def makeSpotLight(renderer, parms, resMult, occlType): light = pvr.SpotLight() cam = pvr.PerspectiveCamera() # Position cam.setPosition(parms["position"]) # Orientation angles = parms["rotation"] pvr.euler = pvr.Euler(radians(angles.x), radians(angles.y), radians(angles.z)) cam.setOrientation(pvr.euler.toQuat()) # FOV cam.setVerticalFOV(parms["fov"]) # Resolution resolution = pvr.V2i(int(1024 * resMult), int(1024 * resMult)) cam.setResolution(resolution) # Intensity light.setIntensity(parms["intensity"]) # Camera light.setCamera(cam) # Number of samples numSamples = parms.get("num_samples", 32) # Occluder occluder = OCCLUDER_MAP.get(occlType, lambda *args: pvr.NullOccluder())( renderer, cam, numSamples, parms, resMult) light.setOccluder(occluder) return light
def makeLights(filename, renderer, mult=1.0): # Exec the file code = "\n".join(open(filename).readlines()) lights = eval(code) retLights = [] # Handle each light for lParms in lights: # Name pvr.logPrint("Adding light " + lParms["name"]) # Parms res = pvr.V2i(int(lParms["resx"] * mult), int(lParms["resy"] * mult)) pos = pvr.Vector(lParms["tx"], lParms["ty"], lParms["tz"]) euler = pvr.Euler(radians(lParms["rx"]), radians(lParms["ry"]), radians(lParms["rz"])) rot = euler.toQuat() fov = lParms["fov"] color = pvr.Color(lParms["color_r"], lParms["color_g"], lParms["color_b"]) intensity = lParms["intensity"] color.r = color.r * intensity color.g = color.g * intensity color.b = color.b * intensity # Create light light = pvr.PointLight() light.setPosition(pos) light.setIntensity(color) # Handle occluder type if lParms["shadow_type"] == "transmittance_map": if lParms["is_spotlight"]: # Create camera cam = pvr.PerspectiveCamera() cam.setPosition(pos) cam.setOrientation(rot) cam.setVerticalFOV(fov) cam.setResolution(res) # Create map render job mapRenderer = renderer.clone() mapRenderer.setCamera(cam) mapRenderer.setPrimaryEnabled(False) mapRenderer.setTransmittanceMapEnabled(True) mapRenderer.execute() # Set up occluder tMap = mapRenderer.transmittanceMap() tMap.printStats() occluder = pvr.TransmittanceMapOccluder() occluder.setTransmittanceMap(tMap) occluder.setCamera(cam) light.setOccluder(occluder) else: pvr.logWarning("Only spot lights supported for trans maps") elif lParms["shadow_type"] == "raymarch": occluder = pvr.RaymarchOccluder() occluder.setRaymarcher(renderer.raymarcher()) light.setOccluder(occluder) retLights.append(light) return retLights
def standard(resMult=1.0): # Settings resolution = pvr.V2i(int(2048 * resMult), int(1556 * resMult)) position = pvr.V3f(0.0, 0.0, 10.0) fov = degrees(pvr.calculateVerticalFOV(45.0, 24.0, resolution)) fovCurve = pvr.FloatCurve() fovCurve.addSample(0.0, fov) # Create camera cam = pvr.PerspectiveCamera() cam.setPosition(position) cam.setVerticalFOV(fovCurve) cam.setClipPlanes(0.1, 1.0) cam.setResolution(resolution) # Done return cam
def setupTransmittanceMap(baseRenderer, light, resolution, orientation, fov, raymarcherType, raymarcherParams, samplerType): rend = baseRenderer.clone() cam = pvr.PerspectiveCamera() cam.setPosition(light.position()) cam.setOrientation(orientation) cam.setVerticalFOV(fov) cam.setResolution(resolution) rend.setCamera(cam) rend.setPrimaryEnabled(False) rend.setTransmittanceMapEnabled(True) rend.execute() tMap = rend.transmittanceMap() tMap.printStats() occluder = pvr.TransmittanceMapOccluder() occluder.setTransmittanceMap(tMap) occluder.setCamera(cam) light.setOccluder(occluder)
def makeCamera(filename, mult=1.0): # Exec the file code = "\n".join(open(filename).readlines()) cam = eval(code) # Get static parameters res = pvr.V2i(int(cam["resx"] * mult), int(cam["resy"] * mult)) # Get (potentially) time varying parameters t0 = cam t1 = cam if "current_frame" in cam.keys() and "next_frame" in cam.keys(): t0 = cam["current_frame"] t1 = cam["next_frame"] posT0 = pvr.Vector(t0["tx"], t0["ty"], t0["tz"]) eulerT0 = pvr.Euler(radians(t0["rx"]), radians(t0["ry"]), radians(t0["rz"])) rotT0 = eulerT0.toQuat() fovT0 = degrees(pvr.calculateVerticalFOV(t0["focal"], t0["aperture"], res)) posT1 = pvr.Vector(t1["tx"], t1["ty"], t1["tz"]) eulerT1 = pvr.Euler(radians(t1["rx"]), radians(t1["ry"]), radians(t1["rz"])) rotT1 = eulerT1.toQuat() fovT1 = degrees(pvr.calculateVerticalFOV(t1["focal"], t1["aperture"], res)) # Create animation curves pTimeNext = 1.0 / pvr.RenderGlobals.shutter() pos = pvr.VectorCurve() rot = pvr.QuatCurve() fov = pvr.FloatCurve() pos.addSample(0.0, posT0) pos.addSample(pTimeNext, posT1) rot.addSample(0.0, rotT0) rot.addSample(pTimeNext, rotT1) fov.addSample(0.0, fovT0) fov.addSample(pTimeNext, fovT1) # Construct camera camera = pvr.PerspectiveCamera() camera.setPosition(pos) camera.setOrientation(rot) camera.setVerticalFOV(fov) camera.setClipPlanes(0.1, 1.0) camera.setResolution(res) return camera