RhythmGame/NoteHandler.gd

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19 KiB
GDScript3
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extends "res://main.gd"
# This script will draw all note events.
var tex := preload("res://assets/spritesheet-1024.png")
var tex_slide_arrow := preload("res://assets/slide-arrow-512.png")
var slide_trail_shadermaterial := preload("res://shaders/slidetrail.tres")
# Constants for the overall notefield
var RADIAL_COL_ANGLES := PoolRealArray() # ideally const
var RADIAL_UNIT_VECTORS := PoolVector2Array() # ideally const
# ------------------------------------------------------
# Ring segments is only for CPU drawing, superceded for now.
# ------------------------------------------------------
#const RING_LINE_SEGMENTS_PER_COLUMN := 12
#var RING_LINE_SEGMENTS_VECTORS := PoolVector2Array()
#const ring_segs := Rules.COLS * RING_LINE_SEGMENTS_PER_COLUMN
#const ring_seg_angle := 360.0/ring_segs
#var ring_line_segments_alphas = PoolRealArray()
#var ring_line_segments_widths = PoolRealArray()
func init_radial_values():
for i in range(Rules.COLS):
var angle = deg2rad(fmod(Rules.FIRST_COLUMN_ANGLE_DEG + (i * Rules.COLS_ANGLE_DEG), 360.0))
RADIAL_COL_ANGLES.push_back(angle)
RADIAL_UNIT_VECTORS.push_back(Vector2(cos(angle), sin(angle)))
# for i in range(ring_segs):
# var angle = deg2rad(Rules.FIRST_COLUMN_ANGLE_DEG + (i * ring_seg_angle))
# RING_LINE_SEGMENTS_VECTORS.push_back(Vector2(cos(angle), sin(angle)))
# for i in range(ring_segs/4):
# var alpha := 1.0 - (i/float(ring_segs/4))
# ring_line_segments_alphas.push_back(alpha)
# ring_line_segments_widths.push_back(lerp(alpha, 1.0, 0.5))
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const SQRT2 := sqrt(2)
const DEG45 := deg2rad(45.0)
const DEG90 := deg2rad(90.0)
const DEG135 := deg2rad(135.0)
var time := 0.0
var t := 0.0
var bpm := 120.0
var active_notes := []
var all_notes := []
var next_note_to_load := 0
var slide_trail_meshes := []
var slide_trail_mesh_instances := []
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# UV vertex arrays for our sprites
# tap/star/arrow are 4-vertex 2-triangle simple squares
# hold is 8-vertex 6-triangle to enable stretching in the middle
const UV_ARRAY_TAP := PoolVector2Array([Vector2(0, 0.5), Vector2(0.5, 0.5), Vector2(0, 1), Vector2(0.5, 1)])
const UV_ARRAY_HOLD := PoolVector2Array([
Vector2(0.5, 0.5), Vector2(1, 0.5), Vector2(0.5, 0.75), Vector2(1, 0.75),
Vector2(0.5, 0.75), Vector2(1, 0.75), Vector2(0.5, 1), Vector2(1, 1)
])
const UV_ARRAY_STAR := PoolVector2Array([Vector2(0.5, 0), Vector2(1, 0), Vector2(0.5, 0.5), Vector2(1, 0.5)])
const UV_ARRAY_ARROW := PoolVector2Array([Vector2(0, 0), Vector2(0.5, 0), Vector2(0, 0.5), Vector2(0.5, 0.5)])
# Slide trail arrow. Single tri.
const UV_ARRAY_SLIDE_ARROW := PoolVector2Array([Vector2(0, 0), Vector2(1, 0), Vector2(0, 1)])
const UV_ARRAY_SLIDE_ARROW2 := PoolVector2Array([Vector2(1, 1), Vector2(0, 1), Vector2(1, 0)])
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# Normal vertex arrays for our sprites. Might be unnecessary?
