num ); } meshes.SetGranularity( 1 ); meshes.SetNum( num ); // // parse joints // parser.ExpectTokenString( "joints" ); parser.ExpectTokenString( "{" ); idJointMat *poseMat = ( idJointMat * )_alloca16( joints.Num() * sizeof( poseMat[0] ) ); for( int i = 0; i < joints.Num(); i++ ) { idMD5Joint * joint = &joints[i]; idJointQuat * pose = &defaultPose[i]; ParseJoint( parser, joint, pose ); poseMat[ i ].SetRotation( pose->q.ToMat3() ); poseMat[ i ].SetTranslation( pose->t ); if ( joint->parent ) { parentNum = joint->parent - joints.Ptr(); pose->q = ( poseMat[ i ].ToMat3() * poseMat[ parentNum ].ToMat3().Transpose() ).ToQuat(); pose->t = ( poseMat[ i ].ToVec3() - poseMat[ parentNum ].ToVec3() ) * poseMat[ parentNum ].ToMat3().Transpose(); } } parser.ExpectTokenString( "}" ); //----------------------------------------- // create the inverse of the base pose joints to support tech6 style deformation // of base pose vertexes, normals, and tangents. // // vertex * joints * inverseJoints == vertex when joints is the base pose // When the joints are in another pose, it gives the animated vertex position //----------------------------------------- invertedDefaultPose.SetNum( SIMD_ROUND_JOINTS( joints.Num() ) ); for ( int i = 0; i < joints.Num(); i++ ) { invertedDefaultPose[i] = poseMat[i]; invertedDefaultPose[i].Invert(); } SIMD_INIT_LAST_JOINT( invertedDefaultPose.Ptr(), joints.Num() ); for ( int i = 0; i < meshes.Num(); i++ ) { parser.ExpectTokenString( "mesh" ); meshes[i].ParseMesh( parser, defaultPose.Num(), poseMat ); } // calculate the bounds of the model bounds.Clear(); for ( int i = 0; i < meshes.Num(); i++ ) { idBounds meshBounds; meshes[i].CalculateBounds( poseMat, meshBounds ); bounds.AddBounds( meshBounds ); } // set the timestamp for reloadmodels fileSystem->ReadFile( name, NULL, &timeStamp ); common->UpdateLevelLoadPacifier(); } /* ============== idRenderModelMD5::Print ============== */ void idRenderModelMD5::Print() const { common->Printf( "%s\n", name.c_str() ); common->Printf( "Dynamic model.\n" ); common->Printf( "Generated smooth normals.\n" ); common->Printf( " verts tris weights material\n" ); int totalVerts = 0; int totalTris = 0; const idMD5Mesh * mesh = meshes.Ptr(); for ( int i = 0; i < meshes.Num(); i++, mesh++ ) { totalVerts += mesh->NumVerts(); totalTris += mesh->NumTris(); common->Printf( "%2i: %5i %5i %s\n", i, mesh->NumVerts(), mesh->NumTris(), mesh->shader->GetName() ); } common->Printf( "-----\n" ); common->Printf( "%4i verts.\n", totalVerts ); common->Printf( "%4i tris.\n", totalTris ); common->Printf( "%4i joints.