/*************************************************************************/ /* rasterizer_canvas_gles2.h */ /*************************************************************************/ /* This file is part of: */ /* GODOT ENGINE */ /* https://godotengine.org */ /*************************************************************************/ /* Copyright (c) 2007-2020 Juan Linietsky, Ariel Manzur. */ /* Copyright (c) 2014-2020 Godot Engine contributors (cf. AUTHORS.md). */ /* */ /* Permission is hereby granted, free of charge, to any person obtaining */ /* a copy of this software and associated documentation files (the */ /* "Software"), to deal in the Software without restriction, including */ /* without limitation the rights to use, copy, modify, merge, publish, */ /* distribute, sublicense, and/or sell copies of the Software, and to */ /* permit persons to whom the Software is furnished to do so, subject to */ /* the following conditions: */ /* */ /* The above copyright notice and this permission notice shall be */ /* included in all copies or substantial portions of the Software. */ /* */ /* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */ /* EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF */ /* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT.*/ /* IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY */ /* CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, */ /* TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE */ /* SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ /*************************************************************************/ #ifndef RASTERIZERCANVASGLES2_H #define RASTERIZERCANVASGLES2_H #include "rasterizer_canvas_base_gles2.h" class RasterizerSceneGLES2; class RasterizerCanvasGLES2 : public RasterizerCanvasBaseGLES2 { // used to determine whether we use hardware transform (none) // software transform all verts, or software transform just a translate // (no rotate or scale) enum TransformMode { TM_NONE, TM_ALL, TM_TRANSLATE, }; // pod versions of vector and color and RID, need to be 32 bit for vertex format struct BatchVector2 { float x, y; void set(const Vector2 &p_o) { x = p_o.x; y = p_o.y; } void to(Vector2 &r_o) const { r_o.x = x; r_o.y = y; } }; struct BatchColor { float r, g, b, a; void set(const Color &p_c) { r = p_c.r; g = p_c.g; b = p_c.b; a = p_c.a; } bool operator==(const BatchColor &p_c) const { return (r == p_c.r) && (g == p_c.g) && (b == p_c.b) && (a == p_c.a); } bool operator!=(const BatchColor &p_c) const { return (*this == p_c) == false; } bool equals(const Color &p_c) const { return (r == p_c.r) && (g == p_c.g) && (b == p_c.b) && (a == p_c.a); } const float *get_data() const { return &r; } String to_string() const; }; struct BatchVertex { // must be 32 bit pod BatchVector2 pos; BatchVector2 uv; }; struct BatchVertexColored : public BatchVertex { // must be 32 bit pod BatchColor col; }; struct Batch { enum CommandType : uint32_t { BT_DEFAULT, BT_RECT, }; CommandType type; uint32_t first_command; // also item reference number uint32_t num_commands; uint32_t first_quad; uint32_t batch_texture_id; BatchColor color; }; struct BatchTex { enum TileMode : uint32_t { TILE_OFF, TILE_NORMAL, TILE_FORCE_REPEAT, }; RID RID_texture; RID RID_normal; TileMode tile_mode; BatchVector2 tex_pixel_size; }; // items in a list to be sorted prior to joining struct BSortItem { // have a function to keep as pod, rather than operator void assign(const BSortItem &o) { item = o.item; z_index = o.z_index; } Item *item; int z_index; }; // batch item may represent 1 or more items struct BItemJoined { uint32_t first_item_ref; uint32_t num_item_refs; Rect2 bounding_rect; // note the z_index may only be correct for the first of the joined item references // this has implications for light culling with z ranged lights. int z_index; // we are always splitting items with lots of commands, // and items with unhandled primitives (default) bool use_hardware_transform() const { return