tgxworld/bm_app_aobench.rb

## bm_app_aobench.rb
mem_start = `ps -o rss= -p #{$$}`.to_i
# AO render benchmark
# Original program (C) Syoyo Fujita in Javascript (and other languages)
#      https://code.google.com/p/aobench/
# Ruby(yarv2llvm) version by Hideki Miura
#

IMAGE_WIDTH = 256
IMAGE_HEIGHT = 256
NSUBSAMPLES = 2
NAO_SAMPLES = 8

class Vec
  def initialize(x, y, z)
    @x = x
    @y = y
    @z = z
  end

  attr_accessor :x, :y, :z

  def vadd(b)
    Vec.new(@x + b.x, @y + b.y, @z + b.z)
  end

  def vsub(b)
    Vec.new(@x - b.x, @y - b.y, @z - b.z)
  end

  def vcross(b)
    Vec.new(@y * b.z - @z * b.y,
            @z * b.x - @x * b.z,
            @x * b.y - @y * b.x)
  end

  def vdot(b)
    @x * b.x + @y * b.y + @z * b.z
  end

  def vlength
    Math.sqrt(@x * @x + @y * @y + @z * @z)
  end

  def vnormalize
    len = vlength
    v = Vec.new(@x, @y, @z)
    if len > 1.0e-17 then
      v.x = v.x / len
      v.y = v.y / len
      v.z = v.z / len
    end
    v
  end
end


class Sphere
  def initialize(center, radius)
    @center = center
    @radius = radius
  end

  attr_reader :center, :radius

  def intersect(ray, isect)
    rs = ray.org.vsub(@center)
    b = rs.vdot(ray.dir)
    c = rs.vdot(rs) - (@radius * @radius)
    d = b * b - c
    if d > 0.0 then
      t = - b - Math.sqrt(d)

      if t > 0.0 and t < isect.t then
        isect.t = t
        isect.hit = true
        isect.pl = Vec.new(ray.org.x + ray.dir.x * t,
                          ray.org.y + ray.dir.y * t,
                          ray.org.z + ray.dir.z * t)
        n = isect.pl.vsub(@center)
        isect.n = n.vnormalize
      else
        0.0
      end
    end
    nil
  end
end

class Plane
  def initialize(p, n)
    @p = p
    @n = n
  end

  def intersect(ray, isect)
    d = -@p.vdot(@n)
    v = ray.dir.vdot(@n)
    v0 = v
    if v < 0.0 then
      v0 = -v
    end
    if v0 < 1.0e-17 then
      return
    end

    t = -(ray.org.vdot(@n) + d) / v

    if t > 0.0 and t < isect.t then
      isect.hit = true
      isect.t = t
      isect.n = @n
      isect.pl = Vec.new(ray.org.x + t * ray.dir.x,
                        ray.org.y + t * ray.dir.y,
                        ray.org.z + t * ray.dir.z)
    end
    nil
  end
end

class Ray
  def initialize(org, dir)
    @org = org
    @dir = dir
  end

  attr_accessor :org, :dir
end

class Isect
  def initialize
    @t = 10000000.0
    @hit = false
    @pl = Vec.new(0.0, 0.0, 0.0)
    @n = Vec.new(0.0, 0.0, 0.0)
  end

  attr_accessor :t, :hit, :pl, :n
end

def clamp(f)
  i = f * 255.5
  if i > 255.0 then
    i = 255.0
  end
  if i < 0.0 then
    i = 0.0
  end
  i.to_i
end

def otherBasis(basis, n)
  basis[2] = Vec.new(n.x, n.y, n.z)
  basis[1] = Vec.new(0.0, 0.0, 0.0)

  if n.x < 0.6 and n.x > -0.6 then
    basis[1].x = 1.0
  elsif n.y < 0.6 and n.y > -0.6 then
    basis[1].y = 1.0
  elsif n.z < 0.6 and n.z > -0.6 then
    basis[1].z = 1.0
  else
    basis[1].x = 1.0
  end

