def _rtt_load_attachment(cfg):
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
program = ngl.Program(vertex=cfg.get_vert('color'), fragment=cfg.get_frag('color'))
program.update_vert_out_vars(var_tex0_coord=ngl.IOVec2(), var_uvcoord=ngl.IOVec2())
background = ngl.Render(quad, program)
background.update_frag_resources(color=ngl.UniformVec4(value=COLORS['white']))
program = ngl.Program(vertex=cfg.get_vert('color'), fragment=cfg.get_frag('color'))
program.update_vert_out_vars(var_tex0_coord=ngl.IOVec2(), var_uvcoord=ngl.IOVec2())
render = ngl.Render(quad, program)
render.update_frag_resources(color=ngl.UniformVec4(value=COLORS['orange']))
texture = ngl.Texture2D(width=16, height=16)
rtt = ngl.RenderToTexture(render, [texture])
texture_noop = ngl.Texture2D(width=16, height=16)
rtt_noop = ngl.RenderToTexture(render, [texture_noop])
quad = ngl.Quad((0, 0, 0), (1, 0, 0), (0, 1, 0))
program = ngl.Program(vertex=cfg.get_vert('texture'), fragment=cfg.get_frag('texture'))
program.update_vert_out_vars(var_tex0_coord=ngl.IOVec2(), var_uvcoord=ngl.IOVec2())
foreground = ngl.Render(quad, program)
foreground.update_frag_resources(tex0=texture)
return ngl.Group(children=(background, rtt, rtt_noop, foreground))
def rtt_clear_attachment_with_timeranges(cfg):
cfg.aspect_ratio = (1, 1)
# Time-disabled full screen white quad
render = ngl.RenderColor(COLORS.white)
time_range_filter = ngl.TimeRangeFilter(render)
time_range_filter.add_ranges(ngl.TimeRangeModeNoop(0))
# Intermediate no-op RTT to force the use of a different render pass internally
texture = ngl.Texture2D(width=32, height=32)
rtt_noop = ngl.RenderToTexture(ngl.Identity(), [texture])
# Centered rotating quad
quad = ngl.Quad((-0.5, -0.5, 0), (1, 0, 0), (0, 1, 0))
render = ngl.RenderColor(COLORS.orange, geometry=quad)
animkf = [ngl.AnimKeyFrameFloat(0, 0), ngl.AnimKeyFrameFloat(cfg.duration, -360)]
render = ngl.Rotate(render, angle=ngl.AnimatedFloat(animkf))
group = ngl.Group(children=(time_range_filter, rtt_noop, render))
# Root RTT
texture = ngl.Texture2D(width=512, height=512)
rtt = ngl.RenderToTexture(group, [texture])
# Full screen render of the root RTT result
render = ngl.RenderTexture(texture)
return ngl.Group(children=(rtt, render))
def media_timeranges_rtt(cfg):
m0 = cfg.medias[0]
cfg.duration = d = 10
cfg.aspect_ratio = (m0.width, m0.height)
# Use a media/texture as leaf to exercise its prefetch/release mechanism
media = ngl.Media(m0.filename)
texture = ngl.Texture2D(data_src=media)
# Diamond tree on the same media texture
render0 = ngl.RenderTexture(texture, label="leaf 0")
render1 = ngl.RenderTexture(texture, label="leaf 1")
# Create intermediate RTT "proxy" to exercise prefetch/release at this
# level as well
dst_tex0 = ngl.Texture2D(width=m0.width, height=m0.height)
dst_tex1 = ngl.Texture2D(width=m0.width, height=m0.height)
rtt0 = ngl.RenderToTexture(render0, [dst_tex0])
rtt1 = ngl.RenderToTexture(render1, [dst_tex1])
# Render the 2 RTTs vertically split (one half content each)
quad0 = ngl.Quad((-1, -1, 0), (1, 0, 0), (0, 2, 0), uv_corner=(0, 0), uv_width=(0.5, 0))
quad1 = ngl.Quad((0, -1, 0), (1, 0, 0), (0, 2, 0), uv_corner=(0.5, 0), uv_width=(0.5, 0))
rtt_render0 = ngl.RenderTexture(dst_tex0, geometry=quad0, label="render RTT 0")
rtt_render1 = ngl.RenderTexture(dst_tex1, geometry=quad1, label="render RTT 1")
