427 lines
12 KiB
Nim
427 lines
12 KiB
Nim
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when defined(pixieSweeps):
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import algorithm
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proc pixelCover(a0, b0: Vec2): float32 =
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## Returns the amount of area a given segment sweeps to the right
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## in a [0,0 to 1,1] box.
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var
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a = a0
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b = b0
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aI: Vec2
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bI: Vec2
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area: float32 = 0.0
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if (a.x < 0 and b.x < 0) or # Both to the left.
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(a.x == b.x): # Vertical line
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# Area of the rectangle:
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return (1 - clamp(a.x, 0, 1)) * (min(b.y, 1) - max(a.y, 0))
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else:
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# y = mm*x + bb
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let
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mm: float32 = (b.y - a.y) / (b.x - a.x)
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bb: float32 = a.y - mm * a.x
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if a.x >= 0 and a.x <= 1 and a.y >= 0 and a.y <= 1:
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# A is in pixel bounds.
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aI = a
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else:
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aI = vec2((0 - bb) / mm, 0)
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if aI.x < 0:
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let y = mm * 0 + bb
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# Area of the extra rectangle.
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area += (min(bb, 1) - max(a.y, 0)).clamp(0, 1)
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aI = vec2(0, y.clamp(0, 1))
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elif aI.x > 1:
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let y = mm * 1 + bb
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aI = vec2(1, y.clamp(0, 1))
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if b.x >= 0 and b.x <= 1 and b.y >= 0 and b.y <= 1:
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# B is in pixel bounds.
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bI = b
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else:
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bI = vec2((1 - bb) / mm, 1)
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if bI.x < 0:
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let y = mm * 0 + bb
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# Area of the extra rectangle.
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area += (min(b.y, 1) - max(bb, 0)).clamp(0, 1)
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bI = vec2(0, y.clamp(0, 1))
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elif bI.x > 1:
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let y = mm * 1 + bb
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bI = vec2(1, y.clamp(0, 1))
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area += ((1 - aI.x) + (1 - bI.x)) / 2 * (bI.y - aI.y)
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return area
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proc intersectsInner*(a, b: Segment, at: var Vec2): bool {.inline.} =
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## Checks if the a segment intersects b segment.
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## If it returns true, at will have point of intersection
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let
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s1 = a.to - a.at
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s2 = b.to - b.at
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denominator = (-s2.x * s1.y + s1.x * s2.y)
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s = (-s1.y * (a.at.x - b.at.x) + s1.x * (a.at.y - b.at.y)) / denominator
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t = (s2.x * (a.at.y - b.at.y) - s2.y * (a.at.x - b.at.x)) / denominator
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if s > 0 and s < 1 and t > 0 and t < 1:
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at = a.at + (t * s1)
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return true
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type
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Trapezoid = object
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nw, ne, se, sw: Vec2
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SweepLine = object
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#m, x, b: float32
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atx, tox: float32
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winding: int16
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proc toLine(s: (Segment, int16)): SweepLine =
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var line = SweepLine()
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line.atx = s[0].at.x
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line.tox = s[0].to.x
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# y = mx + b
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# line.m = (s.at.y - s.to.y) / (s.at.x - s.to.x)
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# line.b = s.at.y - line.m * s.at.x
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line.winding = s[1]
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return line
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proc intersectsYLine(
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y: float32, s: Segment, atx: var float32
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): bool {.inline.} =
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let
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s2y = s.to.y - s.at.y
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denominator = -s2y
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numerator = s.at.y - y
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u = numerator / denominator
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if u >= 0 and u <= 1:
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let at = s.at + (u * vec2(s.to.x - s.at.x, s2y))
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atx = at.x
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return true
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proc binaryInsert(arr: var seq[float32], v: float32) =
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if arr.len == 0:
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arr.add(v)
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return
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var
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L = 0
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R = arr.len - 1
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while L < R:
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let m = (L + R) div 2
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if arr[m] ~= v:
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return
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elif arr[m] < v:
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L = m + 1
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else: # arr[m] > v:
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R = m - 1
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if arr[L] ~= v:
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return
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elif arr[L] > v:
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arr.insert(v, L)
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else:
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arr.insert(v, L + 1)
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proc sortSegments(segments: var seq[(Segment, int16)], inl, inr: int) =
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## Quicksort + insertion sort, in-place and faster than standard lib sort.
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let n = inr - inl + 1
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if n < 32: # Use insertion sort for the rest
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for i in inl + 1 .. inr:
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var
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j = i - 1
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k = i
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while j >= 0 and segments[j][0].at.y > segments[k][0].at.y:
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swap(segments[j + 1], segments[j])
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dec j
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dec k
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return
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var
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l = inl
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r = inr
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let p = segments[l + n div 2][0].at.y
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while l <= r:
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if segments[l][0].at.y < p:
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inc l
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elif segments[r][0].at.y > p:
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dec r
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else:
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swap(segments[l], segments[r])
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inc l
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dec r
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sortSegments(segments, inl, r)
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sortSegments(segments, l, inr)
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proc sortSweepLines(segments: var seq[SweepLine], inl, inr: int) =
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## Quicksort + insertion sort, in-place and faster than standard lib sort.
