historical/toontown-classic.git/panda/include/graphicsEngine.h
2024-01-16 11:20:27 -06:00

422 lines
16 KiB
C++

/**
* PANDA 3D SOFTWARE
* Copyright (c) Carnegie Mellon University. All rights reserved.
*
* All use of this software is subject to the terms of the revised BSD
* license. You should have received a copy of this license along
* with this source code in a file named "LICENSE."
*
* @file graphicsEngine.h
* @author drose
* @date 2002-02-24
*/
#ifndef GRAPHICSENGINE_H
#define GRAPHICSENGINE_H
#include "pandabase.h"
#include "graphicsWindow.h"
#include "graphicsBuffer.h"
#include "frameBufferProperties.h"
#include "graphicsThreadingModel.h"
#include "sceneSetup.h"
#include "pointerTo.h"
#include "thread.h"
#include "pmutex.h"
#include "reMutex.h"
#include "lightReMutex.h"
#include "conditionVar.h"
#include "pStatCollector.h"
#include "pset.h"
#include "ordered_vector.h"
#include "indirectLess.h"
#include "loader.h"
#include "referenceCount.h"
class Pipeline;
class DisplayRegion;
class GraphicsPipe;
class FrameBufferProperties;
class Texture;
/**
* This class is the main interface to controlling the render process. There
* is typically only one GraphicsEngine in an application, and it synchronizes
* rendering to all all of the active windows; although it is possible to have
* multiple GraphicsEngine objects if multiple synchronicity groups are
* required.
*
* The GraphicsEngine is responsible for managing the various cull and draw
* threads. The application simply calls engine->render_frame() and considers
* it done.
*/
class EXPCL_PANDA_DISPLAY GraphicsEngine : public ReferenceCount {
PUBLISHED:
explicit GraphicsEngine(Pipeline *pipeline = nullptr);
BLOCKING ~GraphicsEngine();
void set_threading_model(const GraphicsThreadingModel &threading_model);
GraphicsThreadingModel get_threading_model() const;
MAKE_PROPERTY(threading_model, get_threading_model, set_threading_model);
INLINE const ReMutex &get_render_lock() const;
MAKE_PROPERTY(render_lock, get_render_lock);
INLINE void set_auto_flip(bool auto_flip);
INLINE bool get_auto_flip() const;
MAKE_PROPERTY(auto_flip, get_auto_flip, set_auto_flip);
INLINE void set_portal_cull(bool value);
INLINE bool get_portal_cull() const;
MAKE_PROPERTY(portal_cull, get_portal_cull, set_portal_cull);
INLINE void set_default_loader(Loader *loader);
INLINE Loader *get_default_loader() const;
MAKE_PROPERTY(default_loader, get_default_loader, set_default_loader);
GraphicsOutput *make_output(GraphicsPipe *pipe,
const std::string &name, int sort,
const FrameBufferProperties &fb_prop,
const WindowProperties &win_prop,
int flags, GraphicsStateGuardian *gsg = nullptr,
GraphicsOutput *host = nullptr);
// Syntactic shorthand versions of make_output
INLINE GraphicsOutput *make_buffer(GraphicsOutput *host,
const std::string &name, int sort,
int x_size, int y_size);
INLINE GraphicsOutput *make_buffer(GraphicsStateGuardian *gsg,
const std::string &name, int sort,
int x_size, int y_size);
INLINE GraphicsOutput *make_parasite(GraphicsOutput *host,
const std::string &name, int sort,
int x_size, int y_size);
bool add_window(GraphicsOutput *window, int sort);
bool remove_window(GraphicsOutput *window);
BLOCKING void remove_all_windows();
void reset_all_windows(bool swapchain);
bool is_empty() const;
int get_num_windows() const;
GraphicsOutput *get_window(int n) const;
MAKE_SEQ(get_windows, get_num_windows, get_window);
MAKE_SEQ_PROPERTY(windows, get_num_windows, get_window);
BLOCKING void render_frame();
BLOCKING void open_windows();
BLOCKING void sync_frame();
BLOCKING void ready_flip();
BLOCKING void flip_frame();