proxy0 = ngl.Group(children=(rtt0, rtt_render0), label="proxy 0")
proxy1 = ngl.Group(children=(rtt1, rtt_render1), label="proxy 1")
# We want to make sure the idle times are enough to exercise the
# prefetch/release mechanism
prefetch_time = 1
assert prefetch_time < d / 5
# Split the presentation in 5 segments such that there are inactive times,
# prefetch times and both overlapping and non-overlapping times for the
# RTTs
ranges0 = (
ngl.TimeRangeModeNoop(0),
ngl.TimeRangeModeCont(1 / 5 * d),
ngl.TimeRangeModeNoop(3 / 5 * d),
)
ranges1 = (
ngl.TimeRangeModeNoop(0),
ngl.TimeRangeModeCont(2 / 5 * d),
ngl.TimeRangeModeNoop(4 / 5 * d),
)
trange0 = ngl.TimeRangeFilter(proxy0, ranges=ranges0, prefetch_time=prefetch_time, label="left")
trange1 = ngl.TimeRangeFilter(proxy1, ranges=ranges1, prefetch_time=prefetch_time, label="right")
return ngl.Group(children=(trange0, trange1))
def _rtt_load_attachment():
background = ngl.RenderColor(COLORS.white)
render = ngl.RenderColor(COLORS.orange)
texture = ngl.Texture2D(width=16, height=16)
rtt = ngl.RenderToTexture(render, [texture])
texture_noop = ngl.Texture2D(width=16, height=16)
rtt_noop = ngl.RenderToTexture(render, [texture_noop])
quad = ngl.Quad((0, 0, 0), (1, 0, 0), (0, 1, 0))
foreground = ngl.RenderTexture(texture, geometry=quad)
return ngl.Group(children=(background, rtt, rtt_noop, foreground))
def rtt_clear_attachment_with_timeranges(cfg):
cfg.aspect_ratio = (1, 1)
# Time-disabled full screen white quad
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
program = ngl.Program(vertex=cfg.get_vert('color'),
fragment=cfg.get_frag('color'))
program.update_vert_out_vars(var_tex0_coord=ngl.IOVec2(),
var_uvcoord=ngl.IOVec2())
render = ngl.Render(quad, program)
render.update_frag_resources(color=ngl.UniformVec4(value=COLORS['white']))
time_range_filter = ngl.TimeRangeFilter(render)
time_range_filter.add_ranges(ngl.TimeRangeModeNoop(0))
# Intermediate no-op RTT to force the use of a different render pass internally
texture = ngl.Texture2D(width=32, height=32)
rtt_noop = ngl.RenderToTexture(ngl.Identity(), [texture])
# Centered rotating quad
quad = ngl.Quad((-0.5, -0.5, 0), (1, 0, 0), (0, 1, 0))
program = ngl.Program(vertex=cfg.get_vert('color'),
fragment=cfg.get_frag('color'))
program.update_vert_out_vars(var_tex0_coord=ngl.IOVec2(),
var_uvcoord=ngl.IOVec2())
render = ngl.Render(quad, program)
render.update_frag_resources(color=ngl.UniformVec4(value=COLORS['orange']))
animkf = [
ngl.AnimKeyFrameFloat(0, 0),
ngl.AnimKeyFrameFloat(cfg.duration, -360)
]
render = ngl.Rotate(render, anim=ngl.AnimatedFloat(animkf))
group = ngl.Group(children=(time_range_filter, rtt_noop, render))
# Root RTT
texture = ngl.Texture2D(width=512, height=512)
rtt = ngl.RenderToTexture(group, [texture])
# Full screen render of the root RTT result
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
program = ngl.Program(vertex=cfg.get_vert('texture'),
fragment=cfg.get_frag('texture'))
program.update_vert_out_vars(var_tex0_coord=ngl.IOVec2(),
var_uvcoord=ngl.IOVec2())
render = ngl.Render(quad, program)
render.update_frag_resources(tex0=texture)
return ngl.Group(children=(rtt, render))
def _get_texture_cubemap_from_mrt_scene_2_pass(cfg, samples=0):
group = ngl.Group()
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
