40 changed files with 214 additions and 258 deletions
--- a/src/product_gen/pycache/generate_lamp.cpython-35.pyc
+++ b/src/product_gen/pycache/generate_lamp.cpython-35.pyc
--- a/src/product_gen/pycache/generate_product.cpython-35.pyc
+++ b/src/product_gen/pycache/generate_product.cpython-35.pyc
--- a/src/product_gen/pycache/generate_shades.cpython-35.pyc
+++ b/src/product_gen/pycache/generate_shades.cpython-35.pyc
--- a/src/product_gen/generate_lamp.py
+++ b/src/product_gen/generate_lamp.py
@ -6,20 +6,18 @@ import product_gen.generate_shades as gs
 def generate_models(shape_parameters):
    # Shade
    print(shape_parameters["shape"])
    if shape_parameters["shape"] == "mesh":
        shade = gs.generate_mesh_shade(shape_parameters)
-    elif shape_parameters["shape"] == "led" or shape_parameters["shape"] == "bio":
+    elif shape_parameters["shape"] == "led":
        shade = gs.generate_led_shade(shape_parameters)      
    else: # default pendant
        print("doing pendant")
        shade = gs.generate_pendant_shade(shape_parameters)   
    # Base
    if "bio" not in shape_parameters["shape"]:
-        radius1 = shape_parameters["fixture_radius"]
+        radius1 = 0.3
        radius2 = 0.07
-        depth = shape_parameters["fixture_length"]
+        depth = 0.5
        location = (0.0, 0.0, depth/2.0)
        base = product_gen.generate_lamp_base.generate_cone_base(radius1, 
                                                                 radius2, 
@ -27,7 +25,7 @@ def generate_models(shape_parameters):
                                                                 location)
        # Chord
        radius = 0.05
-        height = 10.0
+        height = 6.0
        location = (0.0, 0.0, height/2.0)
        chord = product_gen.generate_lamp_base.generate_chord(height, 
                                                              radius, 
--- a/src/product_gen/generate_product.py
+++ b/src/product_gen/generate_product.py
@ -4,12 +4,10 @@ import bpy
 import product_gen.generate_lamp
 import rendering.setup_scene
 import rendering.setup_renderer
 from shapes.shape_description import _styles
 def generate(shape_parameters, output_prefix, is_final=False):
-    rendering.setup_renderer.setup_renderer(shape_parameters,
+    rendering.setup_renderer.setup_renderer(shape_parameters)
                                             is_final)
    rendering.setup_scene.initialize_scene(shape_parameters)
@ -20,13 +18,13 @@ def generate(shape_parameters, output_prefix, is_final=False):
    product_gen.generate_lamp.optimize_for_render(models)
    # Set up materials and textures
-    style = _styles[shape_parameters["style"]]
+    color = (0.1, 0.1, 0.1)
    if "bio" not in shape_parameters["shape"]:
-        colormap = {"shade": style["shade"],
+        colormap = {"shade": color,
-                    "base": style["base"],
+                    "base": (132.0/255.0, 64.0/255.0, 11.0/255.0),
-                    "chord": style["chord"]}
+                    "chord": (5.0/255.0, 5.0/255.0, 5.0/255.0)}
    else:
-        colormap = {"shade": style["shade"]}
+        colormap = {"shade": color}
    product_gen.generate_lamp.apply_textures(colormap, models)
@ -35,8 +33,15 @@ def generate(shape_parameters, output_prefix, is_final=False):
    # Do rendering
    prefix = os.getcwd() + "/" + output_prefix + "/" + output_prefix
    if is_final:
-        bpy.context.scene.render.filepath = prefix + "_highres.png"
+        bpy.context.scene.render.filepath = prefix + "_kitchen.png"
        bpy.ops.render.render(write_still=True)
        bpy.context.scene.render.filepath = prefix + "_hall.png"
        bpy.ops.render.render(write_still=True)
        bpy.context.scene.render.filepath = prefix + "_landing.png"
        bpy.ops.render.render(write_still=True)
    else:
        bpy.context.scene.render.filepath = prefix + ".png"
        bpy.ops.render.render(write_still=True)
--- a/src/product_gen/generate_shades.py
+++ b/src/product_gen/generate_shades.py
@ -14,57 +14,86 @@ def UpOrDown(normal):
