//***********************************************************************// // // // - "Talk to me like I'm a 3 year old!" Programming Lessons - // // // // $Author: DigiBen digiben@gametutorials.com // // // // $Program: 3DS Loader // // // // $Description: Demonstrates how to load a .3ds file format // // // // $Date: 10/6/01 // // // //***********************************************************************// #include "3ds.h" #include #include // Global int gBuffer[50000] = {0}; // This is used to read past unwanted data // This file handles all of the code needed to load a .3DS file. // Basically, how it works is, you load a chunk, then you check // the chunk ID. Depending on the chunk ID, you load the information // that is stored in that chunk. If you do not want to read that information, // you read past it. You know how many bytes to read past the chunk because // every chunk stores the length in bytes of that chunk. ///////////////////////////////// CLOAD3DS \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This constructor initializes the tChunk data ///// ///////////////////////////////// CLOAD3DS \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* CLoad3ds::CLoad3ds() { m_FilePointer = NULL; } ///////////////////////////////// IMPORT 3DS \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This is called by the client to open the .3ds file, read it, then clean up ///// ///////////////////////////////// IMPORT 3DS \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* bool CLoad3ds::Import3DS(C3dModel *pModel, char *strFileName) { char strMessage[255] = {0}; tChunk currentChunk = {0}; // Open the 3DS file m_FilePointer = fopen(strFileName, "rb"); // Make sure we have a valid file pointer (we found the file) if(!m_FilePointer) { sprintf(strMessage, "Unable to find the file: %s!", strFileName); /* linuxFix by pb: no MessageBox known by linux */ //MessageBox(NULL, strMessage, "Error", MB_OK); return false; } // Once we have the file open, we need to read the very first data chunk // to see if it's a 3DS file. That way we don't read an invalid file. // If it is a 3DS file, then the first chunk ID will be equal to PRIMARY (some hex num) // Read the first chuck of the file to see if it's a 3DS file ReadChunk(¤tChunk); // Make sure this is a 3DS file if (currentChunk.ID != PRIMARY) { sprintf(strMessage, "Unable to load PRIMARY chuck from file: %s!", strFileName); /* linuxFix by pb: MessageBox not known... */ //MessageBox(NULL, strMessage, "Error", MB_OK); return false; } // Now we actually start reading in the data. ProcessNextChunk() is recursive // Begin loading objects, by calling this recursive function ProcessNextChunk(pModel, ¤tChunk); // After we have read the whole 3DS file, we want to calculate our own vertex normals. ComputeNormals(pModel); // Clean up after everything CleanUp(); return true; } ///////////////////////////////// CLEAN UP \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function cleans up our allocated memory and closes the file ///// ///////////////////////////////// CLEAN UP \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::CleanUp() { if (m_FilePointer) { fclose(m_FilePointer); // Close the current file pointer m_FilePointer = NULL; } } ///////////////////////////////// PROCESS NEXT CHUNK\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function reads the main sections of the .3DS file, then dives deeper with recursion ///// ///////////////////////////////// PROCESS NEXT CHUNK\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ProcessNextChunk(C3dModel *pModel, tChunk *pPreviousChunk) { t3dObject newObject = {0}; // This is used to add to our object list tMaterialInfo newTexture = {0}; // This is used to add to our material list tChunk currentChunk = {0}; // The current chunk to load tChunk tempChunk = {0}; // A temp chunk for holding data // Below we check our chunk ID each time we read a new chunk. Then, if // we want to extract the information from that chunk, we do so. // If we don't want a chunk, we just read past it. // Continue to read the sub chunks until we have reached the length. // After we read ANYTHING we add the bytes read to the chunk and then check // check