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const DEFAULT_NORMAL := Vector3(0, 0, 1)
var NORMAL_ARRAY_4 := PoolVector3Array([DEFAULT_NORMAL, DEFAULT_NORMAL, DEFAULT_NORMAL, DEFAULT_NORMAL])
var NORMAL_ARRAY_8 := PoolVector3Array([
DEFAULT_NORMAL, DEFAULT_NORMAL, DEFAULT_NORMAL, DEFAULT_NORMAL,
DEFAULT_NORMAL, DEFAULT_NORMAL, DEFAULT_NORMAL, DEFAULT_NORMAL
])
# Helper functions to generate meshes from vertex arrays
func make_tap_mesh(mesh: ArrayMesh, vertex_array, color_array = theme.COLOR_ARRAY_TAP):
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var arrays = []
arrays.resize(Mesh.ARRAY_MAX)
arrays[Mesh.ARRAY_VERTEX] = vertex_array
# arrays[Mesh.ARRAY_NORMAL] = NORMAL_ARRAY_4
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arrays[Mesh.ARRAY_TEX_UV] = UV_ARRAY_TAP
arrays[Mesh.ARRAY_COLOR] = color_array
mesh.add_surface_from_arrays(Mesh.PRIMITIVE_TRIANGLE_STRIP, arrays)
func make_hold_mesh(mesh: ArrayMesh, vertex_array, color_array = theme.COLOR_ARRAY_HOLD):
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var arrays = []
arrays.resize(Mesh.ARRAY_MAX)
arrays[Mesh.ARRAY_VERTEX] = vertex_array
# arrays[Mesh.ARRAY_NORMAL] = NORMAL_ARRAY_8
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arrays[Mesh.ARRAY_TEX_UV] = UV_ARRAY_HOLD
arrays[Mesh.ARRAY_COLOR] = color_array
mesh.add_surface_from_arrays(Mesh.PRIMITIVE_TRIANGLE_STRIP, arrays)
func make_star_mesh(mesh: ArrayMesh, vertex_array, color_array = theme.COLOR_ARRAY_STAR):
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var arrays = []
arrays.resize(Mesh.ARRAY_MAX)
arrays[Mesh.ARRAY_VERTEX] = vertex_array
# arrays[Mesh.ARRAY_NORMAL] = NORMAL_ARRAY_4
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arrays[Mesh.ARRAY_TEX_UV] = UV_ARRAY_STAR
arrays[Mesh.ARRAY_COLOR] = color_array
mesh.add_surface_from_arrays(Mesh.PRIMITIVE_TRIANGLE_STRIP, arrays)
func make_arrow_mesh(mesh: ArrayMesh, vertex_array, color_array = theme.COLOR_ARRAY_TAP):
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var arrays = []
arrays.resize(Mesh.ARRAY_MAX)
arrays[Mesh.ARRAY_VERTEX] = vertex_array
# arrays[Mesh.ARRAY_NORMAL] = NORMAL_ARRAY_4
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arrays[Mesh.ARRAY_TEX_UV] = UV_ARRAY_ARROW
arrays[Mesh.ARRAY_COLOR] = color_array
mesh.add_surface_from_arrays(Mesh.PRIMITIVE_TRIANGLE_STRIP, arrays)
const slide_arrows_per_unit_length := 10
func make_slide_trail_mesh(note: Dictionary) -> ArrayMesh:
# Generates a mesh centered around origin. Make sure the MeshInstance2D that draws this is centered on the screen.
var mesh = ArrayMesh.new()
var arrays = []
arrays.resize(Mesh.ARRAY_MAX)
var vertices := PoolVector2Array()
var uvs := PoolVector2Array()
var colors := PoolColorArray()