        return True
    return False
 def morph_shape(x, L, H, morph_type="linear"):
    y = H
    if morph_type == "linear":
        y = (x/L)*H
    elif morph_type == "logistic":
        k = 10.0
        v = 1.0
        y = H/(1.0 + math.exp(-k*(x-L/4.0))**v)
    elif morph_type == "sinusoid":
        y = math.sin((x/L)*math.pi/2.0)
    elif morph_type == "hyperbolic_tan":
        y = math.tanh((x/L)*math.pi/2.0)
    elif morph_type == "circle":
        y = math.sqrt(L*L-(L-x)**2)         
    return y
 def generate_pendant_shade(shape_parameters):
    radius = shape_parameters["radius"]
    depth = shape_parameters["height"]
    print(depth)
    bpy.ops.mesh.primitive_cylinder_add(radius=radius,
                                        depth=depth)
    cone = bpy.data.objects["Cylinder"]
    cone.name = "shade"
    bpy.ops.object.mode_set(mode='EDIT')
    num_subdivisions = 3
    if len(shape_parameters["division_offsets"])>3:
        num_subdivisions = 4
    for idx in range(num_subdivisions):
        bpy.ops.mesh.subdivide()
    bm = bmesh.from_edit_mesh(cone.data)
    num_verts = len(bm.verts)
    summed_offset = 0.0
    for jdx in range(len(shape_parameters["division_offsets"])):
        summed_offset += shape_parameters["division_offsets"][jdx]
    for idx in range(num_verts):
        bm.verts.ensure_lookup_table()
        vert = bm.verts[idx]
        vert.co.z = vert.co.z -depth/2.0
        theta = math.atan2(vert.co.x, vert.co.y)
        vert.co.z = vert.co.z -depth/2.0
-        if abs(vert.co.z)<shape_parameters["stem_length"]:
+        delta = abs(vert.co.z)
-            rad = shape_parameters["fixture_radius"]
+        frac = delta/depth
        summed_offset = 0.0
        prev_offset = 0.0
        division_index = len(shape_parameters["division_offsets"])-1
        for jdx in range(len(shape_parameters["division_offsets"])):
            prev_offset = summed_offset
            summed_offset += shape_parameters["division_offsets"][jdx]
            if frac >=prev_offset and frac <= summed_offset:
                division_index = jdx
        current_offset = shape_parameters["division_offsets"][division_index]                              
        division_type = shape_parameters["division_patterns"][division_index]
        if division_index==0:          
            division_radius = shape_parameters["fixture_radius"]
            previous_offset = 0.0
            previous_radius = division_radius
        else:
-            rad = morph_shape(abs(vert.co.z)-shape_parameters["stem_length"], 
+            division_radius = shape_parameters["radius"]*shape_parameters["division_radii"][division_index]   
-                              depth-shape_parameters["stem_length"], 
+            previous_offset = shape_parameters["division_offsets"][division_index-1]
-                              radius-shape_parameters["fixture_radius"], 
+            previous_radius = shape_parameters["radius"]*shape_parameters["division_radii"][division_index-1]
-                              morph_type=shape_parameters["division_pattern"])
+            if previous_radius< shape_parameters["fixture_radius"]:
-            rad += shape_parameters["fixture_radius"]
+                previous_radius = shape_parameters["fixture_radius"]
-        vert.co.x = rad*math.sin(theta)
+                       
-        vert.co.y = rad*math.cos(theta)        
+        if division_radius<previous_radius:
            division_radius = previous_radius
        if division_type == "square":
            mapped_rad = division_radius + (frac)**2
            vert.co.x = mapped_rad*math.sin(theta)
            vert.co.y = mapped_rad*math.cos(theta)
        elif division_type == "sine":
            mapped_rad = division_radius + math.sin(math.pi/2.0*frac)
            vert.co.x = mapped_rad*math.sin(theta)
            vert.co.y = mapped_rad*math.cos(theta)
        elif division_type == "ramp":
            mapped_rad = division_radius + frac
            vert.co.x = mapped_rad*math.sin(theta)
            vert.co.y = mapped_rad*math.cos(theta)