against the length. while (pPreviousChunk->bytesRead < pPreviousChunk->length) { // Read next Chunk ReadChunk(¤tChunk); // Check the chunk ID switch (currentChunk.ID) { case VERSION: // This holds the version of the file // If the file was made in 3D Studio Max, this chunk has an int that // holds the file version. Since there might be new additions to the 3DS file // format in 4.0, we give a warning to that problem. // However, if the file wasn't made by 3D Studio Max, we don't 100% what the // version length will be so we'll simply ignore the value // Read the file version and add the bytes read to our bytesRead variable currentChunk.bytesRead += fread(gBuffer, 1, currentChunk.length - currentChunk.bytesRead, m_FilePointer); // If the file version is over 3, give a warning that there could be a problem if ((currentChunk.length - currentChunk.bytesRead == 4) && (gBuffer[0] > 0x03)) { /* linuxFix by pb: MessageBox not know, using cout */ //MessageBox(NULL, "This 3DS file is over version 3 so it may load incorrectly", "Warning", MB_OK); //sprintf("This 3DS file is over version 3 so it may load incorrectly"); } break; case OBJECTINFO: // This holds the version of the mesh { // This chunk holds the version of the mesh. It is also the head of the MATERIAL // and OBJECT chunks. From here on we start reading in the material and object info. // Read the next chunk ReadChunk(&tempChunk); // Get the version of the mesh tempChunk.bytesRead += fread(gBuffer, 1, tempChunk.length - tempChunk.bytesRead, m_FilePointer); // Increase the bytesRead by the bytes read from the last chunk currentChunk.bytesRead += tempChunk.bytesRead; // Go to the next chunk, which is the object has a texture, it should be MATERIAL, then OBJECT. ProcessNextChunk(pModel, ¤tChunk); break; } case MATERIAL: // This holds the material information // This chunk is the header for the material info chunks // Increase the number of materials pModel->numOfMaterials++; // Add a empty texture structure to our texture list. // If you are unfamiliar with STL's "vector" class, all push_back() // does is add a new node onto the list. I used the vector class // so I didn't need to write my own link list functions. pModel->pMaterials.push_back(newTexture); // Proceed to the material loading function ProcessNextMaterialChunk(pModel, ¤tChunk); break; case OBJECT: // This holds the name of the object being read // This chunk is the header for the object info chunks. It also // holds the name of the object. // Increase the object count pModel->numOfObjects++; // Add a new tObject node to our list of objects (like a link list) pModel->pObject.push_back(newObject); // Initialize the object and all it's data members memset(&(pModel->pObject[pModel->numOfObjects - 1]), 0, sizeof(t3dObject)); // Get the name of the object and store it, then add the read bytes to our byte counter. currentChunk.bytesRead += GetString(pModel->pObject[pModel->numOfObjects - 1].strName); // Now proceed to read in the rest of the object information ProcessNextObjectChunk(pModel, &(pModel->pObject[pModel->numOfObjects - 1]), ¤tChunk); break; case EDITKEYFRAME: // Because I wanted to make this a SIMPLE tutorial as possible, I did not include // the key frame information. This chunk is the header for all the animation info. // In a later tutorial this will be the subject and explained thoroughly. //ProcessNextKeyFrameChunk(pModel, currentChunk); // Read past this chunk and add the bytes read to the byte counter currentChunk.bytesRead += fread(gBuffer, 1, currentChunk.length - currentChunk.bytesRead, m_FilePointer); break; default: // If we didn't care about a chunk, then we get here. We still need // to read past the unknown or ignored chunk and add the bytes read to the byte counter. currentChunk.bytesRead += fread(gBuffer, 1, currentChunk.length - currentChunk.bytesRead, m_FilePointer); break; } // Add the bytes read from the last chunk to the previous chunk passed in. pPreviousChunk->bytesRead += currentChunk.bytesRead; } } ///////////////////////////////// PROCESS NEXT OBJECT CHUNK \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function handles all the information about the objects in the file ///// ///////////////////////////////// PROCESS NEXT OBJECT CHUNK \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ProcessNextObjectChunk(C3dModel *pModel, t3dObject *pObject, tChunk *pPreviousChunk) { // The current chunk to work with tChunk currentChunk = {0}; // Continue to read these chunks until we read the end of this sub chunk while (pPreviousChunk->bytesRead < pPreviousChunk->length) { // Read the next chunk ReadChunk(¤tChunk); // Check which chunk we just read switch (currentChunk.ID) { case OBJECT_MESH: // This lets us know that we are reading a new object // We found a new object, so let's read in it's info using recursion ProcessNextObjectChunk(pModel, pObject, ¤tChunk); break; case OBJECT_VERTICES: // This is the objects vertices ReadVertices(pObject, ¤tChunk); break; case OBJECT_FACES: // This is the objects face information ReadVertexIndices(pObject, ¤tChunk); break; case OBJECT_MATERIAL: // This holds the material name that the object has // This chunk holds the name of the material that the object has assigned to it. // This could either be just a color or a texture map. This chunk also holds // the faces that the texture is assigned to (In the case that there is multiple // textures assigned to one object, or it just has a texture on a part of the object. // Since most of my game objects just have the texture around the whole object, and // they aren't multitextured, I just want the material name. // We now will read the name of the material assigned to this object ReadObjectMaterial(pModel, pObject, ¤tChunk); break; case OBJECT_UV: // This holds the UV texture coordinates for the object // This chunk holds all of the UV coordinates for our object. Let's read them in. ReadUVCoordinates(pObject, ¤tChunk); break; default: // Read past the ignored or unknown chunks currentChunk.bytesRead += fread(gBuffer, 1, currentChunk.length - currentChunk.bytesRead, m_FilePointer); break; } // Add the bytes read from the last chunk to the previous chunk passed in. pPreviousChunk->bytesRead += currentChunk.bytesRead; } } ///////////////////////////////// PROCESS NEXT MATERIAL CHUNK \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function handles all the information about the material (Texture) ///// ///////////////////////////////// PROCESS NEXT MATERIAL CHUNK \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ProcessNextMaterialChunk(C3dModel *pModel, tChunk *pPreviousChunk) { // The current chunk to work with tChunk currentChunk = {0}; // Continue to read these chunks until we read the end of this sub chunk while (pPreviousChunk->bytesRead < pPreviousChunk->length) { // Read the next chunk ReadChunk(¤tChunk); // Check which chunk we just read in switch (currentChunk.ID) { case MATNAME: // This chunk holds the name of the material // Here we read in the material name currentChunk.bytesRead += fread(pModel->pMaterials[pModel->numOfMaterials - 1].strName, 1, currentChunk.length - currentChunk.bytesRead, m_FilePointer); break; case MATDIFFUSE: // This holds the R G B color of our object ReadColorChunk(&(pModel->pMaterials[pModel->numOfMaterials - 1]), ¤tChunk); break; case MATMAP: // This is the header for the texture info // Proceed to read in the material information ProcessNextMaterialChunk(pModel, ¤tChunk); break; case MATMAPFILE: // This stores the file name of the material // Here we read in the material's file name currentChunk.bytesRead += fread(pModel->pMaterials[pModel->numOfMaterials - 1].strFile, 1, currentChunk.length - currentChunk.bytesRead, m_FilePointer); break; default: // Read past the ignored or unknown chunks currentChunk.bytesRead += fread(gBuffer, 1, currentChunk.length - currentChunk.bytesRead, m_FilePointer); break; } // Add the bytes read from the last chunk to the previous chunk passed in. pPreviousChunk->bytesRead += currentChunk.bytesRead; } } ///////////////////////////////// READ CHUNK \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function reads in a chunk ID and it's length in bytes ///// ///////////////////////////////// READ CHUNK \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ReadChunk(tChunk *pChunk) { // This reads the chunk ID which is 2 bytes. // The chunk ID is like OBJECT or