cube = ngl.TextureCube(size=64, min_filter="linear", mag_filter="linear")
layer_base = 0
for layer_count, fragment in ((2, _RENDER_TO_CUBEMAP_1_FRAG),
(4, _RENDER_TO_CUBEMAP_2_FRAG)):
program = ngl.Program(vertex=_RENDER_TO_CUBEMAP_VERT,
fragment=fragment,
nb_frag_output=layer_count)
program.update_vert_out_vars(var_uvcoord=ngl.IOVec3())
render = ngl.Render(quad, program)
color_textures = [
ngl.TextureView(cube, layer)
for layer in range(layer_base, layer_base + layer_count)
]
rtt = ngl.RenderToTexture(render, color_textures, samples=samples)
group.add_children(rtt)
layer_base += layer_count
program = ngl.Program(vertex=_RENDER_CUBEMAP_VERT,
fragment=_RENDER_CUBEMAP_FRAG)
program.update_vert_out_vars(var_uvcoord=ngl.IOVec3())
render = ngl.Render(quad, program)
render.update_frag_resources(tex0=cube)
group.add_children(render)
return group
def _get_rtt_scene(cfg, features='depth', texture_ds_format=None, samples=0, mipmap_filter='none', sample_depth=False):
cfg.duration = 10
cfg.aspect_ratio = (1, 1)
cube = _get_cube()
program = ngl.Program(vertex=_RENDER_CUBE_VERT, fragment=_RENDER_CUBE_FRAG)
program.update_vert_out_vars(var_normal=ngl.IOVec3())
render = ngl.Render(cube, program)
render = ngl.Scale(render, (0.5, 0.5, 0.5))
for i in range(3):
rot_animkf = ngl.AnimatedFloat([
ngl.AnimKeyFrameFloat(0, 0),
ngl.AnimKeyFrameFloat(cfg.duration, 360 * (i + 1))
])
axis = [int(i == x) for x in range(3)]
render = ngl.Rotate(render, axis=axis, anim=rot_animkf)
config = ngl.GraphicConfig(render, depth_test=True)
camera = ngl.Camera(
config,
eye=(0.0, 0.0, 3.0),
center=(0.0, 0.0, 0.0),
up=(0.0, 1.0, 0.0),
perspective=(45.0, cfg.aspect_ratio_float),
clipping=(1.0, 10.0),
)
size = 1024
texture_depth = None
if texture_ds_format:
texture_depth = ngl.Texture2D(width=size, height=size, format=texture_ds_format)
texture = ngl.Texture2D(
width=size,
height=size,
min_filter='linear',
mipmap_filter=mipmap_filter,
)
rtt = ngl.RenderToTexture(
camera,
[texture],
features=features,
depth_texture=texture_depth,
samples=samples,
clear_color=(0, 0, 0, 1),
)
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
if sample_depth:
program = ngl.Program(vertex=cfg.get_vert('texture'), fragment=_RENDER_DEPTH)
program.update_vert_out_vars(var_tex0_coord=ngl.IOVec2(), var_uvcoord=ngl.IOVec2())
render = ngl.Render(quad, program)
render.update_frag_resources(tex0=texture_depth)
else:
program = ngl.Program(vertex=cfg.get_vert('texture'), fragment=cfg.get_frag('texture'))
program.update_vert_out_vars(var_tex0_coord=ngl.IOVec2(), var_uvcoord=ngl.IOVec2())
render = ngl.Render(quad, program)
render.update_frag_resources(tex0=texture)
return ngl.Group(children=(rtt, render))
def _shape_geometry_rtt(cfg, depth=False, samples=0):
w, h = 640, 480
scene = _shape_geometry(cfg, set_normals=True)
if depth:
scene = ngl.GraphicConfig(scene, depth_test=True)
texture = ngl.Texture2D()
texture.set_width(w)
texture.set_height(h)
rtt = ngl.RenderToTexture(scene)
rtt.add_color_textures(texture)
if depth:
texture = ngl.Texture2D()
texture.set_format('d16_unorm')
texture.set_width(w)
texture.set_height(h)
rtt.set_depth_texture(texture)
else:
rtt.set_clear_color(*COLORS['cgreen'])
if samples:
rtt.set_samples(samples)
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
