X-Git-Url: https://git.ao2.it/vrm.git/blobdiff_plain/fbf9bf8ccfcd931b3e99429b2b0f392ada855a9c..7179af4e908b58499abdbb193c6e1eb1b5918532:/vrm.py?ds=inline diff --git a/vrm.py b/vrm.py index 26a14d7..72ed002 100755 --- a/vrm.py +++ b/vrm.py @@ -1,13 +1,13 @@ #!BPY """ Name: 'VRM' -Blender: 242 +Blender: 245 Group: 'Render' Tooltip: 'Vector Rendering Method script' """ __author__ = "Antonio Ospite" -__url__ = ["http://projects.blender.org/projects/vrm"] +__url__ = ["http://vrm.ao2.it"] __version__ = "0.3.beta" __bpydoc__ = """\ @@ -15,7 +15,7 @@ __bpydoc__ = """\ """ # --------------------------------------------------------------------- -# Copyright (c) 2006 Antonio Ospite +# Copyright (c) 2006, 2007, 2008, 2009 Antonio Ospite # # This program is free software; you can redistribute it and/or modify # it under the terms of the GNU General Public License as published by @@ -40,15 +40,14 @@ __bpydoc__ = """\ # from scratch but Nikola gave me the idea, so I thank him publicly. # # --------------------------------------------------------------------- -# +# # Things TODO for a next release: +# - Shadeless shader # - FIX the issue with negative scales in object tranformations! # - Use a better depth sorting algorithm -# - Implement clipping of primitives and do handle object intersections. -# (for now only clipping away whole objects is supported). # - Review how selections are made (this script uses selection states of # primitives to represent visibility infos) -# - Use a data structure other than Mesh to represent the 2D image? +# - Use a data structure other than Mesh to represent the 2D image? # Think to a way to merge (adjacent) polygons that have the same color. # Or a way to use paths for silhouettes and contours. # - Consider SMIL for animation handling instead of ECMA Script? (Firefox do @@ -58,27 +57,8 @@ __bpydoc__ = """\ # - Implement Edge Styles (silhouettes, contours, etc.) (partially done). # - Implement Shading Styles? (partially done, to make more flexible). # - Add Vector Writers other than SVG. +# - set the background color! # - Check memory use!! -# - Support Indexed palettes!! (Useful for ILDA FILES, for example, -# see http://www.linux-laser.org/download/autotrace/ilda-output.patch) -# -# --------------------------------------------------------------------- -# -# Changelog: -# -# vrm-0.3.py - ... -# * First release after code restucturing. -# Now the script offers a useful set of functionalities -# and it can render animations, too. -# * Optimization in Renderer.doEdgeStyle(), build a topology cache -# so to speed up the lookup of adjacent faces of an edge. -# Thanks ideasman42. -# * The SVG output is now SVG 1.0 valid. -# Checked with: http://jiggles.w3.org/svgvalidator/ValidatorURI.html -# * Progress indicator during HSR. -# * Initial SWF output support -# * Fixed a bug in the animation code, now the projection matrix is -# recalculated at each frame! # # --------------------------------------------------------------------- @@ -88,6 +68,19 @@ from Blender.Mathutils import * from math import * import sys, time +try: + set() +except NameError: + from sets import Set as set + + +def uniq(alist): + tmpdict = dict() + return [tmpdict.setdefault(e,e) for e in alist if e not in tmpdict] + # in python > 2.4 we ca use the following + #return [ u for u in alist if u not in locals()['_[1]'] ] + + # Constants EPS = 10e-5 @@ -95,14 +88,13 @@ EPS = 10e-5 progress = None -# Some global settings +# Config class for global settings class config: polygons = dict() polygons['SHOW'] = True - polygons['SHADING'] = 'FLAT' - #polygons['HSR'] = 'PAINTER' # 'PAINTER' or 'NEWELL' - polygons['HSR'] = 'PAINTER' + polygons['SHADING'] = 'FLAT' # FLAT or TOON + polygons['HSR'] = 'PAINTER' # PAINTER or NEWELL # Hidden to the user for now polygons['EXPANSION_TRICK'] = True @@ -111,25 +103,91 @@ class config: edges = dict() edges['SHOW'] = False edges['SHOW_HIDDEN'] = False - edges['STYLE'] = 'MESH' # or SILHOUETTE - edges['STYLE'] = 'SILHOUETTE' + edges['STYLE'] = 'MESH' # MESH or SILHOUETTE edges['WIDTH'] = 2 edges['COLOR'] = [0, 0, 0] output = dict() output['FORMAT'] = 'SVG' - output['FORMAT'] = 'SWF' - output['ANIMATION'] = True + output['ANIMATION'] = False output['JOIN_OBJECTS'] = True + def saveToRegistry(): + registry = {} + + for k,v in config.