        elif division_type == "inv_ramp":
            mapped_rad = division_radius + frac
            vert.co.x = mapped_rad*math.sin(theta)
            vert.co.y = mapped_rad*math.cos(theta)
        else: #straight
            vert.co.x = division_radius*math.sin(theta)
            vert.co.y = division_radius*math.cos(theta)  
    for face in bm.faces:
        if UpOrDown(face.normal):
            face.select = True
@ -84,53 +113,57 @@ def generate_pendant_shade(shape_parameters):
    bpy.ops.object.mode_set(mode='OBJECT')
    return cone
-def generate_mesh_shade(shape_parameters):
+def generate_cone_shade(radius1, radius2, depth):
-    radius1 = shape_parameters["radius"]
+    bpy.ops.mesh.primitive_cone_add(radius1=radius1,
-    depth = shape_parameters["height"]
+                                    radius2=radius2,
-    radius2 = shape_parameters["fixture_radius"]
+                                    depth=depth)
    cone = bpy.data.objects["Cone"]
    cone.name = "shade"
    bpy.ops.object.mode_set(mode='EDIT')
    bm = bmesh.from_edit_mesh(cone.data)
    for face in bm.faces:
        if UpOrDown(face.normal):
            face.select = True
        else:
            face.select = False 
    faces_select = [f for f in bm.faces if f.select] 
    bmesh.ops.delete(bm, geom=faces_select, context=3)
    bmesh.update_edit_mesh(cone.data, True)
    # Extrude faces
    bpy.ops.mesh.select_mode( type  = 'FACE'   )
    bpy.ops.mesh.select_all( action = 'SELECT' )
    bpy.ops.mesh.extrude_region_move(
        TRANSFORM_OT_translate={"value":(0, 0, 0.01)} ) 
    bpy.ops.mesh.extrude_region_shrink_fatten(
        TRANSFORM_OT_shrink_fatten={"value":-0.05})
    bpy.ops.object.mode_set(mode='OBJECT')
    return cone
 def generate_mesh_shade(radius1, radius2, depth):
    bpy.ops.mesh.primitive_cube_add(radius=radius1)
    cube = bpy.data.objects["Cube"]
    cube.name = "shade"
    bpy.ops.object.mode_set(mode='EDIT')
-    num_subdivisions = 4
+    for idx in range(3):
    for idx in range(num_subdivisions):
        bpy.ops.mesh.subdivide()
    bm = bmesh.from_edit_mesh(cube.data)
    slat_thickness = 0.06
    max_rad = 0.0
    max_z = 0.0
    min_z = 0.0
    rad_min_z = 0.0
    for i in range( len( bm.verts ) ):
        bm.verts.ensure_lookup_table()
        vert = bm.verts[i]
-        
+        #theta = math.atan2(vert.co.x, vert.co.y)
        vert.co.z = vert.co.z - radius1
-        vert.co.z *= depth/(2.0*radius1)
+        vert.co.z = vert.co.z*2.0
-        vert.co.y = vert.co.y*(slat_thickness/(2.0*radius1))
+        height = radius1*2.0
-        vert.co.x = vert.co.x*(slat_thickness/(2.0*radius1))
+        vert.co.y = vert.co.y*0.03
-        
+        vert.co.x = vert.co.x*0.1 + radius1/2.0
-        if abs(vert.co.z)<shape_parameters["stem_length"]:
+        theta = abs(vert.co.z/height)
-            rad = shape_parameters["fixture_radius"]
+        vert.co.x = vert.co.x + 2.0*radius1*math.sin(theta)
-        else:
+        vert.co.z = vert.co.z + 1.0*radius1
            rad = morph_shape(1.0*(abs(vert.co.z)-shape_parameters["stem_length"]), 
                              depth-shape_parameters["stem_length"], 
                              radius1-shape_parameters["fixture_radius"], 
                              morph_type=shape_parameters["division_pattern"])
            rad += shape_parameters["fixture_radius"]
        vert.co.x += rad
        if vert.co.x>max_rad:
            max_rad = vert.co.x
            max_z = vert.co.z
        if vert.co.z<min_z:
            min_z = vert.co.z
            rad_min_z = vert.co.x
    bpy.ops.object.mode_set(mode='OBJECT')
    num_slats = 36
@ -144,13 +177,8 @@ def generate_mesh_shade(shape_parameters):
        scene.update()    
    # Add torus
-    bpy.ops.mesh.primitive_torus_add(location=(0.0, 0.0, max_z),
+    bpy.ops.mesh.primitive_torus_add(location=(0.0, 0.0, -2.6*radius1),
-                                     major_radius=max_rad, 
+                                     major_radius=2.4*radius1, 
                                     minor_radius=0.02)  