program = ngl.Program(vertex=cfg.get_vert('texture'),
fragment=cfg.get_frag('texture'))
render = ngl.Render(quad, program)
render.update_textures(tex0=texture)
return ngl.Group(children=(rtt, render))
def _get_random_layer(cfg, rng, t0, t1, enable_computes, layer=4):
nb_elems = rng.randint(2, 5)
children = []
sub_layers = rng.sample(range(nb_elems), 2)
for i in range(nb_elems):
if i in sub_layers and layer != 0:
# Recursively create another layer
child = _get_random_layer(cfg,
rng,
t0,
t1,
enable_computes,
layer=layer - 1)
child = _get_random_transform(rng, t0, t1, child)
child.set_label(f"layer={layer}")
# Create a (small) RTT of the children
rtt_tex = ngl.Texture2D(
width=rng.randint(50, 90),
height=rng.randint(15, 70),
)
rtt = ngl.RenderToTexture(
child,
clear_color=_get_random_color(rng) + (1, ),
)
rtt.add_color_textures(rtt_tex)
rtt_render = ngl.RenderTexture(
rtt_tex,
geometry=_get_random_geometry(rng),
blending="src_over",
)
rtt_render = _get_random_transform(rng, t0, t1, rtt_render)
t_start, t_end = _get_random_time_range(rng, t0, t1)
rtt_group = ngl.Group(children=(rtt, rtt_render))
t_filter = ngl.TimeRangeFilter(rtt_group)
t_filter.add_ranges(
ngl.TimeRangeModeNoop(0),
ngl.TimeRangeModeCont(t_start),
ngl.TimeRangeModeNoop(t_end),
)
# Draw both the children and the rendered texture
child = ngl.Group(children=(t_filter, child))
else:
# We are at a leaf (last layer) so we create a random render
t_start, t_end = _get_random_time_range(rng, t0, t1)
child = _get_random_render(cfg, rng, t_start, t_end,
enable_computes)
if rng.random() < 1 / 3:
child = _get_random_transform(rng, t_start, t_end, child)
child = ngl.TimeRangeFilter(child)
child.add_ranges(
ngl.TimeRangeModeNoop(0),
ngl.TimeRangeModeCont(t_start),
ngl.TimeRangeModeNoop(t_end),
)
children.append(child)
return ngl.Group(children=children)
def cube(cfg, display_depth_buffer=False):
'''
Cube with a common media Texture but a different color tainting on each side.
Also includes a depth map visualization.
'''
cube = ngl.Group(label='cube')
frag_data = cfg.get_frag('tex-tint')
program = ngl.Program(fragment=frag_data)
texture = ngl.Texture2D(data_src=ngl.Media(cfg.medias[0].filename))
children = [_get_cube_side(texture, program, qi[0], qi[1], qi[2], qi[3]) for qi in _get_cube_quads()]
cube.add_children(*children)
for i in range(3):
rot_animkf = ngl.AnimatedFloat([ngl.AnimKeyFrameFloat(0, 0),
ngl.AnimKeyFrameFloat(cfg.duration, 360 * (i + 1))])
axis = [int(i == x) for x in range(3)]
cube = ngl.Rotate(cube, axis=axis, anim=rot_animkf)
config = ngl.GraphicConfig(cube, depth_test=True)
camera = ngl.Camera(config)
camera.set_eye(0.0, 0.0, 2.0)
camera.set_center(0.0, 0.0, 0.0)
camera.set_up(0.0, 1.0, 0.0)
camera.set_perspective(45.0, cfg.aspect_ratio_float)
camera.set_clipping(1.0, 10.0)
if not display_depth_buffer:
return camera
else:
group = ngl.Group()
depth_texture = ngl.Texture2D()
depth_texture.set_format('d16_unorm')
depth_texture.set_width(640)
depth_texture.set_height(480)
texture = ngl.Texture2D()
texture.set_width(640)
texture.set_height(480)
rtt = ngl.RenderToTexture(camera)
rtt.add_color_textures(texture)
rtt.set_depth_texture(depth_texture)
quad = ngl.Quad((-1.0, -1.0, 0), (1, 0, 0), (0, 1, 0))
program = ngl.Program()
render = ngl.Render(quad, program)
render.update_textures(tex0=texture)