var size := theme.sprite_size2*SQRT2
# First we need to determine how many arrows to leave.
# Chord length is 2r*sin(theta/2)
# Arc length is r*theta (in rads)
# 18 for a 3chord in maimai
# 20 for a 4chord
# 6 per arc segment +1 for every receptor crossed over, ~7 per
var unit_length: float
var trail_length: int
match note.slide_type:
Note.SlideType.CHORD:
unit_length = 2*abs(sin(RADIAL_COL_ANGLES[note.column_release] - RADIAL_COL_ANGLES[note.column]))
Note.SlideType.ARC_CW:
unit_length = fposmod(RADIAL_COL_ANGLES[note.column_release] - RADIAL_COL_ANGLES[note.column], TAU)
Note.SlideType.ARC_ACW:
unit_length = fposmod(RADIAL_COL_ANGLES[note.column] - RADIAL_COL_ANGLES[note.column_release], TAU)
trail_length = int(floor(unit_length * slide_arrows_per_unit_length))
vertices.resize(3*trail_length)
# uvs.resize(3*trail_length)
colors.resize(3*trail_length)
for i in trail_length:
uvs.append_array(UV_ARRAY_SLIDE_ARROW if i%2 else UV_ARRAY_SLIDE_ARROW2)
for j in 3:
# uvs[i*3+j] = UV_ARRAY_SLIDE_ARROW[j] if i%2 else UV_ARRAY_SLIDE_ARROW2[j]
colors[i*3+j] = Color(1.0, 1.0, 1.0, 1.0+float(i))
match note.slide_type:
Note.SlideType.CHORD:
var angle : float = RADIAL_UNIT_VECTORS[note.column].angle_to_point(RADIAL_UNIT_VECTORS[note.column_release])
var start : Vector2 = RADIAL_UNIT_VECTORS[note.column] * theme.receptor_ring_radius
var end : Vector2 = RADIAL_UNIT_VECTORS[note.column_release] * theme.receptor_ring_radius
var uv1o : Vector2 = polar2cartesian(size, angle)
var uv2o : Vector2 = polar2cartesian(size, angle+PI/2.0)
var uv3o : Vector2 = polar2cartesian(size, angle-PI/2.0)
for i in trail_length:
var offset : Vector2 = lerp(start, end, (i+1)/float(trail_length))
vertices[i*3] = offset + uv1o
vertices[i*3+1] = offset + uv2o
vertices[i*3+2] = offset + uv3o
Note.SlideType.ARC_CW:
var start_a : float = RADIAL_COL_ANGLES[note.column]
var end_a : float = RADIAL_COL_ANGLES[note.column_release]
if end_a < start_a:
end_a += TAU
for i in trail_length:
var circle_angle : float = lerp(start_a, end_a, (i+1)/float(trail_length))
var angle : float = circle_angle + PI/2.0
var offset : Vector2 = polar2cartesian(theme.receptor_ring_radius, circle_angle)
vertices[i*3] = offset + polar2cartesian(size, angle)
vertices[i*3+1] = offset + polar2cartesian(size, angle+PI/2.0)
vertices[i*3+2] = offset + polar2cartesian(size, angle-PI/2.0)
Note.SlideType.ARC_ACW:
var start_a : float = RADIAL_COL_ANGLES[note.column]
var end_a : float = RADIAL_COL_ANGLES[note.column_release]
if end_a > start_a:
end_a -= TAU
for i in trail_length:
var circle_angle : float = lerp(start_a, end_a, (i+1)/float(trail_length))
var angle : float = circle_angle - PI/2.0
var offset : Vector2 = polar2cartesian(theme.receptor_ring_radius, circle_angle)
vertices[i*3] = offset + polar2cartesian(size, angle)
vertices[i*3+1] = offset + polar2cartesian(size, angle+PI/2.0)
vertices[i*3+2] = offset + polar2cartesian(size, angle-PI/2.0)
arrays[Mesh.ARRAY_VERTEX] = vertices
arrays[Mesh.ARRAY_TEX_UV] = uvs
arrays[Mesh.ARRAY_COLOR] = colors
mesh.add_surface_from_arrays(Mesh.PRIMITIVE_TRIANGLES, arrays)
return mesh
func make_tap_note(mesh: ArrayMesh, column: int, position: float, scale := 1.0, color_array := theme.COLOR_ARRAY_TAP) -> ArrayMesh:
if position < theme.INNER_NOTE_CIRCLE_RATIO:
scale *= position/theme.INNER_NOTE_CIRCLE_RATIO
position = theme.INNER_NOTE_CIRCLE_RATIO
var note_center = screen_center + (RADIAL_UNIT_VECTORS[column] * position * theme.receptor_ring_radius)
var dim = theme.sprite_size2 * scale
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var vertices = PoolVector2Array([note_center + Vector2(-dim, -dim), note_center + Vector2(dim, -dim), note_center + Vector2(-dim, dim), note_center + Vector2(dim, dim)])
make_tap_mesh(mesh, vertices, color_array)
return mesh
func make_hold_note(mesh: ArrayMesh, column: int, position1: float, position2: float, scale := 1.0, color_array = theme.COLOR_ARRAY_HOLD) -> ArrayMesh:
if position1 < theme.INNER_NOTE_CIRCLE_RATIO:
scale *= position1/theme.INNER_NOTE_CIRCLE_RATIO
position1 = theme.INNER_NOTE_CIRCLE_RATIO
if position2 < theme.INNER_NOTE_CIRCLE_RATIO:
position2 = theme.INNER_NOTE_CIRCLE_RATIO
var note_center1 = screen_center + (RADIAL_UNIT_VECTORS[column] * position1 * theme.receptor_ring_radius)
var note_center2 = screen_center + (RADIAL_UNIT_VECTORS[column] * position2 * theme.receptor_ring_radius)
var dim = theme.sprite_size2 * scale
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var dim2 = dim * SQRT2
var angle = RADIAL_COL_ANGLES[column]
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var a1 = angle - DEG45
var a2 = angle + DEG45
var a3 = angle - DEG90
var a4 = angle + DEG90
var a5 = angle - DEG135
var a6 = angle + DEG135
var vertices = PoolVector2Array([
note_center1 + dim2*Vector2(cos(a1), sin(a1)), note_center1 + dim2*Vector2(cos(a2), sin(a2)),
note_center1 + dim*Vector2(cos(a3), sin(a3)), note_center1 + dim*Vector2(cos(a4), sin(a4)),
note_center2 + dim*Vector2(cos(a3), sin(a3)), note_center2 + dim*Vector2(cos(a4), sin(a4)),
note_center2 + dim2*Vector2(cos(a5), sin(a5)), note_center2 + dim2*Vector2(cos(a6), sin(a6))
])
make_hold_mesh(mesh, vertices, color_array)
return mesh
func make_slide_note(mesh: ArrayMesh, column: int, position: float, scale := 1.0, color_array := theme.COLOR_ARRAY_STAR) -> ArrayMesh:
if position < theme.INNER_NOTE_CIRCLE_RATIO:
scale *= position/theme.INNER_NOTE_CIRCLE_RATIO
position = theme.INNER_NOTE_CIRCLE_RATIO
var note_center = screen_center + (RADIAL_UNIT_VECTORS[column] * position * theme.receptor_ring_radius)
var dim = theme.sprite_size2 * scale * SQRT2
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var angle = deg2rad(fmod(t*270.0, 360.0))
var a1 = angle - DEG45
var a2 = angle + DEG45
var a3 = angle - DEG135
var a4 = angle + DEG135
var vertices = PoolVector2Array([
note_center + dim*Vector2(cos(a1), sin(a1)), note_center + dim*Vector2(cos(a2), sin(a2)),
note_center + dim*Vector2(cos(a3), sin(a3)), note_center + dim*Vector2(cos(a4), sin(a4))
])
make_star_mesh(mesh, vertices, color_array)
return mesh
#----------------------------------------------------------------------------------------------------------------------------------------------
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func _init():
Input.set_mouse_mode(Input.MOUSE_MODE_HIDDEN)
init_radial_values()
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func _draw():
var mesh := ArrayMesh.new()
# var dots := PoolVector2Array()
# var dots_dict := {}
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var noteline_data : Image = noteline_array_image.get_rect(Rect2(0, 0, 16, 16))
noteline_data.lock()
var i := 0
var j := 0
for note in active_notes:
var position : float = (t+theme.note_forecast_beats-note.time_hit)/theme.note_forecast_beats
var note_center := screen_center + (RADIAL_UNIT_VECTORS[note.column] * position * theme.receptor_ring_radius)
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# dots.push_back(note_center)
# if not dots_dict.has(position):
# dots_dict[position] = []
# dots_dict[position].push_back(note.column)
noteline_data.set_pixel(i%16, i/16, Color(position, note.column, RADIAL_COL_ANGLES[note.column]))
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i += 1
match note.type:
Note.NOTE_TAP:
var color = theme.COLOR_ARRAY_DOUBLE_4 if note.double_hit else theme.COLOR_ARRAY_TAP
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make_tap_note(mesh, note.column, position, 1, color)
Note.NOTE_HOLD:
var color = theme.COLOR_ARRAY_DOUBLE_8 if note.double_hit else theme.COLOR_ARRAY_HOLD
var position_rel : float = (t+theme.note_forecast_beats-note.time_release)/theme.note_forecast_beats
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if position_rel > 0:
var note_rel_center := screen_center + (RADIAL_UNIT_VECTORS[note.column] * position_rel * theme.receptor_ring_radius)
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# dots.push_back(note_rel_center)