num_item_refs == 1; } }; struct BItemRef { Item *item; Color final_modulate; }; struct BLightRegion { void reset() { light_bitfield = 0; shadow_bitfield = 0; too_many_lights = false; } uint64_t light_bitfield; uint64_t shadow_bitfield; bool too_many_lights; // we can only do light region optimization if there are 64 or less lights }; struct BatchData { BatchData(); void reset_flush() { batches.reset(); batch_textures.reset(); vertices.reset(); total_quads = 0; total_color_changes = 0; } GLuint gl_vertex_buffer; GLuint gl_index_buffer; uint32_t max_quads; uint32_t vertex_buffer_size_units; uint32_t vertex_buffer_size_bytes; uint32_t index_buffer_size_units; uint32_t index_buffer_size_bytes; RasterizerArrayGLES2 vertices; RasterizerArrayGLES2 vertices_colored; RasterizerArrayGLES2 batches; RasterizerArrayGLES2 batches_temp; // used for translating to colored vertex batches RasterizerArray_non_pod_GLES2 batch_textures; // the only reason this is non-POD is because of RIDs bool use_colored_vertices; RasterizerArrayGLES2 items_joined; RasterizerArrayGLES2 item_refs; // items are sorted prior to joining RasterizerArrayGLES2 sort_items; // counts int total_quads; // we keep a record of how many color changes caused new batches // if the colors are causing an excessive number of batches, we switch // to alternate batching method and add color to the vertex format. int total_color_changes; // if the shader is using MODULATE, we prevent baking so the final_modulate can // be read in the shader bool prevent_color_baking; // measured in pixels, recalculated each frame float scissor_threshold_area; // diagnose this frame, every nTh frame when settings_diagnose_frame is on bool diagnose_frame; String frame_string; uint32_t next_diagnose_tick; uint64_t diagnose_frame_number; // whether to join items across z_indices - this can interfere with z ranged lights, // so has to be disabled in some circumstances bool join_across_z_indices; // global settings bool settings_use_batching; // the current use_batching (affected by flash) bool settings_use_batching_original_choice; // the choice entered in project settings bool settings_flash_batching; // for regression testing, flash between non-batched and batched renderer bool settings_diagnose_frame; // print out batches to help optimize / regression test int settings_max_join_item_commands; float settings_colored_vertex_format_threshold; int settings_batch_buffer_num_verts; bool settings_scissor_lights; float settings_scissor_threshold; // 0.0 to 1.0 int settings_item_reordering_lookahead; bool settings_use_single_rect_fallback; int settings_light_max_join_items; // only done on diagnose frame void reset_stats() { stats_items_sorted = 0; stats_light_items_joined = 0; } // frame stats (just for monitoring and debugging) int stats_items_sorted; int stats_light_items_joined; } bdata; struct RenderItemState { RenderItemState() { reset(); } void reset(); Item *current_clip; RasterizerStorageGLES2::Shader *shader_cache; bool rebind_shader; bool prev_use_skeleton; int last_blend_mode; RID canvas_last_material; Color final_modulate; // used for joining items only BItemJoined *joined_item; bool join_batch_break; BLightRegion light_region; // 'item group' is data over a single call to canvas_render_items int item_group_z; Color item_group_modulate; Light *item_group_light; Transform2D item_group_base_transform; } _render_item_state; struct FillState { void reset() { // don't reset members that need to be preserved after flushing // half way through a list of commands curr_batch = 0; batch_tex_id = -1; texpixel_size = Vector2(1, 1); } Batch *curr_batch; int batch_tex_id; bool use_hardware_transform; Vector2 texpixel_size; Color final_modulate; TransformMode transform_mode; TransformMode orig_transform_mode; // support for extra matrices bool extra_matrix_sent; // whether sent on this item (in which case sofware transform can't be used untl end of item) int transform_extra_command_number_p1; // plus