    if (abs(min_z)-abs(max_z))>0.5:
        bpy.ops.mesh.primitive_torus_add(location=(0.0, 0.0, min_z),
                                         major_radius=rad_min_z, 
                                     minor_radius=0.02)        
    for ob in bpy.context.scene.objects:
@ -190,11 +218,7 @@ def make_square_ring(radius, depth, thickness):
    bpy.ops.object.mode_set(mode='OBJECT')
    return bpy.data.objects["square_ring"]   
-def generate_led_shade(shape_parameters):
+def generate_led_shade(radius1, radius2, depth):
    radius1 = shape_parameters["radius"]
    depth = shape_parameters["height"]
    radius2 = shape_parameters["fixture_radius"]
    ring1 = make_square_ring(3.0*radius1, depth/10.0, 0.2)
    bpy.ops.transform.rotate(value=-math.pi/12.0, axis=(1.0,0.0,0.0))
--- a/src/rendering/pycache/setup_renderer.cpython-35.pyc
+++ b/src/rendering/pycache/setup_renderer.cpython-35.pyc
--- a/src/rendering/pycache/setup_scene.cpython-35.pyc
+++ b/src/rendering/pycache/setup_scene.cpython-35.pyc
--- a/src/rendering/setup_renderer.py
+++ b/src/rendering/setup_renderer.py
@ -1,32 +1,23 @@
 import bpy
-def setup_renderer(shape_parameters, is_final=False, engine="CYCLES"):
+def setup_renderer(shape_parameters, engine="CYCLES"):
    # Set up and do the render
    this_scene = bpy.context.scene
    if engine=="CYCLES":
        this_scene.render.engine = 'CYCLES'
-        this_scene.cycles.samples = 100.0
+        this_scene.cycles.device = 'GPU'
        this_scene.cycles.samples = 12.0
        this_scene.cycles.caustics_reflective = False
        this_scene.cycles.caustics_refractive = False
        this_scene.cycles.max_bounces = 0.0
    this_scene.render.use_border = False
    this_scene.render.use_simplify = True
    this_scene.render.border_max_y = 0.75
    this_scene.render.border_min_y = 0.33
    this_scene.render.border_min_x = 0.25 
    this_scene.render.border_max_x = 0.65 
    if is_final:
        this_scene.render.resolution_x = 1200.0
        this_scene.render.resolution_y = 1200.0        
    else:
    this_scene.render.resolution_x = 600.0
    this_scene.render.resolution_y = 600.0
    this_scene.render.tile_x = 32
    this_scene.render.tile_y = 32
-
+    this_scene.render.resolution_percentage = 50.0   
    if is_final:
        this_scene.render.resolution_percentage = 70.0
    else:
        this_scene.render.resolution_percentage = 100.0
    this_scene.render.image_settings.compression = 60.0  
--- a/src/rendering/setup_scene.py
+++ b/src/rendering/setup_scene.py
@ -11,12 +11,9 @@ def initialize_scene(shape_parameters):
 def setup_scene(shape_parameters): 
    # Set up world
    use_backwall = False
    if not use_backwall:
    bpy.context.scene.world.use_sky_paper = True
-        bpy.context.scene.world.horizon_color = (1.0, 1.0, 1.0)
+    bpy.context.scene.world.horizon_color = (0.99, 0.8, 0.8)
    #bpy.context.scene.world.light_settings.use_environment_light = True
    else:
    # Add back wall
    bpy.ops.mesh.primitive_plane_add(radius=20, location=(-10.0, 0.0, 0.0))
@ -38,22 +35,13 @@ def setup_scene(shape_parameters):
        bpy.context.active_object.data.materials.append(mat)     
    # Set up cameras
-    radius = shape_parameters["radius"]
+    bpy.data.objects["Camera"].location = (10.0, 0.0, -4)
    height = shape_parameters["height"]
    xloc = 1.5 + (3.0*radius + height)/2.0
    zloc = -0.4 - height
    if shape_parameters["shape"] == "bio" or shape_parameters["shape"] == "led":
        bpy.data.objects["Camera"].location = (13, 0.0000, -3.0)
    else:
        bpy.data.objects["Camera"].location = (xloc, 0.0000, zloc)
    fov = 65.0
    bpy.data.objects["Camera"].data.angle = fov*(math.pi/180.0)
    bpy.data.objects["Camera"].rotation_mode = 'XYZ'
-    bpy.data.objects["Camera"].rotation_euler[0] = 1.9326
+    bpy.data.objects["Camera"].rotation_euler[0] = math.pi/2.0
    bpy.data.objects["Camera"].rotation_euler[1] = 0.0
-    bpy.data.objects["Camera"].rotation_euler[2] = 1.5708
+    bpy.data.objects["Camera"].rotation_euler[2] = math.pi/2.0 
