/** * @file lltreeparams.h * @brief Implementation of the LLTreeParams class * * Copyright (c) 2001-$CurrentYear$, Linden Research, Inc. * $License$ */ #ifndef LL_LLTREEPARAMS_H #define LL_LLTREEPARAMS_H /* for information about formulas associated with each type * check the Weber + Penn paper */ typedef enum EShapeRatio { SR_CONICAL, SR_SPHERICAL, SR_HEMISPHERICAL, SR_CYLINDRICAL, SR_TAPERED_CYLINDRICAL, SR_FLAME, SR_INVERSE_CONICAL, SR_TEND_FLAME, SR_ENVELOPE}; const U32 TREE_BLOCK_SIZE = 16; const U8 MAX_NUM_LEVELS = 4; class LLTreeParams { public: LLTreeParams(); virtual ~LLTreeParams(); static F32 ShapeRatio(EShapeRatio shape, F32 ratio); public: // Variables with an asterick (*) cannot be modified without a re-instancing the // trunk/branches // Variables with an exclamation point (!) should probably not be modified outside and instead // be tied directly to the species // Variables with a tilde (~) should be tied to a range specified by the // species type but still slightly controllable by the user // GENERAL //! determines length/radius of branches on tree -- ie: general 'shape' EShapeRatio mShape; //! number of recursive branch levels...limit to MAX_NUM_LEVELS U8 mLevels; //~ percentage of trunk at bottom without branches F32 mBaseSize; //~ the general scale + variance of tree F32 mScale, mScaleV; // general scale of tree F32 mScale0, mScaleV0; // LOBING //*! number of peaks in the radial distance about the perimeter U8 mLobes; // even numbers = obvius symmetry ... use odd numbers //*! magnitude of the variations as a fraction of the radius F32 mLobeDepth; // FLARE //*! causes exponential expansion near base of trunk F32 mFlare; // scales radius base by min 1 to '1 + flare' //*! percentage of the height of the trunk to flair -- likely less than baseSize F32 mFlarePercentage; //*! number of cross sections to make for the flair U8 mFlareRes; // LEAVES //~ number of leaves to make U8 mLeaves; //! scale of the leaves F32 mLeafScaleX, mLeafScaleY; // quality/density of leaves F32 mLeafQuality; // several params don't have level 0 values // BRANCHES //~ angle away from parent F32 mDownAngle[MAX_NUM_LEVELS - 1]; F32 mDownAngleV[MAX_NUM_LEVELS - 1]; //~ rotation around parent F32 mRotate[MAX_NUM_LEVELS - 1]; F32 mRotateV[MAX_NUM_LEVELS - 1]; //~ num branches to spawn U8 mBranches[MAX_NUM_LEVELS - 1]; //~ fractional length of branch. 1 = same length as parent branch F32 mLength[MAX_NUM_LEVELS]; F32 mLengthV[MAX_NUM_LEVELS]; //!~ ratio and ratiopower determine radius/length F32 mRatio, mRatioPower; //*! taper of branches F32 mTaper[MAX_NUM_LEVELS]; // 0 - non-tapering cylinder // 1 - taper to a point // 2 - taper to a spherical end // 3 - periodic tapering (concatenated spheres) //! SEG SPLITTING U8 mBaseSplits; //! num segsplits at first curve cross section of trunk F32 mSegSplits[MAX_NUM_LEVELS]; //~ splits per cross section. 1 = 1 split per section F32 mSplitAngle[MAX_NUM_LEVELS]; //~ angle that splits go from parent (tempered by height) F32 mSplitAngleV[MAX_NUM_LEVELS]; //~ variance of the splits // CURVE F32 mCurve[MAX_NUM_LEVELS]; //* general, 1-axis, overall curve of branch F32 mCurveV[MAX_NUM_LEVELS]; //* curve variance at each cross section from general overall curve U8 mCurveRes[MAX_NUM_LEVELS]; //* number of cross sections for curve F32 mCurveBack[MAX_NUM_LEVELS]; //* curveback is amount branch curves back towards // vertices per cross section U8 mVertices[MAX_NUM_LEVELS]; // * no longer useful with pre-instanced branches // specifies upward tendency of branches. //F32 mAttractionUp; // 1 = each branch will slightly go upwards by the end of the branch // >1 = branches tend to go upwards earlier in their length // pruning not implemented // Prune parameters //F32 mPruneRatio; //F32 mPruneWidth, mPruneWidthPeak; //F32 mPrunePowerLow, mPrunePowerHigh; // NETWORK MESSAGE DATA // Below is the outline for network messages regarding trees. // The general idea is that a user would pick a general 'tree type' (the first variable) // and then several 'open ended' variables like 'branchiness' and 'leafiness'. // The effect that each of these general user variables would then affect the actual // tree parameters (like # branches, # segsplits) in different ways depending on // the tree type selected. Essentially, each tree type should have a formula // that expands the 'leafiness' and 'branchiness' user variables into actual // values for the tree parameters. // These formulas aren't made yet and will certainly require some tuning. The // estimates below for the # bits required seems like a good guesstimate. // VARIABLE - # bits (range) - VARIABLES AFFECTED // tree type - 5 bits (32) - // branches - 6 bits (64) - numBranches // splits - 6 bits (64) - segsplits // leafiness - 3 bits (8) - numLeaves // branch spread - 5 bits (32) - splitAngle(V), rotate(V) // angle - 5 bits (32) - downAngle(V) // branch length - 6 bits (64) - branchlength(V) // randomness - 7 bits (128) - percentage for randomness of the (V)'s // basesize - 5 bits (32) - basesize // total - 48 bits //U8 mNetSpecies; }; #endif