group.add_children(rtt, render)
quad = ngl.Quad((0.0, 0.0, 0), (1, 0, 0), (0, 1, 0))
program = ngl.Program()
render = ngl.Render(quad, program)
render.update_textures(tex0=depth_texture)
group.add_children(rtt, render)
return group
def _rtt_load_attachment_nested(samples=0):
scene = _rtt_load_attachment()
texture = ngl.Texture2D(width=16, height=16)
rtt = ngl.RenderToTexture(scene, [texture], samples=samples)
foreground = ngl.RenderTexture(texture)
return ngl.Group(children=(rtt, foreground))
def histogram(cfg):
"""Histogram using compute shaders"""
m0 = cfg.medias[0]
cfg.duration = m0.duration
cfg.aspect_ratio = (m0.width, m0.height)
g = ngl.Group()
m = ngl.Media(cfg.medias[0].filename)
t = ngl.Texture2D(data_src=m)
h = ngl.Block(label="histogram_block", layout="std430")
h.add_fields(
ngl.BufferUInt(256, label="r"),
ngl.BufferUInt(256, label="g"),
ngl.BufferUInt(256, label="b"),
ngl.UniformUInt(label="maximum"),
)
r = ngl.RenderTexture(t)
proxy_size = 128
proxy = ngl.Texture2D(width=proxy_size, height=proxy_size)
rtt = ngl.RenderToTexture(r)
rtt.add_color_textures(proxy)
g.add_children(rtt)
compute_program = ngl.ComputeProgram(cfg.get_comp("histogram-clear"),
workgroup_size=(1, 1, 1))
compute_program.update_properties(hist=ngl.ResourceProps(writable=True))
compute = ngl.Compute(workgroup_count=(256, 1, 1),
program=compute_program,
label="histogram-clear")
compute.update_resources(hist=h)
g.add_children(compute)
local_size = 8
group_size = proxy_size / local_size
compute_program = ngl.ComputeProgram(cfg.get_comp("histogram-exec"),
workgroup_size=(local_size,
local_size, 1))
compute = ngl.Compute(workgroup_count=(group_size, group_size, 1),
program=compute_program,
label="histogram-exec")
compute.update_resources(hist=h, source=proxy)
compute_program.update_properties(hist=ngl.ResourceProps(writable=True))
compute_program.update_properties(source=ngl.ResourceProps(as_image=True))
g.add_children(compute)
q = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
p = ngl.Program(vertex=cfg.get_vert("histogram-display"),
fragment=cfg.get_frag("histogram-display"))
p.update_vert_out_vars(var_uvcoord=ngl.IOVec2(),
var_tex0_coord=ngl.IOVec2())
render = ngl.Render(q, p)
render.update_frag_resources(tex0=t, hist=h)
g.add_children(render)
return g
def histogram(cfg):
'''Histogram using compute shaders'''
m0 = cfg.medias[0]
cfg.duration = m0.duration
cfg.aspect_ratio = (m0.width, m0.height)
g = ngl.Group()
m = ngl.Media(cfg.medias[0].filename)
t = ngl.Texture2D(data_src=m)
h = ngl.Block(label='histogram_block', layout='std430')
h.add_fields(
ngl.BufferUInt(256, label='r'),
ngl.BufferUInt(256, label='g'),
ngl.BufferUInt(256, label='b'),
ngl.UniformInt(label='maximum'),
)
q = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
r = ngl.Render(q)
r.update_textures(tex0=t)
proxy_size = 128
proxy = ngl.Texture2D(width=proxy_size, height=proxy_size)
rtt = ngl.RenderToTexture(r)
rtt.add_color_textures(proxy)
g.add_children(rtt)
shader_version = '310 es' if cfg.backend == 'gles' else '430'
shader_header = '#version %s\n' % shader_version
if cfg.backend == 'gles' and cfg.system == 'Android':
shader_header += '#extension GL_ANDROID_extension_pack_es31a: require\n'
compute_program = ngl.ComputeProgram(shader_header + cfg.get_comp('histogram-clear'))