    # Lamps
    bpy.data.scenes['Scene'].objects.unlink(bpy.data.objects["Lamp"])
@ -81,13 +69,9 @@ def setup_scene(shape_parameters):
        bpy.context.active_object.data.materials.append(mat) 
    bpy.ops.mesh.primitive_plane_add(radius=5, location=(10.0, 10.0, -5.0))
-    #bpy.ops.transform.rotate(value=-math.pi/2.0, axis=(1.0,2.0,0.0))
+    bpy.ops.transform.rotate(value=-math.pi/2.0, axis=(1.0,2.0,0.0))
-    #bpy.ops.transform.rotate(value=-math.pi/4.0, axis=(0.0,0.0,1.0))
+    bpy.ops.transform.rotate(value=-math.pi/4.0, axis=(0.0,0.0,1.0))
    bpy.data.objects["Plane"].name = "fill_lamp" 
    bpy.data.objects["fill_lamp"].location = (10.0, 10.0, -5.0)
    bpy.data.objects["fill_lamp"].rotation_euler[0] = 0.6454
    bpy.data.objects["fill_lamp"].rotation_euler[1] = 0.7169
    bpy.data.objects["fill_lamp"].rotation_euler[2] = 0.0000
    mat = bpy.data.materials.get("fill-material")
    if mat is None:
--- a/src/shapes/pycache/shape_description.cpython-35.pyc
+++ b/src/shapes/pycache/shape_description.cpython-35.pyc
--- a/src/shapes/shape_description.py
+++ b/src/shapes/shape_description.py
@ -2,42 +2,39 @@ import random
 import copy
 _shape_description = {"shape": "pendant",
-                      "division_pattern": "linear",
+                      "division_patterns": [],
-                      "division_param1": 1.0,
+                      "division_offsets": [],
-                      "division_param2": 1.0,
+                      "division_radii": [],
                      "radius": 1.0,
                      "height": 1.0,
                      "fixture_radius": 0.3,
-                      "fixture_length": 0.3,
+                      "style": "dark"}
                      "stem_length": 0.5,
                      "style": "initial"}
-_styles = { "dark" : {"shade": (0.68, 0.68, 0.6),
+_styles = {"dark" : {"shade": (0.1, 0.1, 0.1),
-            "chord": (5.0/255.0, 5.0/255.0, 5.0/255.0),
+            "chord": (0.05, 0.05, 0.05),
-            "base": (132.0/255.0, 64.0/255.0, 11.0/255.0),
+            "base": (0.05, 0.05, 0.05),
            "use_wall": True,
            "wall": (0.9, 0.9, 0.9)},
-           "initial" : {"shade": (0.1, 0.1, 0.1),
+           "billard": {"shade": (0.1, 0.1, 0.1),
-            "chord": (5.0/255.0, 5.0/255.0, 5.0/255.0),
+            "chord": (0.05, 0.05, 0.05),
-            "base": (132.0/255.0, 64.0/255.0, 11.0/255.0),
+            "base": (0.05, 0.05, 0.05),
            "use_wall": True,
            "wall": (0.9, 0.9, 0.9)},
-           "billard": {"shade": (0.033, 0.065, 0.376),
+           "light": {"shade": (0.1, 0.1, 0.1),
-            "chord": (5.0/255.0, 5.0/255.0, 5.0/255.0),
+            "chord": (0.05, 0.05, 0.05),
-            "base": (132.0/255.0, 64.0/255.0, 11.0/255.0),
+            "base": (0.05, 0.05, 0.05),
            "use_wall": True,
            "wall": (0.9, 0.9, 0.9)},             
-           "light": {"shade": (0.019, 0.202, 0.032),
+           }
-            "chord": (5.0/255.0, 5.0/255.0, 5.0/255.0),
+
-            "base": (132.0/255.0, 64.0/255.0, 11.0/255.0),
+_division_types = ["straight",
-            "use_wall": True,
+                   "square",
-            "wall": (0.9, 0.9, 0.9)}, }
+                   "inv_square",
                   "sine",
                   "inv_sine",
                   "ramp",
                   "inv_ramp"]
 _division_types = ["linear",
                   "logistic",
                   "sinusoid",
                   "hyperbolic_tan",
                   "circle"]
 def get_random_shape_description(shape, bbox, feature_min):
@ -47,11 +44,27 @@ def get_random_shape_description(shape, bbox, feature_min):
    shape_description = copy.deepcopy(_shape_description)
    shape_description["shape"] = shape
    feature_radius = feature_min[0] + random.random()*(bbox[0]-feature_min[0])
    feature_height = feature_min[1] + random.random()*(bbox[1]-feature_min[1])
    max_divisions = 5
    num_divisions = int(1 + random.random()*(max_divisions-1))
    num_divisions = 4