\n", joints.Num() ); } /* ============== idRenderModelMD5::List ============== */ void idRenderModelMD5::List() const { int i; const idMD5Mesh *mesh; int totalTris = 0; int totalVerts = 0; for( mesh = meshes.Ptr(), i = 0; i < meshes.Num(); i++, mesh++ ) { totalTris += mesh->numTris; totalVerts += mesh->NumVerts(); } common->Printf( " %4ik %3i %4i %4i %s(MD5)", Memory()/1024, meshes.Num(), totalVerts, totalTris, Name() ); if ( defaulted ) { common->Printf( " (DEFAULTED)" ); } common->Printf( "\n" ); } /* ==================== idRenderModelMD5::Bounds This calculates a rough bounds by using the joint radii without transforming all the points ==================== */ idBounds idRenderModelMD5::Bounds( const renderEntity_t *ent ) const { if ( ent == NULL ) { // this is the bounds for the reference pose return bounds; } return ent->bounds; } /* ==================== idRenderModelMD5::DrawJoints ==================== */ void idRenderModelMD5::DrawJoints( const renderEntity_t *ent, const viewDef_t *view ) const { int i; int num; idVec3 pos; const idJointMat *joint; const idMD5Joint *md5Joint; int parentNum; num = ent->numJoints; joint = ent->joints; md5Joint = joints.Ptr(); for( i = 0; i < num; i++, joint++, md5Joint++ ) { pos = ent->origin + joint->ToVec3() * ent->axis; if ( md5Joint->parent ) { parentNum = md5Joint->parent - joints.Ptr(); common->RW()->DebugLine( colorWhite, ent->origin + ent->joints[ parentNum ].ToVec3() * ent->axis, pos ); } common->RW()->DebugLine( colorRed, pos, pos + joint->ToMat3()[ 0 ] * 2.0f * ent->axis ); common->RW()->DebugLine( colorGreen,pos, pos + joint->ToMat3()[ 1 ] * 2.0f * ent->axis ); common->RW()->DebugLine( colorBlue, pos, pos + joint->ToMat3()[ 2 ] * 2.0f * ent->axis ); } idBounds bounds; bounds.FromTransformedBounds( ent->bounds, vec3_zero, ent->axis ); common->RW()->DebugBounds( colorMagenta, bounds, ent->origin ); if ( ( r_jointNameScale.GetFloat() != 0.0f ) && ( bounds.Expand( 128.0f ).ContainsPoint( view->renderView.vieworg - ent->origin ) ) ) { idVec3 offset( 0, 0, r_jointNameOffset.GetFloat() ); float scale; scale = r_jointNameScale.GetFloat(); joint = ent->joints; num = ent->numJoints; for( i = 0; i < num; i++, joint++ ) { pos = ent->origin + joint->ToVec3() * ent->axis; common->RW()->DrawText( joints[ i ].name, pos + offset, scale, colorWhite, view->renderView.viewaxis, 1 ); } } } /* ==================== TransformJoints ==================== */ static void TransformJoints( idJointMat *__restrict outJoints, const int numJoints, const idJointMat *__restrict inJoints1, const idJointMat *__restrict inJoints2 ) { float * outFloats = outJoints->ToFloatPtr(); const float * inFloats1 = inJoints1->ToFloatPtr(); const float * inFloats2 = inJoints2->ToFloatPtr(); assert_16_byte_aligned( outFloats ); assert_16_byte_aligned( inFloats1 ); assert_16_byte_aligned( inFloats2 ); const __m128 mask_keep_last = __m128c( _mm_set_epi32( 0xFFFFFFFF, 0x00000000, 0x00000000, 0x00000000 ) ); for ( int i = 0; i < numJoints; i += 2, inFloats1 += 2 * 12, inFloats2 += 2 * 12, outFloats += 2 * 12 ) { __m128 m1a0 = _mm_load_ps( inFloats1 + 0 * 12 + 0 ); __m128 m1b0 = _mm_load_ps( inFloats1 + 0 * 12 + 4 ); __m128 m1c0 = _mm_load_ps( inFloats1 + 0 * 12 + 8 ); __m128 m1a1 = _mm_load_ps( inFloats1 + 1 * 12 + 0 ); __m128 m1b1 = _mm_load_ps( inFloats1 + 1 * 12 + 4 ); __m128 m1c1 = _mm_load_ps( inFloats1 + 1 * 12 + 8 ); __m128 m2a0 = _mm_load_ps( inFloats2 + 0 * 12 + 0 ); __m128 m2b0 = _mm_load_ps( inFloats2 + 0 * 12 + 4 ); __m128 m2c0 = _mm_load_ps( inFloats2 + 0 * 12 + 8 ); __m128 m2a1 = _mm_load_ps( inFloats2 + 1 * 12 + 0 ); __m128 m2b1 = _mm_load_ps( inFloats2 + 1 * 12 + 4 ); __m128 m2c1 = _mm_load_ps( inFloats2 + 1 * 12 + 8 ); __m128 tj0 = _mm_and_ps( m1a0, mask_keep_last ); __m128 tk0 = _mm_and_ps( m1b0, mask_keep_last ); __m128 tl0 = _mm_and_ps( m1c0, mask_keep_last ); __m128 tj1 = _mm_and_ps( m1a1, mask_keep_last ); __m128 tk1 = _mm_and_ps( m1b1, mask_keep_last ); __m128 tl1 = _mm_and_ps( m1c1, mask_keep_last ); __m128 ta0 = _mm_splat_ps( m1a0, 0 ); __m128 td0 = _mm_splat_ps( m1b0, 0 ); __m128 tg0 = _mm_splat_ps( m1c0, 0 ); __m128 ta1 = _mm_splat_ps( m1a1, 0 ); __m128 td1 = _mm_splat_ps( m1b1, 0 ); __m128 tg1 = _mm_splat_ps( m1c1, 0 ); __m128 ra0 = _mm_add_ps( tj0, _mm_mul_ps( ta0, m2a0 ) ); __m128 rd0 = _mm_add_ps( tk0, _mm_mul_ps( td0, m2a0 ) ); __m128 rg0 = _mm_add_ps( tl0, _mm_mul_ps( tg0, m2a0 ) ); __m128 ra1 = _mm_add_ps( tj1, _mm_mul_ps( ta1, m2a1 ) ); __m128 rd1 = _mm_add_ps( tk1, _mm_mul_ps( td1, m2a1 ) ); __m128 rg1 = _mm_add_ps( tl1, _mm_mul_ps( tg1, m2a1 ) ); __m128 tb0 = _mm_splat_ps( m1a0, 1 ); __m128 te0 = _mm_splat_ps( m1b0, 1 ); __m128 th0 = _mm_splat_ps( m1c0, 1 ); __m128 tb1 = _mm_splat_ps( m1a1, 1 ); __m128 te1 = _mm_splat_ps( m1b1, 1 ); __m128 th1 = _mm_splat_ps( m1c1, 1 ); __m128 rb0 = _mm_add_ps( ra0, _mm_mul_ps( tb0, m2b0 ) ); __m128 re0 = _mm_add_ps( rd0, _mm_mul_ps( te0, m2b0 ) ); __m128 rh0 = _mm_add_ps( rg0, _mm_mul_ps( th0, m2b0 ) ); __m128 rb1 = _mm_add_ps( ra1, _mm_mul_ps( tb1, m2b1 ) ); __m128 re1 = _mm_add_ps( rd1, _mm_mul_ps( te1, m2b1 ) ); __m128 rh1 = _mm_add_ps( rg1, _mm_mul_ps( th1, m2b1 ) ); __m128 tc0 = _mm_splat_ps( m1a0, 2 ); __m128 tf0 = _mm_splat_ps( m1b0, 2 ); __m128 ti0 = _mm_splat_ps( m1c0, 2 ); __m128 tf1 = _mm_splat_ps( m1b1, 2 ); __m128 ti1 = _mm_splat_ps( m1c1, 2 ); __m128 tc1 = _mm_splat_ps( m1a1, 2 ); __m128 rc0 = _mm_add_ps( rb0, _mm_mul_ps( tc0, m2c0 ) ); __m128 rf0 = _mm_add_ps( re0, _mm_mul_ps( tf0, m2c0 ) ); __m128 ri0 = _mm_add_ps( rh0, _mm_mul_ps( ti0, m2c0 ) ); __m128 rc1 = _mm_add_ps( rb1, _mm_mul_ps( tc1, m2c1 ) ); __m128 rf1 = _mm_add_ps( re1, _mm_mul_ps( tf1, m2c1 ) ); __m128 ri1 = _mm_add_ps( rh1, _mm_mul_ps( ti1, m2c1 ) ); _mm_store_ps( outFloats + 0 * 12 + 0, rc0 ); _mm_store_ps( outFloats + 0 * 12 + 4, rf0 ); _mm_store_ps( outFloats + 0 * 12 + 8, ri0 ); _mm_store_ps( outFloats + 1 * 12 + 0, rc1 ); _mm_store_ps( outFloats + 1 * 12 + 4, rf1 ); _mm_store_ps( outFloats + 1 * 12 + 8, ri1 ); } } /* ==================== idRenderModelMD5::InstantiateDynamicModel ==================== */ idRenderModel *idRenderModelMD5::InstantiateDynamicModel( const struct renderEntity_s *ent, const viewDef_t *view, idRenderModel *cachedModel ) { if ( cachedModel != NULL && !r_useCachedDynamicModels.GetBool() ) { delete cachedModel; cachedModel = NULL; } if ( purged ) { common->DWarning( "model %s instantiated while purged", Name() ); LoadModel(); } if ( !ent->joints ) { common->Printf( "idRenderModelMD5::InstantiateDynamicModel: NULL joints on renderEntity for '%s'\n", Name() ); delete cachedModel; return NULL; } else if ( ent->numJoints != joints.Num() ) { common->Printf( "idRenderModelMD5::InstantiateDynamicModel: renderEntity has different number of joints than model for '%s'\n", Name() ); delete cachedModel; return NULL; } tr.pc.c_generateMd5++; idRenderModelStatic * staticModel; if ( cachedModel != NULL ) { assert( dynamic_cast(cachedModel) != NULL ); assert( idStr::Icmp( cachedModel->Name(), MD5_SnapshotName ) == 0 ); staticModel = static_cast(cachedModel); } else { staticModel = new (TAG_MODEL) idRenderModelStatic; staticModel->InitEmpty( MD5_SnapshotName ); } staticModel->bounds.Clear(); if ( r_showSkel.GetInteger() ) { if ( ( view != NULL ) && ( !r_skipSuppress.GetBool() || !ent->suppressSurfaceInViewID || ( ent->suppressSurfaceInViewID != view->renderView.viewID ) ) ) { // only draw the skeleton DrawJoints( ent, view ); } if ( r_showSkel.GetInteger() > 1 ) { // turn off the model when showing the skeleton staticModel->InitEmpty( MD5_SnapshotName ); return staticModel; } } // update the GPU joints array const int numInvertedJoints = SIMD_ROUND_JOINTS( joints.Num() ); if ( staticModel->jointsInverted == NULL ) { staticModel->numInvertedJoints = numInvertedJoints; const int alignment = glConfig.uniformBufferOffsetAlignment; staticModel->jointsInverted = (idJointMat *)Mem_ClearedAlloc( ALIGN( numInvertedJoints * sizeof( idJointMat ), alignment ), TAG_JOINTMAT ); staticModel->jointsInvertedBuffer = 0; } else { assert( staticModel->numInvertedJoints == numInvertedJoints ); } TransformJoints( staticModel->jointsInverted, joints.Num(), ent->joints, invertedDefaultPose.Ptr() ); // create all the surfaces idMD5Mesh * mesh = meshes.Ptr(); for ( int i = 0; i < meshes.Num(); i++, mesh++ ) { // avoid deforming the surface if it will be a nodraw due to a skin remapping const idMaterial *shader = mesh->shader; shader = R_RemapShaderBySkin( shader, ent->customSkin, ent->customShader ); if ( !shader || ( !shader->IsDrawn() && !shader->SurfaceCastsShadow() ) ) { staticModel->DeleteSurfaceWithId( i ); mesh->surfaceNum = -1; continue; } modelSurface_t *surf; int surfaceNum = 0; if ( staticModel->FindSurfaceWithId( i, surfaceNum ) ) { mesh->surfaceNum = surfaceNum; surf = &staticModel->surfaces[surfaceNum]; } else { mesh->surfaceNum = staticModel->NumSurfaces(); surf = &staticModel->surfaces.Alloc(); surf->geometry = NULL; surf->shader = NULL; surf->id = i; } mesh->UpdateSurface( ent, ent->joints, staticModel->jointsInverted, surf ); assert( surf->geometry != NULL ); // to get around compiler warning // the deformation of the tangents can be deferred until each surface is added to the view surf->geometry->staticModelWithJoints = staticModel; staticModel->bounds.AddBounds( surf->geometry->bounds ); } return