noteline_data.set_pixel(j%16, 15, Color(position_rel, note.column, RADIAL_COL_ANGLES[note.column]))
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j += 1
make_hold_note(mesh, note.column, position, position_rel, 1.0, theme.COLOR_ARRAY_HOLD_HELD)
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Note.NOTE_SLIDE:
var color = theme.COLOR_ARRAY_DOUBLE_4 if note.double_hit else theme.COLOR_ARRAY_STAR
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make_slide_note(mesh, note.column, position, 1.0, color)
noteline_data.unlock()
var noteline_data_tex = ImageTexture.new()
noteline_data_tex.create_from_image(noteline_data, 0)
$notelines.set_texture(noteline_data_tex)
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# var dot_scale := 1.0 - abs(0.25-fmod(t+0.25, 0.5))
# var dot_inner := 6.0 * dot_scale
# var dot_outer := 9.0 * dot_scale
# for dot in dots:
# draw_circle(dot, dot_inner, Color(1.0, 1.0, 1.0, 0.60))
# draw_circle(dot, dot_outer, Color(1.0, 1.0, 1.0, 0.20))
# var line_inner := 3.0 * dot_scale
# var line_outer := 6.0 * dot_scale
# for position in dots_dict:
# for col in dots_dict[position]:
# var c0 = col * RING_LINE_SEGMENTS_PER_COLUMN
# for i in range(ring_segs/4):
# var alpha :float = ring_line_segments_alphas[i]*dot_scale
# var width_scale : float = ring_line_segments_widths[i]
# draw_line(screen_center + RING_LINE_SEGMENTS_VECTORS[(c0+i)%ring_segs]*position*theme.receptor_ring_radius,
# screen_center + RING_LINE_SEGMENTS_VECTORS[(c0+i+1)%ring_segs]*position*theme.receptor_ring_radius,
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# Color(1.0, 1.0, 0.65, alpha*0.8), line_inner*width_scale)
# draw_line(screen_center + RING_LINE_SEGMENTS_VECTORS[(c0+i)%ring_segs]*position*theme.receptor_ring_radius,
# screen_center + RING_LINE_SEGMENTS_VECTORS[(c0+i+1)%ring_segs]*position*theme.receptor_ring_radius,
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# Color(1.0, 1.0, 0.65, alpha*0.2), line_outer*width_scale)
# draw_line(screen_center + RING_LINE_SEGMENTS_VECTORS[(c0-i)%ring_segs]*position*theme.receptor_ring_radius,
# screen_center + RING_LINE_SEGMENTS_VECTORS[(c0-i-1)%ring_segs]*position*theme.receptor_ring_radius,
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# Color(1.0, 1.0, 0.65, alpha*0.8), line_inner*width_scale)
# draw_line(screen_center + RING_LINE_SEGMENTS_VECTORS[(c0-i)%ring_segs]*position*theme.receptor_ring_radius,
# screen_center + RING_LINE_SEGMENTS_VECTORS[(c0-i-1)%ring_segs]*position*theme.receptor_ring_radius,
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# Color(1.0, 1.0, 0.65, alpha*0.2), line_outer*width_scale)
# var alpha_array = PoolRealArray()
# alpha_array.resize(ring_segs)
# for i in range(ring_segs):
# alpha_array[i] = 0.0
# for col in dots_dict[position]:
# var origin : int = col*RING_LINE_SEGMENTS_PER_COLUMN
# var affected_segs := ring_segs/4
# alpha_array[origin] = 1.0
# for i in range(affected_segs):
# alpha_array[(origin+i)%ring_segs] += 1.0 - i/float(affected_segs)
# alpha_array[(origin-i)%ring_segs] += 1.0 - i/float(affected_segs)
# for i in range(ring_segs):
# var alpha := min(alpha_array[i], 1.0)*dot_scale
# var width_scale : float = lerp(min(alpha_array[i], 1.0), 1.0, 0.5)
# draw_line(screen_center + RING_LINE_SEGMENTS_VECTORS[i]*position*theme.receptor_ring_radius,
# screen_center + RING_LINE_SEGMENTS_VECTORS[(i+1)%ring_segs]*position*theme.receptor_ring_radius,
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# Color(1.0, 1.0, 0.65, alpha*0.8), line_inner*width_scale)
# draw_line(screen_center + RING_LINE_SEGMENTS_VECTORS[i]*position*theme.receptor_ring_radius,
# screen_center + RING_LINE_SEGMENTS_VECTORS[(i+1)%ring_segs]*position*theme.receptor_ring_radius,
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# Color(1.0, 1.0, 0.65, alpha*0.2), line_outer*width_scale)
$meshinstance.set_mesh(mesh)
# draw_mesh(mesh, tex)
var noteline_array_image := Image.new()