one to allow fast checking against zero Transform2D transform_combined; // final * extra }; public: virtual void canvas_render_items_begin(const Color &p_modulate, Light *p_light, const Transform2D &p_base_transform); virtual void canvas_render_items_end(); virtual void canvas_render_items(Item *p_item_list, int p_z, const Color &p_modulate, Light *p_light, const Transform2D &p_base_transform); virtual void canvas_begin(); virtual void canvas_end(); private: // legacy codepath .. to remove after testing void _canvas_render_item(Item *p_ci, RenderItemState &r_ris); _FORCE_INLINE_ void _canvas_item_render_commands(Item *p_item, Item *p_current_clip, bool &r_reclip, RasterizerStorageGLES2::Material *p_material); // high level batch funcs void canvas_render_items_implementation(Item *p_item_list, int p_z, const Color &p_modulate, Light *p_light, const Transform2D &p_base_transform); void render_joined_item(const BItemJoined &p_bij, RenderItemState &r_ris); void record_items(Item *p_item_list, int p_z); void join_items(Item *p_item_list, int p_z); void join_sorted_items(); bool try_join_item(Item *p_ci, RenderItemState &r_ris, bool &r_batch_break); void render_joined_item_commands(const BItemJoined &p_bij, Item *p_current_clip, bool &r_reclip, RasterizerStorageGLES2::Material *p_material, bool p_lit); void render_batches(Item::Command *const *p_commands, Item *p_current_clip, bool &r_reclip, RasterizerStorageGLES2::Material *p_material); bool prefill_joined_item(FillState &r_fill_state, int &r_command_start, Item *p_item, Item *p_current_clip, bool &r_reclip, RasterizerStorageGLES2::Material *p_material); void flush_render_batches(Item *p_first_item, Item *p_current_clip, bool &r_reclip, RasterizerStorageGLES2::Material *p_material); // low level batch funcs void _batch_translate_to_colored(); _FORCE_INLINE_ int _batch_find_or_create_tex(const RID &p_texture, const RID &p_normal, bool p_tile, int p_previous_match); RasterizerStorageGLES2::Texture *_get_canvas_texture(const RID &p_texture) const; void _batch_upload_buffers(); void _batch_render_rects(const Batch &p_batch, RasterizerStorageGLES2::Material *p_material); BatchVertex *_batch_vertex_request_new() { return bdata.vertices.request(); } Batch *_batch_request_new(bool p_blank = true); bool _detect_batch_break(Item *p_ci); void _software_transform_vertex(BatchVector2 &r_v, const Transform2D &p_tr) const; void _software_transform_vertex(Vector2 &r_v, const Transform2D &p_tr) const; TransformMode _find_transform_mode(const Transform2D &p_tr) const; _FORCE_INLINE_ void _prefill_default_batch(FillState &r_fill_state, int p_command_num, const Item &p_item); // sorting void sort_items(); bool sort_items_from(int p_start); bool _sort_items_match(const BSortItem &p_a, const BSortItem &p_b) const; // light scissoring bool _light_find_intersection(const Rect2 &p_item_rect, const Transform2D &p_light_xform, const Rect2 &p_light_rect, Rect2 &r_cliprect) const; bool _light_scissor_begin(const Rect2 &p_item_rect, const Transform2D &p_light_xform, const Rect2 &p_light_rect) const; void _calculate_scissor_threshold_area(); // no need to compile these in in release, they are unneeded outside the editor and only add to executable size #ifdef DEBUG_ENABLED void diagnose_batches(Item::Command *const *p_commands); String get_command_type_string(const Item::Command &p_command) const; #endif public: void initialize(); RasterizerCanvasGLES2(); }; ////////////////////////////////////////////////////////////// // Default batches will not occur in software transform only items // EXCEPT IN THE CASE OF SINGLE RECTS (and this may well not occur, check the logic in prefill_join_item TYPE_RECT) // but can occur where transform commands have been sent during hardware batch _FORCE_INLINE_ void RasterizerCanvasGLES2::_prefill_default_batch(FillState &r_fill_state, int p_command_num, const Item &p_item) { if (r_fill_state.curr_batch->type == Batch::BT_DEFAULT) { // don't need to flush an