  basis[0] = basis[1].vcross(basis[2])
  basis[0] = basis[0].vnormalize

  basis[1] = basis[2].vcross(basis[0])
  basis[1] = basis[1].vnormalize
end

class Scene
  def initialize
    @spheres = Array.new
    @spheres[0] = Sphere.new(Vec.new(-2.0, 0.0, -3.5), 0.5)
    @spheres[1] = Sphere.new(Vec.new(-0.5, 0.0, -3.0), 0.5)
    @spheres[2] = Sphere.new(Vec.new(1.0, 0.0, -2.2), 0.5)
    @plane = Plane.new(Vec.new(0.0, -0.5, 0.0), Vec.new(0.0, 1.0, 0.0))
  end

  def ambient_occlusion(isect)
    basis = Array.new
    otherBasis(basis, isect.n)

    ntheta    = NAO_SAMPLES
    nphi      = NAO_SAMPLES
    eps       = 0.0001
    occlusion = 0.0

    p0 = Vec.new(isect.pl.x + eps * isect.n.x,
                isect.pl.y + eps * isect.n.y,
                isect.pl.z + eps * isect.n.z)
    nphi.times do |j|
      ntheta.times do |i|
        r = rand
        phi = 2.0 * 3.14159265 * rand
        x = Math.cos(phi) * Math.sqrt(1.0 - r)
        y = Math.sin(phi) * Math.sqrt(1.0 - r)
        z = Math.sqrt(r)

        rx = x * basis[0].x + y * basis[1].x + z * basis[2].x
        ry = x * basis[0].y + y * basis[1].y + z * basis[2].y
        rz = x * basis[0].z + y * basis[1].z + z * basis[2].z

        raydir = Vec.new(rx, ry, rz)
        ray = Ray.new(p0, raydir)

        occisect = Isect.new
        @spheres[0].intersect(ray, occisect)
        @spheres[1].intersect(ray, occisect)
        @spheres[2].intersect(ray, occisect)
        @plane.intersect(ray, occisect)
        if occisect.hit then
          occlusion = occlusion + 1.0
        else
          0.0
        end
      end
    end

    occlusion = (ntheta.to_f * nphi.to_f - occlusion) / (ntheta.to_f * nphi.to_f)

    Vec.new(occlusion, occlusion, occlusion)
  end

  def render(w, h, nsubsamples)
    cnt = 0
    nsf = nsubsamples.to_f
    h.times do |y|
      w.times do |x|
        rad = Vec.new(0.0, 0.0, 0.0)

        # Subsmpling
        nsubsamples.times do |v|
          nsubsamples.times do |u|

            cnt = cnt + 1
            wf = w.to_f
            hf = h.to_f
            xf = x.to_f
            yf = y.to_f
            uf = u.to_f
            vf = v.to_f

            px = (xf + (uf / nsf) - (wf / 2.0)) / (wf / 2.0)
            py = -(yf + (vf / nsf) - (hf / 2.0)) / (hf / 2.0)

            eye = Vec.new(px, py, -1.0).vnormalize

            ray = Ray.new(Vec.new(0.0, 0.0, 0.0), eye)

            isect = Isect.new
            @spheres[0].intersect(ray, isect)
            @spheres[1].intersect(ray, isect)
            @spheres[2].intersect(ray, isect)
            @plane.intersect(ray, isect)
            if isect.hit then
              col = ambient_occlusion(isect)
              rad.x = rad.x + col.x
              rad.y = rad.y + col.y
              rad.z = rad.z + col.z
            end
          end
        end

        r = rad.x / (nsf * nsf)
        g = rad.y / (nsf * nsf)
        b = rad.z / (nsf * nsf)
        printf("%c", clamp(r))
        printf("%c", clamp(g))
        printf("%c", clamp(b))
      end
      nil
    end

    nil
  end
end

alias printf_orig printf
def printf *args
end

# File.open("ao.ppm", "w") do |fp|
  printf("P6\n")
  printf("%d %d\n", IMAGE_WIDTH, IMAGE_HEIGHT)
  printf("255\n", IMAGE_WIDTH, IMAGE_HEIGHT)
  Scene.new.render(IMAGE_WIDTH, IMAGE_HEIGHT, NSUBSAMPLES)
# end

undef printf
alias printf printf_orig
mem_end = `ps -o rss= -p #{$$}`.to_i
puts mem_end - mem_start
	mem_start = `ps -o rss= -p #{$$}`.to_i
	# AO render benchmark
	# Original program (C) Syoyo Fujita in Javascript (and other languages)
	# https://code.google.com/p/aobench/
	# Ruby(yarv2llvm) version by Hideki Miura
	#

