#include namespace rw { struct Object { uint8 type; uint8 subType; uint8 flags; uint8 privateFlags; void *parent; void init(uint8 type, uint8 subType){ this->type = type; this->subType = subType; this->flags = 0; this->privateFlags = 0; this->parent = nil; } void copy(Object *o){ this->type = o->type; this->subType = o->subType; this->flags = o->flags; this->privateFlags = o->privateFlags; this->parent = nil; } }; struct Frame { PLUGINBASE typedef Frame *(*Callback)(Frame *f, void *data); enum { ID = 0 }; enum { // private flags // The hierarchy has unsynched frames HIERARCHYSYNCLTM = 0x01, // LTM not synched HIERARCHYSYNCOBJ = 0x02, // attached objects not synched HIERARCHYSYNC = HIERARCHYSYNCLTM | HIERARCHYSYNCOBJ, // This frame is not synched SUBTREESYNCLTM = 0x04, SUBTREESYNCOBJ = 0x08, SUBTREESYNC = SUBTREESYNCLTM | SUBTREESYNCOBJ, SYNCLTM = HIERARCHYSYNCLTM | SUBTREESYNCLTM, SYNCOBJ = HIERARCHYSYNCOBJ | SUBTREESYNCOBJ // STATIC = 0x10 }; Object object; LLLink inDirtyList; LinkList objectList; Matrix matrix; Matrix ltm; Frame *child; Frame *next; Frame *root; static int32 numAllocated; static Frame *create(void); Frame *cloneHierarchy(void); void destroy(void); void destroyHierarchy(void); Frame *addChild(Frame *f, bool32 append = 0); Frame *removeChild(void); Frame *forAllChildren(Callback cb, void *data); Frame *getParent(void) const { return (Frame*)this->object.parent; } int32 count(void); bool32 dirty(void) const { return !!(this->root->object.privateFlags & HIERARCHYSYNC); } Matrix *getLTM(void); void rotate(const V3d *axis, float32 angle, CombineOp op); void translate(const V3d *trans, CombineOp op); void scale(const V3d *scale, CombineOp op); void transform(const Matrix *mat, CombineOp op); void updateObjects(void); void syncHierarchyLTM(void); void setHierarchyRoot(Frame *root); Frame *cloneAndLink(void); void purgeClone(void); #ifndef RWPUBLIC static void registerModule(void); #endif static void syncDirty(void); }; struct FrameList_ { int32 numFrames; Frame **frames; FrameList_ *streamRead(Stream *stream); void streamWrite(Stream *stream); static uint32 streamGetSize(Frame *f); }; Frame **makeFrameList(Frame *frame, Frame **flist); struct ObjectWithFrame { typedef void (*Sync)(ObjectWithFrame*); Object object; LLLink inFrame; Sync syncCB; void setFrame(Frame *f){ if(this->object.parent) this->inFrame.remove(); this->object.parent = f; if(f){ f->objectList.add(&this->inFrame); f->updateObjects(); } } void sync(void){ this->syncCB(this); } static ObjectWithFrame *fromFrame(LLLink *lnk){ return LLLinkGetData(lnk, ObjectWithFrame, inFrame); } }; struct Image { int32 flags; int32 width, height; int32 depth; int32 bpp; // bytes per pixel int32 stride; uint8 *pixels; uint8 *palette; static int32 numAllocated; static Image *create(int32 width, int32 height, int32 depth); void destroy(void); void allocate(void); void free(void); void setPixels(uint8 *pixels); void setPixelsDXT(int32 type, uint8 *pixels); void setPalette(uint8 *palette); bool32 hasAlpha(void); void unindex(void); void removeMask(void); Image *extractMask(void); static void setSearchPath(const char*); static void printSearchPath(void); static char *getFilename(const char*); }; Image *readTGA(const char *filename); void writeTGA(Image *image, const char *filename); Image *readBMP(const char *filename); void writeBMP(Image *image, const char *filename); // used to emulate d3d and xbox textures struct RasterLevels { int32 numlevels; uint32 format; struct Level { int32 width, height, size; uint8 *data; } levels[1]; // 0 is