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proc avg(line: SweepLine): float32 {.inline.} =
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(line.tox + line.atx) / 2.float32
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let n = inr - inl + 1
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if n < 32: # Use insertion sort for the rest
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for i in inl + 1 .. inr:
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var
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j = i - 1
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k = i
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while j >= 0 and segments[j].avg > segments[k].avg:
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swap(segments[j + 1], segments[j])
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dec j
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dec k
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return
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var
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l = inl
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r = inr
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let p = segments[l + n div 2].avg
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while l <= r:
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if segments[l].avg < p:
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inc l
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elif segments[r].avg > p:
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dec r
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else:
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swap(segments[l], segments[r])
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inc l
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dec r
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sortSweepLines(segments, inl, r)
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sortSweepLines(segments, l, inr)
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proc fillShapes(
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image: Image,
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shapes: seq[seq[Vec2]],
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color: SomeColor,
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windingRule: WindingRule,
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blendMode: BlendMode
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) =
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let rgbx = color.rgbx
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var segments = shapes.shapesToSegments()
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let
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bounds = computeBounds(segments).snapToPixels()
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startX = max(0, bounds.x.int)
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if segments.len == 0 or bounds.w.int == 0 or bounds.h.int == 0:
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return
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# const q = 1/10
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# for i in 0 ..< segments.len:
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# segments[i][0].at.x = quantize(segments[i][0].at.x, q)
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# segments[i][0].at.y = quantize(segments[i][0].at.y, q)
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# segments[i][0].to.x = quantize(segments[i][0].to.x, q)
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# segments[i][0].to.y = quantize(segments[i][0].to.y, q)
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# Create sorted segments.
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segments.sortSegments(0, segments.high)
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# Compute cut lines
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var cutLines: seq[float32]
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for s in segments:
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cutLines.binaryInsert(s[0].at.y)
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cutLines.binaryInsert(s[0].to.y)
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var
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# Dont add bottom cutLine.
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sweeps = newSeq[seq[SweepLine]](cutLines.len - 1)
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lastSeg = 0
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i = 0
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while i < sweeps.len:
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if lastSeg < segments.len:
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while segments[lastSeg][0].at.y == cutLines[i]:
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let s = segments[lastSeg]
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if s[0].to.y != cutLines[i + 1]:
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var atx: float32
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var seg = s[0]
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for j in i ..< sweeps.len:
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let y = cutLines[j + 1]
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if intersectsYLine(y, seg, atx):
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sweeps[j].add(toLine((segment(seg.at, vec2(atx, y)), s[1])))
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seg = segment(vec2(atx, y), seg.to)
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else:
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if seg.at.y != seg.to.y:
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sweeps[j].add(toLine(s))
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break
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else:
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sweeps[i].add(toLine(s))
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inc lastSeg
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if lastSeg >= segments.len:
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break
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inc i
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# i = 0
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# while i < sweeps.len:
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# # TODO: Maybe finds all cuts first, add them to array, cut all lines at once.
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# var crossCuts: seq[float32]
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# # echo i, " cut?"
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# for aIndex in 0 ..< sweeps[i].len:
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# let a = sweeps[i][aIndex]
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# # echo i, ":", sweeps.len, ":", cutLines.len
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# let aSeg = segment(vec2(a.atx, cutLines[i]), vec2(a.tox, cutLines[i+1]))
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# for bIndex in aIndex + 1 ..< sweeps[i].len:
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# let b = sweeps[i][bIndex]
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# let bSeg = segment(vec2(b.atx, cutLines[i]), vec2(b.tox, cutLines[i+1]))
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# var at: Vec2
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# if intersectsInner(aSeg, bSeg, at):
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# crossCuts.binaryInsert(at.y)
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# if crossCuts.len > 0:
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# var
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# thisSweep = sweeps[i]
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# yTop = cutLines[i]
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# yBottom = cutLines[i + 1]
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# sweeps[i].setLen(0)
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# for k in crossCuts:
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# let prevLen = cutLines.len
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# cutLines.binaryInsert(k)
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# if prevLen != cutLines.len:
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# sweeps.insert(newSeq[SweepLine](), i + 1)
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# for a in thisSweep:
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# var seg = segment(vec2(a.atx, yTop), vec2(a.tox, yBottom))
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# var at: Vec2
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# for j, cutterLine in crossCuts:
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# if intersects(line(vec2(0, cutterLine), vec2(1, cutterLine)), seg, at):
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# sweeps[i+j].add(toLine((segment(seg.at, at), a.winding)))
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# seg = segment(at, seg.to)
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# sweeps[i+crossCuts.len].add(toLine((seg, a.winding)))
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# i += crossCuts.len
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# inc i
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i = 0
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while i < sweeps.len:
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# Sort the sweep by X
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sweeps[i].sortSweepLines(0, sweeps[i].high)
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# Do winding order
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var
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pen = 0
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prevFill = false
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j = 0
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while j < sweeps[i].len:
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let a = sweeps[i][j]
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if a.winding == 1:
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inc pen
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if a.winding == -1:
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dec pen
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let thisFill = shouldFill(windingRule, pen)
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if prevFill == thisFill:
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# Remove this sweep line.