	IMAGE_WIDTH = 256
	IMAGE_HEIGHT = 256
	NSUBSAMPLES = 2
	NAO_SAMPLES = 8

	class Vec
	def initialize(x, y, z)
	@x = x
	@y = y
	@z = z
	end

	attr_accessor :x, :y, :z

	def vadd(b)
	Vec.new(@x + b.x, @y + b.y, @z + b.z)
	end

	def vsub(b)
	Vec.new(@x - b.x, @y - b.y, @z - b.z)
	end

	def vcross(b)
	Vec.new(@y * b.z - @z * b.y,
	@z * b.x - @x * b.z,
	@x * b.y - @y * b.x)
	end

	def vdot(b)
	@x * b.x + @y * b.y + @z * b.z
	end

	def vlength
	Math.sqrt(@x * @x + @y * @y + @z * @z)
	end

	def vnormalize
	len = vlength
	v = Vec.new(@x, @y, @z)
	if len > 1.0e-17 then
	v.x = v.x / len
	v.y = v.y / len
	v.z = v.z / len
	end
	v
	end
	end


	class Sphere
	def initialize(center, radius)
	@center = center
	@radius = radius
	end

	attr_reader :center, :radius

	def intersect(ray, isect)
	rs = ray.org.vsub(@center)
	b = rs.vdot(ray.dir)
	c = rs.vdot(rs) - (@radius * @radius)
	d = b * b - c
	if d > 0.0 then
	t = - b - Math.sqrt(d)

	if t > 0.0 and t < isect.t then
	isect.t = t
	isect.hit = true
	isect.pl = Vec.new(ray.org.x + ray.dir.x * t,
	ray.org.y + ray.dir.y * t,
	ray.org.z + ray.dir.z * t)
	n = isect.pl.vsub(@center)
	isect.n = n.vnormalize
	else
	0.0
	end
	end
	nil
	end
	end

	class Plane
	def initialize(p, n)
	@p = p
	@n = n
	end

	def intersect(ray, isect)
	d = -@p.vdot(@n)
	v = ray.dir.vdot(@n)
	v0 = v
	if v < 0.0 then
	v0 = -v
	end
	if v0 < 1.0e-17 then
	return
	end

	t = -(ray.org.vdot(@n) + d) / v

	if t > 0.0 and t < isect.t then
	isect.hit = true
	isect.t = t
	isect.n = @n
	isect.pl = Vec.new(ray.org.x + t * ray.dir.x,
	ray.org.y + t * ray.dir.y,
	ray.org.z + t * ray.dir.z)
	end
	nil
	end
	end

	class Ray
	def initialize(org, dir)
	@org = org
	@dir = dir
	end

	attr_accessor :org, :dir
	end

	class Isect
	def initialize
	@t = 10000000.0
	@hit = false
	@pl = Vec.new(0.0, 0.0, 0.0)
	@n = Vec.new(0.0, 0.0, 0.0)
	end

	attr_accessor :t, :hit, :pl, :n
	end

	def clamp(f)
	i = f * 255.5
	if i > 255.0 then
	i = 255.0
	end
	if i < 0.0 then
	i = 0.0
	end
	i.to_i
	end

	def otherBasis(basis, n)
	basis[2] = Vec.new(n.x, n.y, n.z)
	basis[1] = Vec.new(0.0, 0.0, 0.0)

	if n.x < 0.6 and n.x > -0.6 then
	basis[1].x = 1.0
	elsif n.y < 0.6 and n.y > -0.6 then
	basis[1].y = 1.0
	elsif n.z < 0.6 and n.z > -0.6 then
	basis[1].z = 1.0
	else
	basis[1].x = 1.0
	end