    remaining_offset = 1.0
    feature_height = feature_min[1] + random.random()*(bbox[1]-feature_min[1])
    feature_radius = feature_min[0] + random.random()*(bbox[0]-feature_min[0])
    shape_description["height"] = feature_height
    shape_description["radius"] = feature_radius
-    shape_description["division_pattern"] = random.choice(_division_types)
+    
-    shape_description["style"] = "initial"
+    min_radius_fraction = feature_min[0]/feature_radius
    for idx in range(num_divisions):
        shape_description["division_patterns"].append(random.choice(_division_types))
        offset = 1.0/num_divisions
        #offset = random.random()*remaining_offset
        remaining_offset -= offset
        shape_description["division_offsets"].append(offset)
        radius_fraction = min_radius_fraction+random.random()*(1.0-min_radius_fraction)
        shape_description["division_radii"].append(radius_fraction)
    shape_description["style"] = random.choice(list(_styles.keys()))
    shape_description["division_radii"].sort()
    return shape_description
--- a/src/utility/apply_texture.py
+++ b/src/utility/apply_texture.py
@ -1,10 +1,8 @@
 import os
 import sys
 import ast
 import random
 import json
 import product_gen.generate_product
 from shapes.shape_description import _styles
 from argparse import ArgumentParser
@ -19,20 +17,17 @@ if __name__ == "__main__":
    if not os.path.exists(os.getcwd() + "/" + output):
        os.makedirs(os.getcwd() + "/" + output)
-    shape_parameters = {}
+    height = float(shape_params["height"])
-    shape_parameters["shape"] = shape
+    radius = float(shape_params["radius"])
    shape_parameters["output"] = output
    shape_parameters["height"] = float(shape_params["height"])
    shape_parameters["radius"] = float(shape_params["radius"])
    shape_parameters["fixture_radius"] = float(shape_params["fixture_radius"])
    shape_parameters["fixture_length"] = float(shape_params["fixture_length"])
    shape_parameters["stem_length"] = float(shape_params["stem_length"])
    shape_parameters["style"] = random.choice(list(_styles.keys()))
    shape_parameters["division_pattern"] = shape_params["division_pattern"]
    shape_parameters["division_param1"] = float(shape_params["division_param1"])
    shape_parameters["division_param2"] = float(shape_params["division_param2"])
-    product_gen.generate_product.generate(shape_parameters, output)
+    colors = [(0.1, 0.1, 0.1),
              (0.68, 0.68, 0.68),
              (0.033, 0.065, 0.376),
              (0.019, 0.202, 0.032)]
    color = random.choice(colors)
    product_gen.generate_product.generate(shape, height, radius, color, output)
    shape_parameters = shape_params
    shape_parameters["color"] = color
    with open(os.getcwd() + "/" + output + "/"+ output + '.json', 'w') as outfile:
        json.dump(shape_parameters, outfile)
--- a/src/utility/final_render.py
+++ b/src/utility/final_render.py
@ -18,17 +18,9 @@ if __name__ == "__main__":
    if not os.path.exists(os.getcwd() + "/" + output):
        os.makedirs(os.getcwd() + "/" + output)
-    shape_parameters = {}
+    height = float(shape_params["height"])
-    shape_parameters["shape"] = shape
+    radius = float(shape_params["radius"])
-    shape_parameters["output"] = output
+    color = ast.literal_eval(shape_params["color"])
-    shape_parameters["height"] = float(shape_params["height"])
+    print(color[0])
-    shape_parameters["radius"] = float(shape_params["radius"])
+    product_gen.generate_product.generate(shape, height, radius, 
-    shape_parameters["fixture_radius"] = float(shape_params["fixture_radius"])
+                                       color, output, is_final=True)
    shape_parameters["fixture_length"] = float(shape_params["fixture_length"])
    shape_parameters["stem_length"] = float(shape_params["stem_length"])
    shape_parameters["style"] = shape_params["style"]
    shape_parameters["division_pattern"] = shape_params["division_pattern"]
    shape_parameters["division_param1"] = float(shape_params["division_param1"])