MATERIAL. It tells what data is // able to be read in within the chunks section. pChunk->bytesRead = fread(&pChunk->ID, 1, 2, m_FilePointer); // Then, we read the length of the chunk which is 4 bytes. // This is how we know how much to read in, or read past. pChunk->bytesRead += fread(&pChunk->length, 1, 4, m_FilePointer); } ///////////////////////////////// GET STRING \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function reads in a string of characters ///// ///////////////////////////////// GET STRING \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* int CLoad3ds::GetString(char *pBuffer) { int index = 0; // Read 1 byte of data which is the first letter of the string fread(pBuffer, 1, 1, m_FilePointer); // Loop until we get NULL while (*(pBuffer + index++) != 0) { // Read in a character at a time until we hit NULL. fread(pBuffer + index, 1, 1, m_FilePointer); } // Return the string length, which is how many bytes we read in (including the NULL) return strlen(pBuffer) + 1; } ///////////////////////////////// READ COLOR \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function reads in the RGB color data ///// ///////////////////////////////// READ COLOR \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ReadColorChunk(tMaterialInfo *pMaterial, tChunk *pChunk) { tChunk tempChunk = {0}; // Read the color chunk info ReadChunk(&tempChunk); // Read in the R G B color (3 bytes - 0 through 255) tempChunk.bytesRead += fread(pMaterial->color, 1, tempChunk.length - tempChunk.bytesRead, m_FilePointer); // Add the bytes read to our chunk pChunk->bytesRead += tempChunk.bytesRead; } ///////////////////////////////// READ VERTEX INDECES \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function reads in the indices for the vertex array ///// ///////////////////////////////// READ VERTEX INDECES \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ReadVertexIndices(t3dObject *pObject, tChunk *pPreviousChunk) { unsigned short index = 0; // This is used to read in the current face index // In order to read in the vertex indices for the object, we need to first // read in the number of them, then read them in. Remember, // we only want 3 of the 4 values read in for each face. The fourth is // a visibility flag for 3D Studio Max that doesn't mean anything to us. // Read in the number of faces that are in this object (int) pPreviousChunk->bytesRead += fread(&pObject->iNumOfFaces, 1, 2, m_FilePointer); // Alloc enough memory for the faces and initialize the structure pObject->pFaces = new tFace [pObject->iNumOfFaces]; memset(pObject->pFaces, 0, sizeof(tFace) * pObject->iNumOfFaces); // Go through all of the faces in this object for(int i = 0; i < pObject->iNumOfFaces; i++) { // Next, we read in the A then B then C index for the face, but ignore the 4th value. // The fourth value is a visibility flag for 3D Studio Max, we don't care about this. for(int j = 0; j < 4; j++) { // Read the first vertice index for the current face pPreviousChunk->bytesRead += fread(&index, 1, sizeof(index), m_FilePointer); if(j < 3) { // Store the index in our face structure. pObject->pFaces[i].vertIndex[j] = index; } } } } ///////////////////////////////// READ UV COORDINATES \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function reads in the UV coordinates for the object ///// ///////////////////////////////// READ UV COORDINATES \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ReadUVCoordinates(t3dObject *pObject, tChunk *pPreviousChunk) { // In order to read in the UV indices for the object, we need to first // read in the amount there are, then read them in. // Read in the number of UV coordinates there are (int) pPreviousChunk->bytesRead += fread(&pObject->iNumTexVertex, 1, 2, m_FilePointer); // Allocate memory to hold the UV coordinates pObject->pTexVerts = new CVector2 [pObject->iNumTexVertex]; // Read in the texture coodinates (an array 2 float) pPreviousChunk->bytesRead += fread(pObject->pTexVerts, 1, pPreviousChunk->length - pPreviousChunk->bytesRead, m_FilePointer); } ///////////////////////////////// READ VERTICES \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function reads in the vertices for the object ///// ///////////////////////////////// READ VERTICES \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ReadVertices(t3dObject *pObject, tChunk *pPreviousChunk) { // Like most chunks, before we read in the actual vertices, we need // to find out how many there are to read in. Once we have that number // we then fread() them into our vertice array. // Read in the number of vertices (int) pPreviousChunk->bytesRead += fread(&(pObject->iNumOfVerts), 1, 2, m_FilePointer); // Allocate the memory for the verts and initialize the structure pObject->pVerts = new CVector3 [pObject->iNumOfVerts]; memset(pObject->pVerts, 0, sizeof(CVector3) * pObject->iNumOfVerts); // Read in the array of vertices (an array of 3 floats) pPreviousChunk->bytesRead += fread(pObject->pVerts, 1, pPreviousChunk->length - pPreviousChunk->bytesRead, m_FilePointer); // Now we should have all of the vertices read in. Because 3D Studio Max // Models with the Z-Axis pointing up (strange and ugly I know!), we need // to flip the y values with the z values in our vertices. That way it // will be normal, with Y pointing up. If you prefer to work with Z pointing // up, then just delete this next loop. Also, because we swap the Y and Z // we need to negate the Z to make it come out correctly. // Go through all of the vertices that we just read and swap the Y and Z values for(int i = 0; i < pObject->iNumOfVerts; i++) { // Store off the Y value float fTempY = pObject->pVerts[i].y; // Set the Y value to the Z value pObject->pVerts[i].y = pObject->pVerts[i].z; // Set the Z value to the Y value, // but negative Z because 3D Studio max does the opposite. pObject->pVerts[i].z = -fTempY; } } ///////////////////////////////// READ OBJECT MATERIAL \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function reads in the material name assigned to the object and sets the materialID ///// ///////////////////////////////// READ OBJECT MATERIAL \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ReadObjectMaterial(C3dModel *pModel, t3dObject *pObject, tChunk *pPreviousChunk) { char strMaterial[255] = {0}; // This is used to hold the objects material name // *What is a material?* - A material is either the color or the texture map of the object. // It can also hold other information like the brightness, shine, etc... Stuff we don't // really care about. We just want the color, or the texture map file name really. // Here we read the material name that is assigned to the current object. // strMaterial should now have a string of the material name, like "Material #2" etc.. pPreviousChunk->bytesRead += GetString(strMaterial); // Now that we have a material name, we need to go through all of the materials // and check the name against each material. When we find a material in our material // list that matches this name we just read in, then we assign the materialID // of the object to that material index. You will notice that we passed in the // model to this function. This is because we need the number of textures. // Yes though, we could have just passed in the model and not the object too. // Go through all of the textures for(int i = 0; i < pModel->numOfMaterials; i++) { // If the material we just read in matches the current texture name if(strcmp(strMaterial, pModel->pMaterials[i].strName) == 0) { // Set the material ID to the current index 'i' and stop checking pObject->materialID = i; // Now that we found the material, check if it's a texture map. // If the strFile has a string length of 1 and over it's a texture if(strlen(pModel->pMaterials[i].strFile) > 0) { // Set the object's flag to say it has a texture map to bind. pObject->bHasTexture = true; } break; } else { // Set the ID to -1 to show there is no material for this object pObject->materialID = -1; } } // Read past the rest of the chunk since we don't care about shared vertices // You will notice we subtract the bytes already read in this chunk from the total length. pPreviousChunk->bytesRead += fread(gBuffer, 1, pPreviousChunk->length - pPreviousChunk->bytesRead, m_FilePointer); } // *Note* // // Below are some math functions for calculating vertex normals. We want vertex normals // because it makes the lighting look really