bool extract_texture_data(Texture *tex, GraphicsStateGuardian *gsg);
void dispatch_compute(const LVecBase3i &work_groups,
const ShaderAttrib *sattr,
GraphicsStateGuardian *gsg);
static GraphicsEngine *get_global_ptr();
public:
enum ThreadState {
TS_wait,
TS_do_frame,
TS_do_flip,
TS_do_release,
TS_do_windows,
TS_do_compute,
TS_do_extract,
TS_do_screenshot,
TS_terminate,
TS_done
};
void texture_uploaded(Texture *tex);
PT(Texture) do_get_screenshot(DisplayRegion *region, GraphicsStateGuardian *gsg);
public:
static void do_cull(CullHandler *cull_handler, SceneSetup *scene_setup,
GraphicsStateGuardian *gsg, Thread *current_thread);
private:
typedef ov_set< PT(GraphicsOutput), IndirectLess<GraphicsOutput> > Windows;
typedef pset< PT(GraphicsStateGuardian) > GSGs;
static bool scene_root_func(const PandaNode *node);
bool is_scene_root(const PandaNode *node);
void set_window_sort(GraphicsOutput *window, int sort);
void cull_and_draw_together(Windows wlist, Thread *current_thread);
void cull_and_draw_together(GraphicsOutput *win, DisplayRegion *dr,
Thread *current_thread);
void cull_to_bins(Windows wlist, Thread *current_thread);
void cull_to_bins(GraphicsOutput *win, GraphicsStateGuardian *gsg,
DisplayRegion *dr, SceneSetup *scene_setup,
CullResult *cull_result, Thread *current_thread);
void draw_bins(const Windows &wlist, Thread *current_thread);
void make_contexts(const Windows &wlist, Thread *current_thread);
void process_events(const Windows &wlist, Thread *current_thread);
void ready_flip_windows(const Windows &wlist, Thread *current_thread);
void flip_windows(const Windows &wlist, Thread *current_thread);
void do_sync_frame(Thread *current_thread);
void do_ready_flip(Thread *current_thread);
void do_flip_frame(Thread *current_thread);
INLINE void close_gsg(GraphicsPipe *pipe, GraphicsStateGuardian *gsg);
PT(SceneSetup) setup_scene(GraphicsStateGuardian *gsg,
DisplayRegionPipelineReader *dr);
void do_draw(GraphicsOutput *win, GraphicsStateGuardian *gsg,
DisplayRegion *dr, Thread *current_thread);
void do_add_window(GraphicsOutput *window);
void do_add_gsg(GraphicsStateGuardian *gsg, GraphicsPipe *pipe);
void do_remove_window(GraphicsOutput *window, Thread *current_thread);
void do_resort_windows();
void terminate_threads(Thread *current_thread);
void auto_adjust_capabilities(GraphicsStateGuardian *gsg);
#ifdef DO_PSTATS
typedef std::map<TypeHandle, PStatCollector> CyclerTypeCounters;
CyclerTypeCounters _all_cycler_types;
CyclerTypeCounters _dirty_cycler_types;
static void pstats_count_cycler_type(TypeHandle type, int count, void *data);
static void pstats_count_dirty_cycler_type(TypeHandle type, int count, void *data);
#endif // DO_PSTATS
static const RenderState *get_invert_polygon_state();
// The WindowRenderer class records the stages of the pipeline that each
// thread (including the main thread, a.k.a. "app") should process, and the
// list of windows for each stage.
// There is one WindowRenderer instance for app, and another instance for
// each thread (the thread-specific WindowRenderers are actually instances
// of RenderThread, below, which inherits from WindowRenderer).
// The idea is that each window is associated with one or more
// WindowRenderer objects, according to the threads in which its rendering
// tasks (window, cull, and draw) are divided into.
// The "window" task is responsible for doing any updates to the window
// itself, such as size and placement, and is wholly responsible for any API
// calls to the windowing system itself, unrelated to OpenGL-type calls.
// This is normally done in app (the design of X-Windows is such that all X
// calls must be issued in the same thread).