compute = ngl.Compute(256, 1, 1, compute_program, label='histogram-clear')
compute.update_blocks(histogram_buffer=h)
g.add_children(compute)
local_size = 8
group_size = proxy_size / local_size
compute_shader = cfg.get_comp('histogram-exec') % {'local_size': local_size}
compute_program = ngl.ComputeProgram(shader_header + compute_shader)
compute = ngl.Compute(group_size, group_size, 1, compute_program, label='histogram-exec')
compute.update_blocks(histogram_buffer=h)
compute.update_textures(source=proxy)
g.add_children(compute)
q = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
p = ngl.Program(vertex=shader_header + cfg.get_vert('histogram-display'),
fragment=shader_header + cfg.get_frag('histogram-display'))
render = ngl.Render(q, p)
render.update_textures(tex0=t)
render.update_blocks(histogram_buffer=h)
g.add_children(render)
return g
def texture_scissor(cfg):
cfg.aspect_ratio = (1, 1)
render = ngl.RenderColor(COLORS.orange)
graphic_config = ngl.GraphicConfig(render,
scissor_test=True,
scissor=(32, 32, 32, 32))
texture = ngl.Texture2D(width=64, height=64)
rtt = ngl.RenderToTexture(graphic_config, [texture],
clear_color=(0, 0, 0, 1))
render = ngl.RenderTexture(texture)
return ngl.Group(children=(rtt, render))
def texture_clear_and_scissor(cfg):
render = ngl.RenderColor(COLORS.white)
graphic_config = ngl.GraphicConfig(render,
scissor_test=True,
scissor=(0, 0, 0, 0),
color_write_mask="")
texture = ngl.Texture2D(width=64, height=64)
rtt = ngl.RenderToTexture(ngl.Identity(), [texture],
clear_color=list(COLORS.orange) + [1])
render = ngl.RenderTexture(texture)
return ngl.Group(children=(graphic_config, rtt, render))
def rtt_load_attachment_nested(cfg):
scene = _rtt_load_attachment(cfg)
texture = ngl.Texture2D(width=16, height=16)
rtt = ngl.RenderToTexture(scene, [texture])
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
program = ngl.Program(vertex=cfg.get_vert('texture'), fragment=cfg.get_frag('texture'))
program.update_vert_out_vars(var_tex0_coord=ngl.IOVec2(), var_uvcoord=ngl.IOVec2())
foreground = ngl.Render(quad, program)
foreground.update_frag_resources(tex0=texture)
return ngl.Group(children=(rtt, foreground))
def _get_texture_cubemap_from_mrt_scene(cfg, samples=0):
program = ngl.Program(vertex=_RENDER_TO_CUBEMAP_VERT,
fragment=_RENDER_TO_CUBEMAP_FRAG,
nb_frag_output=6)
program.update_vert_out_vars(var_uvcoord=ngl.IOVec3())
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
render = ngl.Render(quad, program)
cube = ngl.TextureCube(size=64, min_filter="linear", mag_filter="linear")
rtt = ngl.RenderToTexture(render, [cube], samples=samples)
program = ngl.Program(vertex=_RENDER_CUBEMAP_VERT,
fragment=_RENDER_CUBEMAP_FRAG)
program.update_vert_out_vars(var_uvcoord=ngl.IOVec3())
render = ngl.Render(quad, program)
render.update_frag_resources(tex0=cube)
return ngl.Group(children=(rtt, render))
def filter_gamma_correct(cfg, linear=True):
"""This test operates a gamma correct blending (the blending happens in linear space)"""
# Hue colors rotated clockwise
dst = ngl.RenderGradient4(
color_tl=COLORS.rose,
color_tr=COLORS.blue,
color_br=COLORS.sgreen,
color_bl=COLORS.yellow,
)
# Hue colors rotated counter-clockwise started with another color
src = ngl.RenderGradient4(
color_tl=COLORS.orange,
color_tr=COLORS.magenta,
color_br=COLORS.azure,
color_bl=COLORS.green,
)