staticModel; } /* ==================== idRenderModelMD5::IsDynamicModel ==================== */ dynamicModel_t idRenderModelMD5::IsDynamicModel() const { return DM_CACHED; } /* ==================== idRenderModelMD5::NumJoints ==================== */ int idRenderModelMD5::NumJoints() const { return joints.Num(); } /* ==================== idRenderModelMD5::GetJoints ==================== */ const idMD5Joint *idRenderModelMD5::GetJoints() const { return joints.Ptr(); } /* ==================== idRenderModelMD5::GetDefaultPose ==================== */ const idJointQuat *idRenderModelMD5::GetDefaultPose() const { return defaultPose.Ptr(); } /* ==================== idRenderModelMD5::GetJointHandle ==================== */ jointHandle_t idRenderModelMD5::GetJointHandle( const char *name ) const { const idMD5Joint *joint = joints.Ptr(); for ( int i = 0; i < joints.Num(); i++, joint++ ) { if ( idStr::Icmp( joint->name.c_str(), name ) == 0 ) { return ( jointHandle_t )i; } } return INVALID_JOINT; } /* ===================== idRenderModelMD5::GetJointName ===================== */ const char *idRenderModelMD5::GetJointName( jointHandle_t handle ) const { if ( ( handle < 0 ) || ( handle >= joints.Num() ) ) { return ""; } return joints[ handle ].name; } /* ==================== idRenderModelMD5::NearestJoint ==================== */ int idRenderModelMD5::NearestJoint( int surfaceNum, int a, int b, int c ) const { if ( surfaceNum > meshes.Num() ) { common->Error( "idRenderModelMD5::NearestJoint: surfaceNum > meshes.Num()" ); } const idMD5Mesh *mesh = meshes.Ptr(); for ( int i = 0; i < meshes.Num(); i++, mesh++ ) { if ( mesh->surfaceNum == surfaceNum ) { return mesh->NearestJoint( a, b, c ); } } return 0; } /* ==================== idRenderModelMD5::TouchData models that are already loaded at level start time will still touch their materials to make sure they are kept loaded ==================== */ void idRenderModelMD5::TouchData() { for ( int i = 0; i < meshes.Num(); i++ ) { declManager->FindMaterial( meshes[i].shader->GetName() ); } } /* =================== idRenderModelMD5::PurgeModel frees all the data, but leaves the class around for dangling references, which can regenerate the data with LoadModel() =================== */ void idRenderModelMD5::PurgeModel() { purged = true; joints.Clear(); defaultPose.Clear(); meshes.Clear(); } /* =================== idRenderModelMD5::Memory =================== */ int idRenderModelMD5::Memory() const { int total = sizeof( *this ); total += joints.MemoryUsed() + defaultPose.MemoryUsed() + meshes.MemoryUsed(); // count up strings for ( int i = 0; i < joints.Num(); i++ ) { total += joints[i].name.DynamicMemoryUsed(); } // count up meshes for ( int i = 0; i < meshes.Num(); i++ ) { const idMD5Mesh *mesh = &meshes[i]; total += mesh->numMeshJoints * sizeof( mesh->meshJoints[0] ); // sum up deform info total += sizeof( mesh->deformInfo ); total += R_DeformInfoMemoryUsed( mesh->deformInfo ); } return total; }