illegal :/ }; struct Raster { PLUGINBASE int32 platform; // TODO: use bytes int32 type; int32 flags; int32 privateFlags; int32 format; int32 width, height, depth; int32 stride; uint8 *pixels; uint8 *palette; // remember for locked rasters uint8 *originalPixels; int32 originalWidth; int32 originalHeight; int32 originalStride; // subraster Raster *parent; int32 offsetX, offsetY; static int32 numAllocated; static Raster *create(int32 width, int32 height, int32 depth, int32 format, int32 platform = 0); void subRaster(Raster *parent, Rect *r); void destroy(void); static bool32 imageFindRasterFormat(Image *image, int32 type, int32 *pWidth, int32 *pHeight, int32 *pDepth, int32 *pFormat, int32 platform = 0); Raster *setFromImage(Image *image, int32 platform = 0); static Raster *createFromImage(Image *image, int32 platform = 0); Image *toImage(void); uint8 *lock(int32 level, int32 lockMode); void unlock(int32 level); uint8 *lockPalette(int32 lockMode); void unlockPalette(void); int32 getNumLevels(void); static int32 calculateNumLevels(int32 width, int32 height); static bool formatHasAlpha(int32 format); static Raster *pushContext(Raster *raster); static Raster *popContext(void); static Raster *getCurrentContext(void); bool32 renderFast(int32 x, int32 y); #ifndef RWPUBLIC static void registerModule(void); #endif enum Format { DEFAULT = 0, C1555 = 0x0100, C565 = 0x0200, C4444 = 0x0300, LUM8 = 0x0400, C8888 = 0x0500, C888 = 0x0600, D16 = 0x0700, D24 = 0x0800, D32 = 0x0900, C555 = 0x0A00, AUTOMIPMAP = 0x1000, PAL8 = 0x2000, PAL4 = 0x4000, MIPMAP = 0x8000 }; enum Type { NORMAL = 0x00, ZBUFFER = 0x01, CAMERA = 0x02, TEXTURE = 0x04, CAMERATEXTURE = 0x05, DONTALLOCATE = 0x80 }; enum LockMode { LOCKWRITE = 1, LOCKREAD = 2, LOCKNOFETCH = 4, // don't fetch pixel data LOCKRAW = 8, }; }; #define IGNORERASTERIMP 0 struct TexDictionary; struct Texture { enum FilterMode { NEAREST = 1, LINEAR, MIPNEAREST, MIPLINEAR, LINEARMIPNEAREST, LINEARMIPLINEAR }; enum Addressing { WRAP = 1, MIRROR, CLAMP, BORDER }; PLUGINBASE Raster *raster; TexDictionary *dict; LLLink inDict; char name[32]; char mask[32]; uint32 filterAddressing; // VVVVUUUU FFFFFFFF int32 refCount; LLLink inGlobalList; // actually not in RW static int32 numAllocated; static Texture *create(Raster *raster); void addRef(void) { this->refCount++; } void destroy(void); static Texture *fromDict(LLLink *lnk){ return LLLinkGetData(lnk, Texture, inDict); } FilterMode getFilter(void) { return (FilterMode)(filterAddressing & 0xFF); } void setFilter(FilterMode f) { filterAddressing = (filterAddressing & ~0xFF) | f; } Addressing getAddressU(void) { return (Addressing)((filterAddressing >> 8) & 0xF); } Addressing getAddressV(void) { return (Addressing)((filterAddressing >> 12) & 0xF); } void setAddressU(Addressing u) { filterAddressing = (filterAddressing & ~0xF00) | u<<8; } void setAddressV(Addressing v) { filterAddressing = (filterAddressing & ~0xF000) | v<<12; } static Texture *streamRead(Stream *stream); bool streamWrite(Stream *stream); uint32 streamGetSize(void); static Texture *read(const char *name, const char *mask); static Texture *streamReadNative(Stream *stream); void streamWriteNative(Stream *stream); uint32 streamGetSizeNative(void); static Texture *(*findCB)(const char *name); static Texture *(*readCB)(const char *name, const char *mask); static void setLoadTextures(bool32); // default: true static void setCreateDummies(bool32); // default: false #ifndef RWPUBLIC static void registerModule(void); #endif }; struct SurfaceProperties { float32 ambient; float32 