# Screen blending so that working in linear space makes a significant
# difference
blend = ngl.GraphicConfig(
ngl.Group(children=(dst, src)),
blend=True,
blend_src_factor="one",
blend_dst_factor="one_minus_src_color",
blend_src_factor_a="one",
blend_dst_factor_a="zero",
)
# Intermediate RTT so that we can gamma correct the result
tex = ngl.Texture2D(width=320, height=240)
rtt = ngl.RenderToTexture(blend, color_textures=[tex])
render = ngl.RenderTexture(tex)
if linear:
# The result of the combination is linear
dst.add_filters(ngl.FilterSRGB2Linear())
src.add_filters(ngl.FilterSRGB2Linear())
# ...and we compress it back to sRGB
render.add_filters(ngl.FilterLinear2sRGB())
return ngl.Group(children=(rtt, render))
def texture_scissor(cfg):
cfg.aspect_ratio = (1, 1)
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
color = ngl.UniformVec4(COLORS['orange'])
program = ngl.Program(vertex=cfg.get_vert('color'),
fragment=cfg.get_frag('color'))
render = ngl.Render(quad, program)
render.update_uniforms(color=color)
graphic_config = ngl.GraphicConfig(render,
scissor_test=True,
scissor=(32, 32, 32, 32))
texture = ngl.Texture2D(width=64, height=64)
rtt = ngl.RenderToTexture(graphic_config, [texture])
program = ngl.Program(vertex=cfg.get_vert('texture'),
fragment=cfg.get_frag('texture'))
render = ngl.Render(quad, program)
render.update_textures(tex0=texture)
return ngl.Group(children=(rtt, render))
def texture_clear_and_scissor(cfg):
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
color = ngl.UniformVec4(COLORS['white'])
program = ngl.Program(vertex=cfg.get_vert('color'),
fragment=cfg.get_frag('color'))
render = ngl.Render(quad, program)
render.update_uniforms(color=color)
graphic_config = ngl.GraphicConfig(render,
scissor_test=True,
scissor=(0, 0, 0, 0))
texture = ngl.Texture2D(width=64, height=64)
rtt = ngl.RenderToTexture(ngl.Identity(), [texture],
clear_color=COLORS['orange'])
program = ngl.Program(vertex=cfg.get_vert('texture'),
fragment=cfg.get_frag('texture'))
render = ngl.Render(quad, program)
render.update_textures(tex0=texture)
return ngl.Group(children=(graphic_config, rtt, render))
def _get_texture_cubemap_from_mrt_scene(cfg, samples=0):
glsl_version = '300 es' if cfg.backend == 'gles' else '330'
glsl_header = '#version %s\n' % glsl_version
render_to_cubemap_vert = glsl_header + _RENDER_TO_CUBEMAP_VERT
render_to_cubemap_frag = glsl_header + _RENDER_TO_CUBEMAP_FRAG
program = ngl.Program(vertex=render_to_cubemap_vert,
fragment=render_to_cubemap_frag)
quad = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
render = ngl.Render(quad, program)
cube = ngl.TextureCube(size=64, min_filter="linear", mag_filter="linear")
rtt = ngl.RenderToTexture(render, [cube], samples=samples)
render_cubemap_vert = glsl_header + _RENDER_CUBEMAP_VERT
render_cubemap_frag = glsl_header + _RENDER_CUBEMAP_FRAG
program = ngl.Program(vertex=render_cubemap_vert,
fragment=render_cubemap_frag)
render = ngl.Render(quad, program)
render.update_textures(tex0=cube)
return ngl.Group(children=(rtt, render))
def histogram(cfg):
'''Histogram using compute shaders'''
m0 = cfg.medias[0]
cfg.duration = m0.duration
cfg.aspect_ratio = (m0.width, m0.height)
g = ngl.Group()
m = ngl.Media(cfg.medias[0].filename)
t = ngl.Texture2D(data_src=m)
h = ngl.Block(label='histogram_block', layout='std430')