	basis[0] = basis[1].vcross(basis[2])
	basis[0] = basis[0].vnormalize

	basis[1] = basis[2].vcross(basis[0])
	basis[1] = basis[1].vnormalize
	end

	class Scene
	def initialize
	@spheres = Array.new
	@spheres[0] = Sphere.new(Vec.new(-2.0, 0.0, -3.5), 0.5)
	@spheres[1] = Sphere.new(Vec.new(-0.5, 0.0, -3.0), 0.5)
	@spheres[2] = Sphere.new(Vec.new(1.0, 0.0, -2.2), 0.5)
	@plane = Plane.new(Vec.new(0.0, -0.5, 0.0), Vec.new(0.0, 1.0, 0.0))
	end

	def ambient_occlusion(isect)
	basis = Array.new
	otherBasis(basis, isect.n)

	ntheta = NAO_SAMPLES
	nphi = NAO_SAMPLES
	eps = 0.0001
	occlusion = 0.0

	p0 = Vec.new(isect.pl.x + eps * isect.n.x,
	isect.pl.y + eps * isect.n.y,
	isect.pl.z + eps * isect.n.z)
	nphi.times do \|j\|
	ntheta.times do \|i\|
	r = rand
	phi = 2.0 * 3.14159265 * rand
	x = Math.cos(phi) * Math.sqrt(1.0 - r)
	y = Math.sin(phi) * Math.sqrt(1.0 - r)
	z = Math.sqrt(r)

	rx = x * basis[0].x + y * basis[1].x + z * basis[2].x
	ry = x * basis[0].y + y * basis[1].y + z * basis[2].y
	rz = x * basis[0].z + y * basis[1].z + z * basis[2].z

	raydir = Vec.new(rx, ry, rz)
	ray = Ray.new(p0, raydir)

	occisect = Isect.new
	@spheres[0].intersect(ray, occisect)
	@spheres[1].intersect(ray, occisect)
	@spheres[2].intersect(ray, occisect)
	@plane.intersect(ray, occisect)
	if occisect.hit then
	occlusion = occlusion + 1.0
	else
	0.0
	end
	end
	end

	occlusion = (ntheta.to_f * nphi.to_f - occlusion) / (ntheta.to_f * nphi.to_f)

	Vec.new(occlusion, occlusion, occlusion)
	end

	def render(w, h, nsubsamples)
	cnt = 0
	nsf = nsubsamples.to_f
	h.times do \|y\|
	w.times do \|x\|
	rad = Vec.new(0.0, 0.0, 0.0)

	# Subsmpling
	nsubsamples.times do \|v\|
	nsubsamples.times do \|u\|

	cnt = cnt + 1
	wf = w.to_f
	hf = h.to_f
	xf = x.to_f
	yf = y.to_f
	uf = u.to_f
	vf = v.to_f

	px = (xf + (uf / nsf) - (wf / 2.0)) / (wf / 2.0)
	py = -(yf + (vf / nsf) - (hf / 2.0)) / (hf / 2.0)

	eye = Vec.new(px, py, -1.0).vnormalize

	ray = Ray.new(Vec.new(0.0, 0.0, 0.0), eye)

	isect = Isect.new
	@spheres[0].intersect(ray, isect)
	@spheres[1].intersect(ray, isect)
	@spheres[2].intersect(ray, isect)
	@plane.intersect(ray, isect)
	if isect.hit then
	col = ambient_occlusion(isect)
	rad.x = rad.x + col.x
	rad.y = rad.y + col.y
	rad.z = rad.z + col.z
	end
	end
	end

	r = rad.x / (nsf * nsf)
	g = rad.y / (nsf * nsf)
	b = rad.z / (nsf * nsf)
	printf("%c", clamp(r))
	printf("%c", clamp(g))
	printf("%c", clamp(b))
	end
	nil
	end

	nil
	end
	end

	alias printf_orig printf
	def printf *args
	end

	# File.open("ao.ppm", "w") do \|fp\|
	printf("P6\n")
	printf("%d %d\n", IMAGE_WIDTH, IMAGE_HEIGHT)
	printf("255\n", IMAGE_WIDTH, IMAGE_HEIGHT)
	Scene.new.render(IMAGE_WIDTH, IMAGE_HEIGHT, NSUBSAMPLES)
	# end

	undef printf
	alias printf printf_orig
	mem_end = `ps -o rss= -p #{$$}`.to_i
	puts mem_end - mem_start