specular; float32 diffuse; }; struct Material { PLUGINBASE Texture *texture; RGBA color; SurfaceProperties surfaceProps; Pipeline *pipeline; int32 refCount; static int32 numAllocated; static Material *create(void); void addRef(void) { this->refCount++; } Material *clone(void); void destroy(void); void setTexture(Texture *tex); static Material *streamRead(Stream *stream); bool streamWrite(Stream *stream); uint32 streamGetSize(void); }; void registerMaterialRightsPlugin(void); struct Mesh { uint16 *indices; uint32 numIndices; Material *material; }; struct MeshHeader { enum { TRISTRIP = 1 }; uint32 flags; uint16 numMeshes; uint16 serialNum; uint32 totalIndices; uint32 pad; // needed for alignment of Meshes // after this the meshes Mesh *getMeshes(void) { return (Mesh*)(this+1); } void setupIndices(void); uint32 guessNumTriangles(void); }; struct Geometry; struct MorphTarget { Geometry *parent; Sphere boundingSphere; V3d *vertices; V3d *normals; Sphere calculateBoundingSphere(void) const; }; struct InstanceDataHeader { uint32 platform; }; struct Triangle { uint16 v[3]; uint16 matId; }; struct MaterialList { Material **materials; int32 numMaterials; int32 space; void init(void); void deinit(void); int32 appendMaterial(Material *mat); int32 findIndex(Material *mat); static MaterialList *streamRead(Stream *stream, MaterialList *matlist); bool streamWrite(Stream *stream); uint32 streamGetSize(void); }; struct Geometry { PLUGINBASE enum { ID = 8 }; Object object; uint32 flags; uint16 lockedSinceInst; int32 numTriangles; int32 numVertices; int32 numMorphTargets; int32 numTexCoordSets; Triangle *triangles; RGBA *colors; TexCoords *texCoords[8]; MorphTarget *morphTargets; MaterialList matList; MeshHeader *meshHeader; InstanceDataHeader *instData; int32 refCount; static int32 numAllocated; static Geometry *create(int32 numVerts, int32 numTris, uint32 flags); void addRef(void) { this->refCount++; } void destroy(void); void lock(int32 lockFlags); void unlock(void); void addMorphTargets(int32 n); void calculateBoundingSphere(void); bool32 hasColoredMaterial(void); void allocateData(void); MeshHeader *allocateMeshes(int32 numMeshes, uint32 numIndices, bool32 noIndices); void generateTriangles(int8 *adc = nil); void buildMeshes(void); void buildTristrips(void); // private, used by buildMeshes void correctTristripWinding(void); void removeUnusedMaterials(void); static Geometry *streamRead(Stream *stream); bool streamWrite(Stream *stream); uint32 streamGetSize(void); enum Flags { TRISTRIP = 0x01, POSITIONS = 0x02, TEXTURED = 0x04, PRELIT = 0x08, NORMALS = 0x10, LIGHT = 0x20, MODULATE = 0x40, TEXTURED2 = 0x80, // When this flag is set the geometry has // native geometry. When streamed out this geometry // is written out instead of the platform independent data. // When streamed in with this flag, the geometry is mostly empty. NATIVE = 0x01000000, // Just for documentation: RW sets this flag // to prevent rendering when executing a pipeline, // so only instancing will occur. // librw's pipelines are different so it's unused here. NATIVEINSTANCE = 0x02000000 }; enum LockFlags { LOCKPOLYGONS = 0x0001, LOCKVERTICES = 0x0002, LOCKNORMALS = 0x0004, LOCKPRELIGHT = 0x0008, LOCKTEXCOORDS = 0x0010, LOCKTEXCOORDS1 = 0x0010, LOCKTEXCOORDS2 = 0x0020, LOCKTEXCOORDS3 = 0x0040, LOCKTEXCOORDS4 = 0x0080, LOCKTEXCOORDS5 = 0x0100, LOCKTEXCOORDS6 = 0x0200, LOCKTEXCOORDS7 = 0x0400, LOCKTEXCOORDS8 = 0x0800, LOCKTEXCOORDSALL = 0x0ff0, LOCKALL = 0x0fff }; }; void registerMeshPlugin(void); void registerNativeDataPlugin(void); struct Clump; struct