extra transform command? if (!r_fill_state.transform_extra_command_number_p1) { // another default command, just add to the existing batch r_fill_state.curr_batch->num_commands++; } else { #ifdef DEBUG_ENABLED if (r_fill_state.transform_extra_command_number_p1 != p_command_num) { WARN_PRINT_ONCE("_prefill_default_batch : transform_extra_command_number_p1 != p_command_num"); } #endif // we do have a pending extra transform command to flush // either the extra transform is in the prior command, or not, in which case we need 2 batches r_fill_state.curr_batch->num_commands += 2; r_fill_state.transform_extra_command_number_p1 = 0; // mark as sent r_fill_state.extra_matrix_sent = true; // the original mode should always be hardware transform .. // test this assumption //CRASH_COND(r_fill_state.orig_transform_mode != TM_NONE); r_fill_state.transform_mode = r_fill_state.orig_transform_mode; // do we need to restore anything else? } } else { // end of previous different type batch, so start new default batch // first consider whether there is a dirty extra matrix to send if (r_fill_state.transform_extra_command_number_p1) { // get which command the extra is in, and blank all the records as it no longer is stored CPU side int extra_command = r_fill_state.transform_extra_command_number_p1 - 1; // plus 1 based r_fill_state.transform_extra_command_number_p1 = 0; r_fill_state.extra_matrix_sent = true; // send the extra to the GPU in a batch r_fill_state.curr_batch = _batch_request_new(); r_fill_state.curr_batch->type = Batch::BT_DEFAULT; r_fill_state.curr_batch->first_command = extra_command; r_fill_state.curr_batch->num_commands = 1; // revert to the original transform mode // e.g. go back to NONE if we were in hardware transform mode r_fill_state.transform_mode = r_fill_state.orig_transform_mode; // reset the original transform if we are going back to software mode, // because the extra is now done on the GPU... // (any subsequent extras are sent directly to the GPU, no deferring) if (r_fill_state.orig_transform_mode != TM_NONE) { r_fill_state.transform_combined = p_item.final_transform; } // can possibly combine batch with the next one in some cases // this is more efficient than having an extra batch especially for the extra if ((extra_command + 1) == p_command_num) { r_fill_state.curr_batch->num_commands = 2; return; } } // start default batch r_fill_state.curr_batch = _batch_request_new(); r_fill_state.curr_batch->type = Batch::BT_DEFAULT; r_fill_state.curr_batch->first_command = p_command_num; r_fill_state.curr_batch->num_commands = 1; } } _FORCE_INLINE_ void RasterizerCanvasGLES2::_software_transform_vertex(BatchVector2 &r_v, const Transform2D &p_tr) const { Vector2 vc(r_v.x, r_v.y); vc = p_tr.xform(vc); r_v.set(vc); } _FORCE_INLINE_ void RasterizerCanvasGLES2::_software_transform_vertex(Vector2 &r_v, const Transform2D &p_tr) const { r_v = p_tr.xform(r_v); } _FORCE_INLINE_ RasterizerCanvasGLES2::TransformMode RasterizerCanvasGLES2::_find_transform_mode(const Transform2D &p_tr) const { // decided whether to do translate only for software transform if ((p_tr.elements[0].x == 1.0) && (p_tr.elements[0].y == 0.0) && (p_tr.elements[1].x == 0.0) && (p_tr.elements[1].y == 1.0)) { return TM_TRANSLATE; } return TM_ALL; } _FORCE_INLINE_ bool RasterizerCanvasGLES2::_sort_items_match(const BSortItem &p_a, const BSortItem &p_b) const { const Item *a = p_a.item; const Item *b = p_b.item; if (b->commands.size() != 1) return false; // tested outside function // if (a->commands.size() != 1) // return false; const Item::Command &cb = *b->commands[0]; if (cb.type != Item::Command::TYPE_RECT) return false; const Item::Command &ca = *a->commands[0]; // tested outside function // if (ca.type != Item::Command::TYPE_RECT) // return false; const Item::CommandRect *rect_a = static_cast(&ca); const Item::CommandRect *rect_b = static_cast(&cb); if (rect_a->texture != rect_b->texture) return false; return true; } #endif // RASTERIZERCANVASGLES2_H