# Called when the node enters the scene tree for the first time.
func _ready():
t = 0.0
time = -2.0
bpm = 120.0
active_notes = []
all_notes = []
next_note_to_load = 0
$meshinstance.material.set_shader_param("star_color", theme.COLOR_STAR)
$meshinstance.material.set_shader_param("held_color", theme.COLOR_HOLD_HELD)
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$meshinstance.material.set_shader_param("bps", bpm/60.0)
$meshinstance.material.set_shader_param("screen_size", get_viewport().get_size())
$meshinstance.set_texture(tex)
var rec_scale1 = (float(screen_height)/float(theme.receptor_ring_radius))*0.5
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var uv_array_playfield := PoolVector2Array([Vector2(-1.0, -1.0)*rec_scale1, Vector2(-1.0, 1.0)*rec_scale1, Vector2(1.0, -1.0)*rec_scale1, Vector2(1.0, 1.0)*rec_scale1])
var vertex_array_playfield := PoolVector2Array([
Vector2(x_margin, screen_height), Vector2(x_margin, 0.0),
Vector2(x_margin+screen_height, screen_height), Vector2(x_margin+screen_height, 0.0)])
var mesh_playfield := ArrayMesh.new()
var arrays = []
arrays.resize(Mesh.ARRAY_MAX)
arrays[Mesh.ARRAY_VERTEX] = vertex_array_playfield
arrays[Mesh.ARRAY_NORMAL] = NORMAL_ARRAY_4
arrays[Mesh.ARRAY_TEX_UV] = uv_array_playfield
mesh_playfield.add_surface_from_arrays(Mesh.PRIMITIVE_TRIANGLE_STRIP, arrays)
$notelines.set_mesh(mesh_playfield)
$notelines.material.set_shader_param("bps", bpm/60.0)
noteline_array_image.create(16, 16, false, Image.FORMAT_RGBF)
noteline_array_image.fill(Color(0.0, 0.0, 0.0))
# Format: first 15 rows are for hit events, last row is for releases only (no ring glow)
all_notes = FileLoader.SRT.load_file("res://songs/199_cirno_master.srt")
# all_notes = FileLoader.Test.stress_pattern()
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bpm = 175.0
Note.process_doubles(all_notes)
for note in all_notes:
if note.type == Note.NOTE_SLIDE:
slide_trail_meshes.push_back(make_slide_trail_mesh(note))
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func game_time(realtime: float) -> float:
return time * bpm / 60.0
# Called every frame. 'delta' is the elapsed time since the previous frame.
func _process(delta):
$meshinstance.material.set_shader_param("bps", bpm/60.0)
$notelines.material.set_shader_param("bps", bpm/60.0)
var t_old := game_time(time)
time += delta
t = game_time(time)
if (t_old < 0) and (t >= 0):
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get_node("/root/main/video").play()
# Clean out expired notes
for i in range(len(active_notes)-1, -1, -1):
if active_notes[i].time_death < t:
active_notes.remove(i)
# Add new notes as necessary
while true:
if next_note_to_load >= len(all_notes):
# All notes have been loaded, maybe do something
break
if all_notes[next_note_to_load].time_hit > (t + theme.note_forecast_beats):
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# Next chronological note isn't ready to load yet
break
# Next chronological note is ready to load, load it
active_notes.push_back(all_notes[next_note_to_load])
if active_notes[-1].type == Note.NOTE_SLIDE:
slide_trail_mesh_instances.push_back(MeshInstance2D.new())
slide_trail_mesh_instances[-1].set_mesh(slide_trail_meshes.pop_front())
slide_trail_mesh_instances[-1].set_position(screen_center)
add_child(slide_trail_mesh_instances[-1])
slide_trail_mesh_instances[-1].set_material(slide_trail_shadermaterial)
slide_trail_mesh_instances[-1].material.set_shader_param("trail_progress", 0.0)
slide_trail_mesh_instances[-1].set_texture(tex_slide_arrow)
2019-11-10 15:09:14 +10:30
next_note_to_load += 1
# DEBUG: Reset after all notes are done
if (len(active_notes) < 1) and (next_note_to_load >= len(all_notes)) and (time > 10.0):
time = fmod(time, 1.0) - 2.0
next_note_to_load = 0
# get_node("/root/main/video").set_stream_position(0.0)
# get_node("/root/main/video").play()
# Redraw
$meshinstance.material.set_shader_param("screen_size", get_viewport().get_size())
update()