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sweeps[i].delete(j)
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continue
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prevFill = thisFill
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inc j
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inc i
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# Used to debug sweeps:
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# for s in 0 ..< sweeps.len:
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# let
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# y1 = cutLines[s]
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# echo "M -100 ", y1
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# echo "L 300 ", y1
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# for line in sweeps[s]:
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# let
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# nw = vec2(line.atx, cutLines[s])
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# sw = vec2(line.tox, cutLines[s + 1])
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# echo "M ", nw.x, " ", nw.y
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# echo "L ", sw.x, " ", sw.y
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proc computeCoverage(
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coverages: var seq[uint16],
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y: int,
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startX: int,
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cutLines: seq[float32],
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currCutLine: int,
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sweep: seq[SweepLine]
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) =
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if cutLines[currCutLine + 1] - cutLines[currCutLine] < 1/256:
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# TODO some thing about micro sweeps
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return
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let
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sweepHeight = cutLines[currCutLine + 1] - cutLines[currCutLine]
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yFracTop = ((y.float32 - cutLines[currCutLine]) / sweepHeight).clamp(0, 1)
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yFracBottom = ((y.float32 + 1 - cutLines[currCutLine]) /
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sweepHeight).clamp(0, 1)
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var i = 0
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while i < sweep.len:
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let
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nwX = mix(sweep[i+0].atx, sweep[i+0].tox, yFracTop)
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neX = mix(sweep[i+1].atx, sweep[i+1].tox, yFracTop)
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swX = mix(sweep[i+0].atx, sweep[i+0].tox, yFracBottom)
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seX = mix(sweep[i+1].atx, sweep[i+1].tox, yFracBottom)
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minWi = min(nwX, swX).int #.clamp(startX, coverages.len + startX)
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maxWi = max(nwX, swX).ceil.int #.clamp(startX, coverages.len + startX)
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minEi = min(neX, seX).int #.clamp(startX, coverages.len + startX)
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maxEi = max(neX, seX).ceil.int #.clamp(startX, coverages.len + startX)
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let
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nw = vec2(sweep[i+0].atx, cutLines[currCutLine])
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sw = vec2(sweep[i+0].tox, cutLines[currCutLine + 1])
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f16 = (256 * 256 - 1).float32
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for x in minWi ..< maxWi:
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var area = pixelCover(
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nw - vec2(x.float32, y.float32),
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sw - vec2(x.float32, y.float32)
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)
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coverages[x - startX] += (area * f16).uint16
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let x = maxWi
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var midArea = pixelCover(
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nw - vec2(x.float32, y.float32),
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sw - vec2(x.float32, y.float32)
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)
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for x in maxWi ..< maxEi:
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coverages[x - startX] += (midArea * f16).uint16
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let
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ne = vec2(sweep[i+1].atx, cutLines[currCutLine])
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se = vec2(sweep[i+1].tox, cutLines[currCutLine + 1])
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for x in minEi ..< maxEi:
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var area = pixelCover(
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ne - vec2(x.float32, y.float32),
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se - vec2(x.float32, y.float32)
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)
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coverages[x - startX] -= (area * f16).uint16
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i += 2
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var
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currCutLine = 0
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coverages16 = newSeq[uint16](bounds.w.int)
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coverages8 = newSeq[uint8](bounds.w.int)
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for scanLine in max(cutLines[0].int, 0) ..< min(cutLines[^1].ceil.int, image.height):
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zeroMem(coverages16[0].addr, coverages16.len * 2)
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coverages16.computeCoverage(
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scanLine, startX, cutLines, currCutLine, sweeps[currCutLine])
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while cutLines[currCutLine + 1] < scanLine.float + 1.0:
|
||
|
inc currCutLine
|
||
|
if currCutLine == sweeps.len:
|
||
|
break
|
||
|
coverages16.computeCoverage(
|
||
|
scanLine, startX, cutLines, currCutLine, sweeps[currCutLine])
|
||
|
|
||
|
for i in 0 ..< coverages16.len:
|
||
|
coverages8[i] = (coverages16[i] shr 8).uint8
|
||
|
image.fillCoverage(
|
||
|
rgbx,
|
||
|
startX = startX,
|
||
|
y = scanLine,
|
||
|
coverages8,
|
||
|
blendMode
|
||
|
)
|
||
|
|
||
|
else:
|