World; struct Atomic { PLUGINBASE typedef void (*RenderCB)(Atomic *atomic); enum { ID = 1 }; enum { // flags COLLISIONTEST = 0x01, // unused here RENDER = 0x04, // private flags WORLDBOUNDDIRTY = 0x01, // for setGeometry SAMEBOUNDINGSPHERE = 0x01 }; ObjectWithFrame object; Geometry *geometry; Sphere boundingSphere; Sphere worldBoundingSphere; Clump *clump; LLLink inClump; ObjPipeline *pipeline; RenderCB renderCB; World *world; ObjectWithFrame::Sync originalSync; static int32 numAllocated; static Atomic *create(void); Atomic *clone(void); void destroy(void); void setFrame(Frame *f) { this->object.setFrame(f); this->object.object.privateFlags |= WORLDBOUNDDIRTY; } Frame *getFrame(void) const { return (Frame*)this->object.object.parent; } static Atomic *fromClump(LLLink *lnk){ return LLLinkGetData(lnk, Atomic, inClump); } void setGeometry(Geometry *geo, uint32 flags); Sphere *getWorldBoundingSphere(void); ObjPipeline *getPipeline(void); void instance(void); void uninstance(void); void render(void) { this->renderCB(this); } void setRenderCB(RenderCB renderCB){ this->renderCB = renderCB; if(this->renderCB == nil) this->renderCB = defaultRenderCB; }; void setFlags(uint32 flags) { this->object.object.flags = flags; } uint32 getFlags(void) const { return this->object.object.flags; } static Atomic *streamReadClump(Stream *stream, FrameList_ *frameList, Geometry **geometryList); bool streamWriteClump(Stream *stream, FrameList_ *frmlst); uint32 streamGetSize(void); static void defaultRenderCB(Atomic *atomic); }; void registerAtomicRightsPlugin(void); struct Light { PLUGINBASE enum { ID = 3 }; ObjectWithFrame object; float32 radius; RGBAf color; float32 minusCosAngle; LLLink inWorld; // clump extension Clump *clump; LLLink inClump; // world extension World *world; ObjectWithFrame::Sync originalSync; static int32 numAllocated; static Light *create(int32 type); void destroy(void); void setFrame(Frame *f) { this->object.setFrame(f); } Frame *getFrame(void) const { return (Frame*)this->object.object.parent; } static Light *fromClump(LLLink *lnk){ return LLLinkGetData(lnk, Light, inClump); } static Light *fromWorld(LLLink *lnk){ return LLLinkGetData(lnk, Light, inWorld); } void setAngle(float32 angle); float32 getAngle(void); void setColor(float32 r, float32 g, float32 b); int32 getType(void){ return this->object.object.subType; } void setFlags(uint32 flags) { this->object.object.flags = flags; } uint32 getFlags(void) { return this->object.object.flags; } static Light *streamRead(Stream *stream); bool streamWrite(Stream *stream); uint32 streamGetSize(void); enum Type { DIRECTIONAL = 1, AMBIENT, POINT = 0x80, // positioned SPOT, SOFTSPOT }; enum Flags { LIGHTATOMICS = 1, LIGHTWORLD = 2 }; }; struct FrustumPlane { Plane plane; /* Used for BBox tests: * 0 = inf is closer to normal direction * 1 = sup is closer to normal direction */ uint8 closestX; uint8 closestY; uint8 closestZ; }; struct Camera { PLUGINBASE enum { ID = 4 }; enum { PERSPECTIVE = 1, PARALLEL }; enum { CLEARIMAGE = 0x1, CLEARZ = 0x2}; // return value of frustumTestSphere enum { SPHEREOUTSIDE, SPHEREBOUNDARY, SPHEREINSIDE }; ObjectWithFrame object; void (*beginUpdateCB)(Camera*); void (*endUpdateCB)(Camera*); V2d viewWindow; V2d viewOffset; float32 nearPlane, farPlane; float32 fogPlane; int32 projection; Matrix viewMatrix; float32 zScale, zShift; FrustumPlane frustumPlanes[6]; V3d frustumCorners[8]; BBox frustumBoundBox; Raster *frameBuffer; Raster *zBuffer; // Device dependant view and projection matrices // optional RawMatrix devView; RawMatrix