    shape_parameters["division_param2"] = float(shape_params["division_param2"])
    product_gen.generate_product.generate(shape_parameters, output, is_final=True)
--- a/src/utility/generate_shape.py
+++ b/src/utility/generate_shape.py
@ -23,18 +23,16 @@ if __name__ == "__main__":
        os.makedirs(os.getcwd() + "/" + output)
    # Global bounding box
-    bbox_xmax = 3.0
+    bbox_xmax = 4.0
-    bbox_ymax = 3.0
+    bbox_ymax = 5.0
    # Minimum feature sizes
-    feature_xmin = 1.0
+    feature_xmin = 0.4
    feature_ymin = 1.0
    shape_parameters = sd.get_random_shape_description(shape, 
                                                       [bbox_xmax, bbox_ymax],
                                                       [feature_xmin, feature_ymin])
    shape_parameters = product_gen.generate_product.generate(shape_parameters, output)
    shape_parameters["output"] = output
    with open(os.getcwd() + "/" + output + "/"+ output + '.json', 'w') as outfile:
        json.dump(shape_parameters, outfile)
--- a/src/utility/test456/test456.blend
+++ b/src/utility/test456/test456.blend
--- a/src/utility/test456/test456.blend1
+++ b/src/utility/test456/test456.blend1
--- a/src/utility/test456/test456.json
+++ b/src/utility/test456/test456.json
@ -1 +1 @@
-{"fixture_radius": 0.3, "output": "test456", "radius": 1.8287633826475211, "height": 3.910662786988026, "division_patterns": ["ramp", "sine", "sine", "inv_sine"], "division_radii": [0.4473225094039008, 0.5963619022128677, 0.7765883654637191, 0.889395569488088], "division_offsets": [0.25, 0.25, 0.25, 0.25], "style": "billard", "shape": "bio"}
+{"fixture_radius": 0.3, "division_radii": [0.7366486532785445, 0.8362702452541098, 0.9661599163089211, 0.9867733391465805], "radius": 0.611924774203075, "division_patterns": ["inv_square", "inv_ramp", "sine", "inv_square"], "shape": "cone", "height": 3.7486713335143, "style": "light", "division_offsets": [0.25, 0.25, 0.25, 0.25]}
--- a/src/utility/test456/test456.png
+++ b/src/utility/test456/test456.png
--- a/src/utility/test456/test456_hall.png
+++ b/src/utility/test456/test456_hall.png
--- a/src/utility/test456/test456_kitchen.png
+++ b/src/utility/test456/test456_kitchen.png
--- a/src/utility/test456/test456_landing.png
+++ b/src/utility/test456/test456_landing.png
--- a/src/utility/test789/test789.blend
+++ b/src/utility/test789/test789.blend
--- a/src/utility/test789/test789.blend1
+++ b/src/utility/test789/test789.blend1
--- a/src/utility/test789/test789.json
+++ b/src/utility/test789/test789.json
@ -1 +0,0 @@
 {"division_param2": 1.0, "radius": 1.8509219558134604, "stem_length": 0.5, "division_param1": 1.0, "division_pattern": "hyperbolic_tan", "output": "test789", "shape": "bio", "style": "dark", "height": 1.3296018884322776, "fixture_radius": 0.3, "fixture_length": 0.3}
--- a/src/utility/test789/test789.png
+++ b/src/utility/test789/test789.png
--- a/src/utility/test789/test789.png0001.png
+++ b/src/utility/test789/test789.png0001.png
--- a/src/utility/test789/test789.png0002.png
+++ b/src/utility/test789/test789.png0002.png
--- a/src/utility/test789/test789.png0003.png
+++ b/src/utility/test789/test789.png0003.png
--- a/src/utility/test789/test789.png0004.png
+++ b/src/utility/test789/test789.png0004.png
--- a/src/utility/test789/test789.png0005.png
+++ b/src/utility/test789/test789.png0005.png
--- a/src/utility/test91011/test91011.blend
+++ b/src/utility/test91011/test91011.blend
--- a/src/utility/test91011/test91011.blend1
+++ b/src/utility/test91011/test91011.blend1
--- a/src/utility/test91011/test91011.json
+++ b/src/utility/test91011/test91011.json
@ -1 +0,0 @@
 {"stem_length": 0.5, "division_param1": 1.0, "fixture_length": 0.3, "output": "test91011", "height": 2.3703425509577607, "division_pattern": "sinusoid", "division_param2": 1.0, "style": "light", "shape": "cone", "radius": 1.1040660329988414, "fixture_radius": 0.3}
--- a/src/utility/test91011/test91011.png
+++ b/src/utility/test91011/test91011.png
--- a/test/lamp_shape_generation.py
+++ b/test/lamp_shape_generation.py