smooth and life like. You probably already // have these functions in the rest of your engine, so you can delete these and call // your own. I wanted to add them so I could show how to calculate vertex normals. ////////////////////////////// Math Functions ////////////////////////////////* // This computes the magnitude of a normal. (magnitude = sqrt(x^2 + y^2 + z^2) #define Mag(Normal) (sqrt(Normal.x*Normal.x + Normal.y*Normal.y + Normal.z*Normal.z)) // This calculates a vector between 2 points and returns the result CVector3 Vector(CVector3 vPoint1, CVector3 vPoint2) { CVector3 vVector; // The variable to hold the resultant vector vVector.x = vPoint1.x - vPoint2.x; // Subtract point1 and point2 x's vVector.y = vPoint1.y - vPoint2.y; // Subtract point1 and point2 y's vVector.z = vPoint1.z - vPoint2.z; // Subtract point1 and point2 z's return vVector; // Return the resultant vector } // This adds 2 vectors together and returns the result CVector3 AddVector(CVector3 vVector1, CVector3 vVector2) { CVector3 vResult; // The variable to hold the resultant vector vResult.x = vVector2.x + vVector1.x; // Add Vector1 and Vector2 x's vResult.y = vVector2.y + vVector1.y; // Add Vector1 and Vector2 y's vResult.z = vVector2.z + vVector1.z; // Add Vector1 and Vector2 z's return vResult; // Return the resultant vector } // This divides a vector by a single number (scalar) and returns the result CVector3 DivideVectorByScaler(CVector3 vVector1, float Scaler) { CVector3 vResult; // The variable to hold the resultant vector vResult.x = vVector1.x / Scaler; // Divide Vector1's x value by the scaler vResult.y = vVector1.y / Scaler; // Divide Vector1's y value by the scaler vResult.z = vVector1.z / Scaler; // Divide Vector1's z value by the scaler return vResult; // Return the resultant vector } // This returns the cross product between 2 vectors CVector3 Cross(CVector3 vVector1, CVector3 vVector2) { CVector3 vCross; // The vector to hold the cross product // Get the X value vCross.x = ((vVector1.y * vVector2.z) - (vVector1.z * vVector2.y)); // Get the Y value vCross.y = ((vVector1.z * vVector2.x) - (vVector1.x * vVector2.z)); // Get the Z value vCross.z = ((vVector1.x * vVector2.y) - (vVector1.y * vVector2.x)); return vCross; // Return the cross product } // This returns the normal of a vector CVector3 Normalize(CVector3 vNormal) { double Magnitude; // This holds the magitude Magnitude = Mag(vNormal); // Get the magnitude vNormal.x /= (float)Magnitude; // Divide the vector's X by the magnitude vNormal.y /= (float)Magnitude; // Divide the vector's Y by the magnitude vNormal.z /= (float)Magnitude; // Divide the vector's Z by the magnitude return vNormal; // Return the normal } ///////////////////////////////// COMPUTER NORMALS \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* ///// ///// This function computes the normals and vertex normals of the objects ///// ///////////////////////////////// COMPUTER NORMALS \\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\\* void CLoad3ds::ComputeNormals(C3dModel *pModel) { CVector3 vVector1, vVector2, vNormal, vPoly[3]; // If there are no objects, we can skip this part if(pModel->numOfObjects <= 0) return; // What are vertex normals? And how are they different from other normals? // Well, if you find the normal to a triangle, you are finding a "Face Normal". // If you give OpenGL a face normal for lighting, it will make your object look // really flat and not very round. If we find the normal for each vertex, it makes // the smooth lighting look. This also covers up blocky looking objects and they appear // to have more polygons than they do. Basically, what you do is first // calculate the face normals, then you take the average of all the normals around each // vertex. It's just averaging. That way you get a better approximation for that vertex. // Go through each of the objects to calculate their normals for(int index = 0; index < pModel->numOfObjects; index++) { // Get the current object t3dObject *pObject = &(pModel->pObject[index]); // Here we allocate all the memory we need to calculate the normals CVector3 *pNormals = new CVector3 [pObject->iNumOfFaces]; CVector3 *pTempNormals = new CVector3 [pObject->iNumOfFaces]; pObject->pNormals = new CVector3 [pObject->iNumOfVerts]; // Go though all of the faces of this object for(int i=0; i < pObject->iNumOfFaces; i++) { // To cut down LARGE code, we extract the 3 points of this face vPoly[0] = pObject->pVerts[pObject->pFaces[i].vertIndex[0]]; vPoly[1] = pObject->pVerts[pObject->pFaces[i].vertIndex[1]]; vPoly[2] = pObject->pVerts[pObject->pFaces[i].vertIndex[2]]; // Now let's calculate the face normals (Get 2 vectors and find the cross product of those 2) vVector1 = Vector(vPoly[0], vPoly[2]); // Get the vector of the polygon (we just need 2 sides for the normal) vVector2 = Vector(vPoly[2], vPoly[1]); // Get a second vector of the polygon vNormal = Cross(vVector1, vVector2); // Return the cross product of the 2 vectors (normalize vector, but not a unit vector) pTempNormals[i] = vNormal; // Save the un-normalized normal for the vertex normals vNormal = Normalize(vNormal); // Normalize the cross product to give us the polygons normal pNormals[i] = vNormal; // Assign the normal to the list of normals } //////////////// Now Get The Vertex Normals ///////////////// CVector3 vSum = {0.0, 0.0, 0.0}; CVector3 vZero = vSum; int shared=0; for (int i = 0; i < pObject->iNumOfVerts; i++) // Go through all of the vertices { for (int j = 0; j < pObject->iNumOfFaces; j++) // Go through all of the triangles { // Check if the vertex is shared by another face if (pObject->pFaces[j].vertIndex[0] == i || pObject->pFaces[j].vertIndex[1] == i || pObject->pFaces[j].vertIndex[2] == i) { vSum = AddVector(vSum, pTempNormals[j]);// Add the un-normalized normal of the shared face shared++; // Increase the number of shared triangles } } // Get the normal by dividing the sum by the shared. We negate the shared so it has the normals pointing out. pObject->pNormals[i] = DivideVectorByScaler(vSum, float(-shared)); // Normalize the normal for the final vertex normal pObject->pNormals[i] = Normalize(pObject->pNormals[i]); vSum = vZero; // Reset the sum shared = 0; // Reset the shared } // Free our memory and start over on the next object delete [] pTempNormals; delete [] pNormals; } } ///////////////////////////////////////////////////////////////////////////////// // // * QUICK NOTES * // // This was a HUGE amount of knowledge and probably the largest tutorial yet! // In the next tutorial we will show you how to load a text file format called .obj. // This is the most common 3D file format that almost ANY 3D software will import. // // Once again I should point out that the coordinate system of OpenGL and 3DS Max are different. // Since 3D Studio Max Models with the Z-Axis pointing up (strange and ugly I know! :), // we need to flip the y values with the z values in our vertices. That way it // will be normal, with Y pointing up. Also, because we swap the Y and Z we need to negate // the Z to make it come out correctly. This is also explained and done in ReadVertices(). // // CHUNKS: What is a chunk anyway? // // "The chunk ID is a unique code which identifies the type of data in this chunk // and also may indicate the existence of subordinate chunks. The chunk length indicates // the length of following data to be associated with this chunk. Note, this may // contain more data than just this chunk. If the length of data is greater than that // needed to fill in the information for the chunk, additional subordinate chunks are // attached to this chunk immediately following any data needed for this chunk, and // should be parsed out. These subordinate chunks may themselves contain subordinate chunks. // Unfortunately, there is no indication of the length of data, which is owned by the current // chunk, only the total length of data attached to the chunk, which means that the only way // to parse out subordinate chunks is to know the exact format of the owning chunk. On the // other hand, if a chunk is unknown, the parsing program can skip the entire chunk and // subordinate chunks in one jump. " - Jeff Lewis (werewolf@worldgate.com) // // In a short amount of words, a chunk is defined this way: // 2 bytes - Stores the chunk ID (OBJECT, MATERIAL, PRIMARY, etc...) // 4 bytes - Stores the length of that chunk. That way