godot/drivers/gles2/rasterizer_canvas_gles2.h

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/*************************************************************************/
/* 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). */
/* */
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/* a copy of this software and associated documentation files (the */
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/* the following conditions: */
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/* The above copyright notice and this permission notice shall be */
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/* */
/* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, */
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#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;
};
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
// 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;
};
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
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<BatchVertex> vertices;
RasterizerArrayGLES2<BatchVertexColored> vertices_colored;
RasterizerArrayGLES2<Batch> batches;
RasterizerArrayGLES2<Batch> batches_temp; // used for translating to colored vertex batches
RasterizerArray_non_pod_GLES2<BatchTex> batch_textures; // the only reason this is non-POD is because of RIDs
bool use_colored_vertices;
RasterizerArrayGLES2<BItemJoined> items_joined;
RasterizerArrayGLES2<BItemRef> item_refs;
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
// items are sorted prior to joining
RasterizerArrayGLES2<BSortItem> 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
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
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;
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
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();
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
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);
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
void record_items(Item *p_item_list, int p_z);
void join_items(Item *p_item_list, int p_z);
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
void join_sorted_items();
bool try_join_item(Item *p_ci, RenderItemState &r_ris, bool &r_batch_break);
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
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);
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
// 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;
}
GLES2 2D batching - item reordering, light joining and light modulate fix Although 2D draws in painters order with strict ordering, in certain circumstances items can be reordered to increase batching / decrease state changes, without affecting the end result. This can be determined by an overlap test. In situation with item: A-B-A providing the third item does not overlap the second, they can be reordered: A-A-B Items already contain an AABB which can be used for this overlap test. 1) To utilise this, I have implemented item reordering (only for single rects for now), with the lookahead adjustable in project settings. This can increase performance in situations where items may not be grouped in the scene tree by texture. It can also be switched off (by setting lookahead to 0). 2) This same trick can be used to help join items that are lit. Lit items previously would prevent joining completely, thus missing out on performance gains other than multi-command items such as tilemaps. In this PR, lights are assigned as bits in a bitfield (up to 64, the optimization is disabled above this), and on each try_item (for joining), the bitfield for lights and shadows is constructed and compared with the previous items. If these match the 2 items can potentially be joined. However, this can only be done without changing the rendered result if an overlap test is successful. This overlap test can be adjusted to join items up to a specific number of item references, selectable in project settings, or turned off. 3) The legacy uniform single rect drawing routine seems to have been identified as the source of flicker, particularly on nvidia. However, it can also be up to 2x as fast. Because of the speed the batching contains a fallback where it can use the legacy single rect method, but I have now added a project setting to make this switchable. In most cases with batching it should not be necessary (as single rects are drawn less frequently) and thus the flickering can be totally avoided. 4) This PR also fixes a color modulate bug when drawing light passes, in certain situations (particularly custom _draw routines with multiple rects). 5) This PR also fixes #38291, a bug in the legacy renderer where light passes could draw rects in wrong position.
2020-04-29 07:24:43 +00:00
_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<const Item::CommandRect *>(&ca);
const Item::CommandRect *rect_b = static_cast<const Item::CommandRect *>(&cb);
if (rect_a->texture != rect_b->texture)
return false;
return true;
}
#endif // RASTERIZERCANVASGLES2_H