@ -1,42 +0,0 @@
 import numpy as np
 import matplotlib.pyplot as plt
 height = 3
 radius = 2
 base_radius = 0.5
 base_length = 0.3
 def morph_shape(x, L, H, morph_type="linear"):
    y = np.ones(x.shape[0])
    if morph_type == "linear":
        y = (x/L)*H
    elif morph_type == "logistic":
        k = 10.0
        v = 1.0
        y = H/(1.0 + np.power(np.exp(-k*(x-L/4.0)), v))
    elif morph_type == "sinusoid":
        y = np.sin((x/L)*np.pi/2.0)
    elif morph_type == "hyperbolic_tan":
        y = np.tanh((x/L)*np.pi/2.0)
    elif morph_type == "circle":
        y = np.sqrt(L*L-np.power((L-x),2))         
    return y
 x_base = np.linspace(0, base_length, 10)
 y_base = base_radius*np.ones(x_base.shape[0])
 x_lamp = np.linspace(base_length, height, 100)
 y_lamp = base_radius + morph_shape(x_lamp-base_length,
                                   height-base_length,
                                   radius-base_radius,
                                   "circle")
 x = np.append(x_base, x_lamp)
 y = np.append(y_base, y_lamp)
 plt.plot(x, y)
 axes = plt.gca()
 axes.set_xlim([0, 1.1*base_length+height])
 axes.set_ylim([0,1.1*radius])
 plt.axis('equal')
 plt.show()
--- a/test/test/test.blend
+++ b/test/test/test.blend
--- a/test/test/test.blend1
+++ b/test/test/test.blend1
--- a/test/test/test.json
+++ b/test/test/test.json
@ -1 +1 @@
-{"shape": "pendant", "style": "billard", "division_offsets": [0.25, 0.25, 0.25, 0.25], "division_patterns": ["sine", "inv_square", "sine", "sine"], "fixture_radius": 0.3, "radius": 1.108292895591573, "height": 2.3656568205530943, "division_radii": [0.5013193491935374, 0.5714972928268524, 0.7183081060448532, 0.7995437239322076]}
+{"division_offsets": [0.25, 0.25, 0.25, 0.25], "radius": 0.5151794595751276, "height": 4.115548193330971, "division_patterns": ["inv_square", "inv_square", "square", "inv_sine"], "shape": "pendant", "style": "light", "division_radii": [0.9221841829622927, 0.9489520915432629, 0.9897309968469092, 0.994921834206689], "fixture_radius": 0.3}
--- a/test/test/test.png
+++ b/test/test/test.png
		`@ -1 +1 @@`
			`{"fixture_radius": 0.3, "output": "test456", "radius": 1.8287633826475211, "height": 3.910662786988026, "division_patterns": ["ramp", "sine", "sine", "inv_sine"], "division_radii": [0.4473225094039008, 0.5963619022128677, 0.7765883654637191, 0.889395569488088], "division_offsets": [0.25, 0.25, 0.25, 0.25], "style": "billard", "shape": "bio"}`				`{"fixture_radius": 0.3, "division_radii": [0.7366486532785445, 0.8362702452541098, 0.9661599163089211, 0.9867733391465805], "radius": 0.611924774203075, "division_patterns": ["inv_square", "inv_ramp", "sine", "inv_square"], "shape": "cone", "height": 3.7486713335143, "style": "light", "division_offsets": [0.25, 0.25, 0.25, 0.25]}`
		`@ -1 +0,0 @@`
			`{"division_param2": 1.0, "radius": 1.8509219558134604, "stem_length": 0.5, "division_param1": 1.0, "division_pattern": "hyperbolic_tan", "output": "test789", "shape": "bio", "style": "dark", "height": 1.3296018884322776, "fixture_radius": 0.3, "fixture_length": 0.3}`
		`@ -1 +0,0 @@`
			`{"stem_length": 0.5, "division_param1": 1.0, "fixture_length": 0.3, "output": "test91011", "height": 2.3703425509577607, "division_pattern": "sinusoid", "division_param2": 1.0, "style": "light", "shape": "cone", "radius": 1.1040660329988414, "fixture_radius": 0.3}`
		`@ -1 +1 @@`
			`{"shape": "pendant", "style": "billard", "division_offsets": [0.25, 0.25, 0.25, 0.25], "division_patterns": ["sine", "inv_square", "sine", "sine"], "fixture_radius": 0.3, "radius": 1.108292895591573, "height": 2.3656568205530943, "division_radii": [0.5013193491935374, 0.5714972928268524, 0.7183081060448532, 0.7995437239322076]}`				`{"division_offsets": [0.25, 0.25, 0.25, 0.25], "radius": 0.5151794595751276, "height": 4.115548193330971, "division_patterns": ["inv_square", "inv_square", "square", "inv_sine"], "shape": "pendant", "style": "light", "division_radii": [0.9221841829622927, 0.9489520915432629, 0.9897309968469092, 0.994921834206689], "fixture_radius": 0.3}`