// The "cull" task is responsible for crawling through the scene graph and
// discovering all of the Geoms that are within the viewing frustum. It
// assembles all such Geoms, along with their computed net state and
// transform, in a linked list of CullableObjects, which it stores for the
// "draw" task, next.
// The "draw" task is responsible for walking through the list of
// CullableObjects recorded by the cull task, and issuing the appropriate
// graphics commands to draw them.
// There is an additional task, not often used, called "cdraw". This task,
// if activated, will crawl through the scene graph and issue graphics
// commands immediately, as each Geom is discovered. It is only rarely used
// because it cannot perform sorting beyond basic scene graph order, making
// it less useful than a separate cull and draw task.
// It is possible for all three of the normal tasks: window, cull, and draw,
// to be handled by the same thread. This is the normal, single-threaded
// model: all tasks are handled by the app thread. In this case, the window
// will be added to _app's _window, _cull, and _draw lists.
/*
* On the other hand, a window's tasks may also be distributed among as many
* as three threads. For instance, if the window is listed on _app's _window
* list, but on thread A's _cull list, and thread B's _draw list, then the
* window task will be handled in the app thread, while the cull task will be
* handled by thread A, and the draw task will be handled (in parallel) by
* thread B. (In order for this to work, it will be necessary that thread A
* and B are configured to view different stages of the graphics pipeline.
* This is a more advanced topic than there is room to discuss in this
* comment.)
*/
// Manipulation of the various window lists in each WindowRenderer object is
// always performed in the app thread. The auxiliary threads are slaves to
// the app thread, and they can only perform one of a handful of specified
// tasks, none of which includes adding or removing windows from its lists.
// The full set of tasks that a WindowRenderer may perform is enumerated in
// ThreadState, above; see RenderThread::thread_main().
/*
* There is a pair of condition variables for each thread, _cv_start and
* _cv_done, that is used to synchronize requests made by app to a particular
* thread. The usual procedure to request a thread to perform a particular
* task is the following: the app thread waits on the thread's _cv_done
* variable, stores the value corresponding to the desired task in the
* thread's _thread_state value, then signals the thread's _cv_start variable.
* The thread, in turn, will perform its requested task, set its _thread_state
* to TS_wait, and signal _cv_done. See examples in the code, e.g.
* open_windows(), for more details on this process.
*/
// It is of course not necessary to signal any threads in order to perform
// tasks listed in the _app WindowRenderer. For this object only, we simply
// call the appropriate methods on _app when we want the tasks to be
// performed.
class WindowRenderer {
public:
WindowRenderer(const std::string &name);
void add_gsg(GraphicsStateGuardian *gsg);
void add_window(Windows &wlist, GraphicsOutput *window);
void remove_window(GraphicsOutput *window);
void resort_windows();
void do_frame(GraphicsEngine *engine, Thread *current_thread);
void do_windows(GraphicsEngine *engine, Thread *current_thread);
void do_ready_flip(GraphicsEngine *engine, Thread *current_thread);
void do_flip(GraphicsEngine *engine, Thread *current_thread);
void do_release(GraphicsEngine *engine, Thread *current_thread);
void do_close(GraphicsEngine *engine, Thread *current_thread);
void do_pending(GraphicsEngine *engine, Thread *current_thread);
bool any_done_gsgs() const;
public:
Windows _cull; // cull stage
Windows _cdraw; // cull-and-draw-together stage
Windows _draw; // draw stage
Windows _window; // window stage, i.e. process windowing events
// These are not kept sorted.
Windows _pending_close; // moved from _window, pending close.
GSGs _gsgs; // draw stage
LightReMutex _wl_lock;
};
class RenderThread : public Thread, public WindowRenderer {
public:
RenderThread(const std::string &name, GraphicsEngine *engine);
virtual void thread_main();
GraphicsEngine *_engine;
Mutex _cv_mutex;
ConditionVar _cv_start;
ConditionVar _cv_done;
ThreadState _thread_state;
// These are stored for extract_texture_data and dispatch_compute.