devProj; // clump link handled by plugin in RW Clump *clump; LLLink inClump; // world extension /* RW: frustum sectors, space, position */ World *world; ObjectWithFrame::Sync originalSync; void (*originalBeginUpdate)(Camera*); void (*originalEndUpdate)(Camera*); static int32 numAllocated; static Camera *create(void); Camera *clone(void); void destroy(void); void setFrame(Frame *f) { this->object.setFrame(f); } Frame *getFrame(void)const { return (Frame*)this->object.object.parent; } static Camera *fromClump(LLLink *lnk){ return LLLinkGetData(lnk, Camera, inClump); } void beginUpdate(void) { this->beginUpdateCB(this); } void endUpdate(void) { this->endUpdateCB(this); } void clear(RGBA *col, uint32 mode); void showRaster(void); void setNearPlane(float32); void setFarPlane(float32); void setViewWindow(const V2d *window); void setViewOffset(const V2d *offset); void setProjection(int32 proj); int32 frustumTestSphere(const Sphere *s) const; static Camera *streamRead(Stream *stream); bool streamWrite(Stream *stream); uint32 streamGetSize(void); // fov in degrees void setFOV(float32 fov, float32 ratio); }; struct Clump { PLUGINBASE enum { ID = 2 }; Object object; LinkList atomics; LinkList lights; LinkList cameras; World *world; LLLink inWorld; static int32 numAllocated; static Clump *create(void); Clump *clone(void); void destroy(void); static Clump *fromWorld(LLLink *lnk){ return LLLinkGetData(lnk, Clump, inWorld); } int32 countAtomics(void) { return this->atomics.count(); } void addAtomic(Atomic *a); void removeAtomic(Atomic *a); int32 countLights(void) { return this->lights.count(); } void addLight(Light *l); void removeLight(Light *l); int32 countCameras(void) { return this->cameras.count(); } void addCamera(Camera *c); void removeCamera(Camera *c); void setFrame(Frame *f){ this->object.parent = f; } Frame *getFrame(void) const { return (Frame*)this->object.parent; } static Clump *streamRead(Stream *stream); bool streamWrite(Stream *stream); uint32 streamGetSize(void); void render(void); }; // used by enumerateLights for lighting callback struct WorldLights { int32 numAmbients; RGBAf ambient; // all ambients added int32 numDirectionals; Light **directionals; // only directionals int32 numLocals; Light **locals; // points, (soft)spots }; // A bit of a stub right now struct World { PLUGINBASE enum { ID = 7 }; Object object; LinkList localLights; // these have positions (type >= 0x80) LinkList globalLights; // these do not (type < 0x80) LinkList clumps; static int32 numAllocated; static World *create(void); void destroy(void); void addLight(Light *light); void removeLight(Light *light); void addCamera(Camera *cam); void removeCamera(Camera *cam); void addAtomic(Atomic *atomic); void removeAtomic(Atomic *atomic); void addClump(Clump *clump); void removeClump(Clump *clump); void render(void); void enumerateLights(Atomic *atomic, WorldLights *lightData); }; struct TexDictionary { PLUGINBASE enum { ID = 6 }; Object object; LinkList textures; LLLink inGlobalList; static int32 numAllocated; static TexDictionary *create(void); static TexDictionary *fromLink(LLLink *lnk){ return LLLinkGetData(lnk, TexDictionary, inGlobalList); } void destroy(void); int32 count(void) { return this->textures.count(); } void add(Texture *t); void addFront(Texture *t); void remove(Texture *t); Texture *find(const char *name); static TexDictionary *streamRead(Stream *stream); void streamWrite(Stream *stream); uint32 streamGetSize(void); static void setCurrent(TexDictionary *txd); static TexDictionary *getCurrent(void); }; }