h.add_fields(
ngl.BufferUInt(256, label='r'),
ngl.BufferUInt(256, label='g'),
ngl.BufferUInt(256, label='b'),
ngl.UniformUInt(label='maximum'),
)
q = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
p = ngl.Program(vertex=cfg.get_vert('texture'),
fragment=cfg.get_frag('texture'))
p.update_vert_out_vars(var_uvcoord=ngl.IOVec2(),
var_tex0_coord=ngl.IOVec2())
r = ngl.Render(q, p)
r.update_frag_resources(tex0=t)
proxy_size = 128
proxy = ngl.Texture2D(width=proxy_size, height=proxy_size)
rtt = ngl.RenderToTexture(r)
rtt.add_color_textures(proxy)
g.add_children(rtt)
compute_program = ngl.ComputeProgram(cfg.get_comp('histogram-clear'))
compute = ngl.Compute(256, 1, 1, compute_program, label='histogram-clear')
compute.update_resources(hist=h)
g.add_children(compute)
local_size = 8
group_size = proxy_size / local_size
compute_shader = cfg.get_comp('histogram-exec') % {
'local_size': local_size
}
compute_program = ngl.ComputeProgram(compute_shader)
compute = ngl.Compute(group_size,
group_size,
1,
compute_program,
label='histogram-exec')
compute.update_resources(hist=h, source=proxy)
compute_program.update_properties(source=ngl.ResourceProps(as_image=True))
g.add_children(compute)
q = ngl.Quad((-1, -1, 0), (2, 0, 0), (0, 2, 0))
p = ngl.Program(vertex=cfg.get_vert('histogram-display'),
fragment=cfg.get_frag('histogram-display'))
p.update_vert_out_vars(var_uvcoord=ngl.IOVec2(),
var_tex0_coord=ngl.IOVec2())
render = ngl.Render(q, p)
render.update_frag_resources(tex0=t, hist=h)
g.add_children(render)
return g
def cube(cfg, display_depth_buffer=False):
"""
Cube with a common media Texture but a different color tainting on each side.
Also includes a depth map visualization.
"""
cube = ngl.Group(label="cube")
vert_data = cfg.get_vert("texture")
frag_data = cfg.get_frag("tex-tint")
program = ngl.Program(vertex=vert_data, fragment=frag_data)
program.update_vert_out_vars(var_uvcoord=ngl.IOVec2(),
var_tex0_coord=ngl.IOVec2())
texture = ngl.Texture2D(data_src=ngl.Media(cfg.medias[0].filename))
children = [
_get_cube_side(texture, program, qi[0], qi[1], qi[2], qi[3])
for qi in _get_cube_quads()
]
cube.add_children(*children)
for i in range(3):
rot_animkf = ngl.AnimatedFloat([
ngl.AnimKeyFrameFloat(0, 0),
ngl.AnimKeyFrameFloat(cfg.duration, 360 * (i + 1))
])
axis = tuple(int(i == x) for x in range(3))
cube = ngl.Rotate(cube, axis=axis, angle=rot_animkf)
config = ngl.GraphicConfig(cube, depth_test=True)
camera = ngl.Camera(config)
camera.set_eye(0.0, 0.0, 2.0)
camera.set_center(0.0, 0.0, 0.0)
camera.set_up(0.0, 1.0, 0.0)
camera.set_perspective(45.0, cfg.aspect_ratio_float)
camera.set_clipping(1.0, 10.0)
if not display_depth_buffer:
return camera
else:
group = ngl.Group()
depth_texture = ngl.Texture2D()
depth_texture.set_format("auto_depth")
depth_texture.set_width(640)
depth_texture.set_height(480)
texture = ngl.Texture2D()
texture.set_width(640)
texture.set_height(480)
rtt = ngl.RenderToTexture(camera)
rtt.add_color_textures(texture)
rtt.set_depth_texture(depth_texture)
quad = ngl.Quad((-1.0, -1.0, 0), (1, 0, 0), (0, 1, 0))
render = ngl.RenderTexture(texture, geometry=quad)
group.add_children(rtt, render)
quad = ngl.Quad((0.0, 0.0, 0), (1, 0, 0), (0, 1, 0))
render = ngl.RenderTexture(depth_texture, geometry=quad)
group.add_children(rtt, render)
return group