GraphicsStateGuardian *_gsg;
PT(Texture) _texture;
const RenderState *_state;
DisplayRegion *_region;
LVecBase3i _work_groups;
bool _result;
};
WindowRenderer *get_window_renderer(const std::string &name, int pipeline_stage);
Pipeline *_pipeline;
Windows _windows;
bool _windows_sorted;
// This lock protects the next two fields.
Mutex _new_windows_lock;
unsigned int _window_sort_index;
pvector<PT(GraphicsOutput)> _new_windows;
WindowRenderer _app;
typedef pmap<std::string, PT(RenderThread) > Threads;
Threads _threads;
GraphicsThreadingModel _threading_model;
bool _auto_flip;
bool _portal_enabled; //toggle to portal culling on/off
PT(Loader) _default_loader;
enum FlipState {
FS_draw, // Still drawing.
FS_sync, // All windows are done drawing.
FS_flip, // All windows are done drawing and have flipped.
};
FlipState _flip_state;
bool _singular_warning_last_frame;
bool _singular_warning_this_frame;
ReMutex _lock;
ReMutex _public_lock;
class LoadedTexture {
public:
PT(Texture) _tex;
UpdateSeq _image_modified;
};
typedef pvector<LoadedTexture> LoadedTextures;
LoadedTextures _loaded_textures;
Mutex _loaded_textures_lock;
static PT(GraphicsEngine) _global_ptr;
static PStatCollector _wait_pcollector;
static PStatCollector _cycle_pcollector;
static PStatCollector _app_pcollector;
static PStatCollector _render_frame_pcollector;
static PStatCollector _do_frame_pcollector;
static PStatCollector _yield_pcollector;
static PStatCollector _cull_pcollector;
static PStatCollector _cull_setup_pcollector;
static PStatCollector _cull_sort_pcollector;
static PStatCollector _draw_pcollector;
static PStatCollector _sync_pcollector;
static PStatCollector _flip_pcollector;
static PStatCollector _flip_begin_pcollector;
static PStatCollector _flip_end_pcollector;
static PStatCollector _transform_states_pcollector;
static PStatCollector _transform_states_unused_pcollector;
static PStatCollector _render_states_pcollector;
static PStatCollector _render_states_unused_pcollector;
static PStatCollector _cyclers_pcollector;
static PStatCollector _dirty_cyclers_pcollector;
static PStatCollector _delete_pcollector;
static PStatCollector _sw_sprites_pcollector;
static PStatCollector _vertex_data_small_pcollector;
static PStatCollector _vertex_data_independent_pcollector;
static PStatCollector _vertex_data_pending_pcollector;
static PStatCollector _vertex_data_resident_pcollector;
static PStatCollector _vertex_data_compressed_pcollector;
static PStatCollector _vertex_data_used_disk_pcollector;
static PStatCollector _vertex_data_unused_disk_pcollector;
static PStatCollector _cnode_volume_pcollector;
static PStatCollector _gnode_volume_pcollector;
static PStatCollector _geom_volume_pcollector;
static PStatCollector _node_volume_pcollector;
static PStatCollector _volume_pcollector;
static PStatCollector _test_pcollector;
static PStatCollector _volume_polygon_pcollector;
static PStatCollector _test_polygon_pcollector;
static PStatCollector _volume_plane_pcollector;
static PStatCollector _test_plane_pcollector;
static PStatCollector _volume_sphere_pcollector;
static PStatCollector _test_sphere_pcollector;
static PStatCollector _volume_box_pcollector;
static PStatCollector _test_box_pcollector;
static PStatCollector _volume_capsule_pcollector;
static PStatCollector _test_capsule_pcollector;
static PStatCollector _volume_inv_sphere_pcollector;
static PStatCollector _test_inv_sphere_pcollector;
static PStatCollector _volume_geom_pcollector;
static PStatCollector _test_geom_pcollector;
static PStatCollector _occlusion_untested_pcollector;
static PStatCollector _occlusion_passed_pcollector;
static PStatCollector _occlusion_failed_pcollector;
static PStatCollector _occlusion_tests_pcollector;
friend class WindowRenderer;
friend class GraphicsOutput;
};
#include "graphicsEngine.I"
#endif