you know when that // chunk is done and there is a new chunk. // // So, to start reading the 3DS file, you read the first 2 bytes of it, then // the length (using fread()). It should be the PRIMARY chunk, otherwise it isn't // a .3DS file. // // Below is a list of the order that you will find the chunks and all the know chunks. // If you go to www.wosit.org you can find a few documents on the 3DS file format. // You can also take a look at the 3DS Format.rtf that is included with this tutorial. // // // // MAIN3DS (0x4D4D) // | // +--EDIT3DS (0x3D3D) // | | // | +--EDIT_MATERIAL (0xAFFF) // | | | // | | +--MAT_NAME01 (0xA000) (See mli Doc) // | | // | +--EDIT_CONFIG1 (0x0100) // | +--EDIT_CONFIG2 (0x3E3D) // | +--EDIT_VIEW_P1 (0x7012) // | | | // | | +--TOP (0x0001) // | | +--BOTTOM (0x0002) // | | +--LEFT (0x0003) // | | +--RIGHT (0x0004) // | | +--FRONT (0x0005) // | | +--BACK (0x0006) // | | +--USER (0x0007) // | | +--CAMERA (0xFFFF) // | | +--LIGHT (0x0009) // | | +--DISABLED (0x0010) // | | +--BOGUS (0x0011) // | | // | +--EDIT_VIEW_P2 (0x7011) // | | | // | | +--TOP (0x0001) // | | +--BOTTOM (0x0002) // | | +--LEFT (0x0003) // | | +--RIGHT (0x0004) // | | +--FRONT (0x0005) // | | +--BACK (0x0006) // | | +--USER (0x0007) // | | +--CAMERA (0xFFFF) // | | +--LIGHT (0x0009) // | | +--DISABLED (0x0010) // | | +--BOGUS (0x0011) // | | // | +--EDIT_VIEW_P3 (0x7020) // | +--EDIT_VIEW1 (0x7001) // | +--EDIT_BACKGR (0x1200) // | +--EDIT_AMBIENT (0x2100) // | +--EDIT_OBJECT (0x4000) // | | | // | | +--OBJ_TRIMESH (0x4100) // | | | | // | | | +--TRI_VERTEXL (0x4110) // | | | +--TRI_VERTEXOPTIONS (0x4111) // | | | +--TRI_MAPPINGCOORS (0x4140) // | | | +--TRI_MAPPINGSTANDARD (0x4170) // | | | +--TRI_FACEL1 (0x4120) // | | | | | // | | | | +--TRI_SMOOTH (0x4150) // | | | | +--TRI_MATERIAL (0x4130) // | | | | // | | | +--TRI_LOCAL (0x4160) // | | | +--TRI_VISIBLE (0x4165) // | | | // | | +--OBJ_LIGHT (0x4600) // | | | | // | | | +--LIT_OFF (0x4620) // | | | +--LIT_SPOT (0x4610) // | | | +--LIT_UNKNWN01 (0x465A) // | | | // | | +--OBJ_CAMERA (0x4700) // | | | | // | | | +--CAM_UNKNWN01 (0x4710) // | | | +--CAM_UNKNWN02 (0x4720) // | | | // | | +--OBJ_UNKNWN01 (0x4710) // | | +--OBJ_UNKNWN02 (0x4720) // | | // | +--EDIT_UNKNW01 (0x1100) // | +--EDIT_UNKNW02 (0x1201) // | +--EDIT_UNKNW03 (0x1300) // | +--EDIT_UNKNW04 (0x1400) // | +--EDIT_UNKNW05 (0x1420) // | +--EDIT_UNKNW06 (0x1450) // | +--EDIT_UNKNW07 (0x1500) // | +--EDIT_UNKNW08 (0x2200) // | +--EDIT_UNKNW09 (0x2201) // | +--EDIT_UNKNW10 (0x2210) // | +--EDIT_UNKNW11 (0x2300) // | +--EDIT_UNKNW12 (0x2302) // | +--EDIT_UNKNW13 (0x2000) // | +--EDIT_UNKNW14 (0xAFFF) // | // +--KEYF3DS (0xB000) // | // +--KEYF_UNKNWN01 (0xB00A) // +--............. (0x7001) ( viewport, same as editor ) // +--KEYF_FRAMES (0xB008) // +--KEYF_UNKNWN02 (0xB009) // +--KEYF_OBJDES (0xB002) // | // +--KEYF_OBJHIERARCH (0xB010) // +--KEYF_OBJDUMMYNAME (0xB011) // +--KEYF_OBJUNKNWN01 (0xB013) // +--KEYF_OBJUNKNWN02 (0xB014) // +--KEYF_OBJUNKNWN03 (0xB015) // +--KEYF_OBJPIVOT (0xB020) // +--KEYF_OBJUNKNWN04 (0xB021) // +--KEYF_OBJUNKNWN05 (0xB022) // // Once you know how to read chunks, all you have to know is the ID you are looking for // and what data is stored after that ID. You need to get the file format for that. // I can give it to you if you want, or you can go to www.wosit.org for several versions. // Because this is a proprietary format, it isn't a official document. // // I know there was a LOT of information blown over, but it is too much knowledge for // one tutorial. In the animation tutorial that I eventually will get to, some of // the things explained here will be explained in more detail. I do not claim that // this is the best .3DS tutorial, or even a GOOD one :) But it is a good start, and there // isn't much code out there that is simple when it comes to reading .3DS files. // So far, this is the best I have seen. That is why I made it :) // // I would like to thank www.wosit.org and Terry Caton (tcaton@umr.edu) for his help on this. // // Let me know if this helps you out! // // // Ben Humphrey (DigiBen) // Game Programmer // DigiBen@GameTutorials.com // Co-Web Host of www.GameTutorials.com // //