__dict__.iteritems(): + + # config class store settings in dictionaries + if v.__class__ == dict().__class__: + + regkey_prefix = k.upper()+"_" + + for opt_k,opt_v in v.iteritems(): + regkey = regkey_prefix + opt_k + + registry[regkey] = opt_v + + Blender.Registry.SetKey('VRM', registry, True) + + saveToRegistry = staticmethod(saveToRegistry) + + def loadFromRegistry(): + registry = Blender.Registry.GetKey('VRM', True) + if not registry: + return + + for k,v in registry.iteritems(): + k_tmp = k.split('_') + conf_attr = k_tmp[0].lower() + conf_key = str.join("_",k_tmp[1:]) + conf_val = v + + if config.__dict__.has_key(conf_attr): + config.__dict__[conf_attr][conf_key] = conf_val + + loadFromRegistry = staticmethod(loadFromRegistry) # Utility functions +print_debug = False + +def dumpfaces(flist, filename): + """Dump a single face to a file. + """ + if not print_debug: + return + + class tmpmesh: + pass + + m = tmpmesh() + m.faces = flist + + writerobj = SVGVectorWriter(filename) + + writerobj.open() + writerobj._printPolygons(m) + + writerobj.close() + +def debug(msg): + if print_debug: + sys.stderr.write(msg) + +def EQ(v1, v2): + return (abs(v1[0]-v2[0]) < EPS and + abs(v1[1]-v2[1]) < EPS ) +by_furthest_z = (lambda f1, f2: + cmp(max([v.co[2] for v in f1]), max([v.co[2] for v in f2])+EPS) + ) + def sign(x): if x < -EPS: + #if x < 0: return -1 elif x > EPS: + #elif x > 0: return 1 else: return 0 @@ -137,13 +195,579 @@ def sign(x): # --------------------------------------------------------------------- # +## HSR Utility class +# +# --------------------------------------------------------------------- + +EPS = 10e-5 +INF = 10e5 + +class HSR: + """A utility class for HSR processing. + """ + + def is_nonplanar_quad(face): + """Determine if a quad is non-planar. + + From: http://mathworld.wolfram.com/Coplanar.html + + Geometric objects lying in a common plane are said to be coplanar. + Three noncollinear points determine a plane and so are trivially coplanar. + Four points are coplanar iff the volume of the tetrahedron defined by them is + 0, + + | x_1 y_1 z_1 1 | + | x_2 y_2 z_2 1 | + | x_3 y_3 z_3 1 | + | x_4 y_4 z_4 1 | == 0 + + Coplanarity is equivalent to the statement that the pair of lines + determined by the four points are not skew, and can be equivalently stated + in vector form as (x_3-x_1).[(x_2-x_1)x(x_4-x_3)]==0. + + An arbitrary number of n points x_1, ..., x_n can be tested for + coplanarity by finding the point-plane distances of the points + x_4, ..., x_n from the plane determined by (x_1,x_2,x_3) + and checking if they are all zero. + If so, the points are all coplanar. + + We here check only for 4-point complanarity. + """ + n = len(face) + + # assert(n>4) + if n < 3 or n > 4: + print "ERROR a mesh in Blender can't have more than 4 vertices or less than 3" + raise AssertionError + + elif n == 3: + # three points must be complanar + return False + else: # n == 4 + x1 = Vector(face[0].co) + x2 = Vector(face[1].co) + x3 = Vector(face[2].co) + x4 = Vector(face[3].co) + + v = (x3-x1) * CrossVecs((x2-x1), (x4-x3)) + if v != 0: + return True + + return False + + is_nonplanar_quad = staticmethod(is_nonplanar_quad) + + def pointInPolygon(poly, v): + return False + + pointInPolygon = staticmethod(pointInPolygon) + + def edgeIntersection(s1, s2, do_perturbate=False): + + (x1, y1) = s1[0].co[0], s1[0].co[1] + (x2, y2) = s1[1].co[0], s1[1].co[1] + + (x3, y3) = s2[0].co[0], s2[0].co[1] + (x4, y4) = s2[1].co[0], s2[1].co[1] + + #z1 = s1[0].co[2] + #z2 = s1[1].co[2] + #z3 = s2[0].co[2] + #z4 = s2[1].co[2] + + + # calculate delta values (vector components) + dx1 = x2 - x1; + dx2 = x4 - x3; + dy1 = y2 - y1; + dy2 = y4 - y3; + + #dz1 = z2 - z1; + #dz2 = z4 - z3; + + C = dy2 * dx1 - dx2 * dy1 # /* cross product */ + if C == 0: #/* parallel */ + return None + + dx3 = x1 - x3 # /* combined origin offset vector */ + dy3 = y1 - y3 + + a1 = (dy3 * dx2 - dx3 * dy2) / C; + a2 = (dy3 * dx1 - dx3 * dy1) / C; + + # check for degeneracies + #print_debug("\n") + #print_debug(str(a1)+"\n") + #print_debug(str(a2)+"\n\n") + + if (a1 == 0 or a1 == 1 or a2 == 0 or a2 == 1): + # Intersection on boundaries, we consider the point external? + return None + + elif (a1>0.0 and a1<1.0 and a2>0.0 and a2<1.0): # /* lines cross */ + x = x1 + a1*dx1 + y = y1 + a1*dy1 + + #z = z1 + a1*dz1 + z = 0 + return (NMesh.Vert(x, y, z), a1, a2) + + else: + # lines have intersections but not those segments + return None + + edgeIntersection = staticmethod(edgeIntersection) + + def isVertInside(self, v): + winding_number = 0 + coincidence = False + + # Create point at infinity + point_at_infinity = NMesh.Vert(-INF, v.co[1], -INF) + + for i in range(len(self.v)): + s1 = (point_at_infinity, v) + s2 = (self.v[i-1], self.v[i]) + + if EQ(v.co, s2[0].co) or EQ(v.co, s2[1].co): + coincidence = True + + if HSR.edgeIntersection(s1, s2, do_perturbate=False): + winding_number += 1 + + # Check even or odd + if winding_number % 2 == 0 : + return False + else: + if coincidence: + return False + return True + + isVertInside = staticmethod(isVertInside) + + + def det(a, b, c): + return ((b[0] - a[0]) * (c[1] - a[1]) - + (b[1] - a[1]) * (c[0] - a[0]) ) + + det = staticmethod(det) + + def pointInPolygon(q, P): + is_in = False + + point_at_infinity = NMesh.Vert(-INF, q.co[1], -INF) + + det = HSR.det + + for i in range(len(P.v)): + p0 = P.v[i-1] + p1 = P.v[i] + if (det(q.co, point_at_infinity.co, p0.co)<0) != (det(q.co, point_at_infinity.co, p1.co)<0): + if det(p0.co, p1.co, q.co) == 0 : + #print "On Boundary" + return False + elif (det(p0.co, p1.co, q.co)<0) != (det(p0.co, p1.co, point_at_infinity.co)<0): + is_in = not is_in + + return is_in + + pointInPolygon = staticmethod(pointInPolygon) + + def projectionsOverlap(f1, f2): + """ If you have nonconvex, but still simple polygons, an acceptable method + is to iterate over all vertices and perform the Point-in-polygon test[1]. + The advantage of this method is that you can compute the exact + intersection point and collision normal that you will need to simulate + collision. When you have the point that lies inside the other polygon, you + just iterate over all edges of the second polygon again and look for edge + intersections. Note that this method detects collsion when it already + happens. This algorithm is fast enough to perform it hundreds of times per + sec. """ + + for i in range(len(f1.v)): + + + # If a point of f1 in inside f2, there is an overlap! + v1 = f1.v[i] + #if HSR.isVertInside(f2, v1): + if HSR.pointInPolygon(v1, f2): + return True + + # If not the polygon can be ovelap as well, so we check for + # intersection between an edge of f1 and all the edges of f2 + + v0 = f1.v[i-1] + + for j in range(len(f2.v)): + v2 = f2.v[j-1] + v3 = f2.v[j] + + e1 = v0, v1 + e2 = v2, v3 + + intrs = HSR.edgeIntersection(e1, e2) + if intrs: + #print_debug(str(v0.co) + " " + str(v1.co) + " " + + # str(v2.co) + " " + str(v3.co) ) + #print_debug("\nIntersection\n") + + return True + + return False + + projectionsOverlap = staticmethod(projectionsOverlap) + + def midpoint(p1, p2): + """Return the midpoint of two vertices. + """ + m = MidpointVecs(Vector(p1), Vector(p2)) + mv = NMesh.Vert(m[0], m[1], m[2]) + + return mv + + midpoint = staticmethod(midpoint) + + def facesplit(P, Q, facelist, nmesh): + """Split P or Q according to the strategy illustrated in the Newell's + paper. + """ + + by_furthest_z = (lambda f1, f2: + cmp(max([v.co[2] for v in f1]), max([v.co[2] for v in f2])+EPS) + ) + + # Choose if split P on Q plane or vice-versa + + n = 0 + for Pi in P: + d = HSR.Distance(Vector(Pi), Q) + if d <= EPS: + n += 1 + pIntersectQ = (n != len(P)) + + n = 0 + for Qi in Q: + d = HSR.Distance(Vector(Qi), P) + if d >= -EPS: + n += 1 + qIntersectP = (n != len(Q)) + + newfaces = [] + + # 1. If parts of P lie in both half-spaces of Q + # then splice P in two with the plane of Q + if pIntersectQ: + #print "We split P" + f = P + plane = Q + + newfaces = HSR.splitOn(plane, f) + + # 2. Else if parts of Q lie in both half-space of P + # then splice Q in two with the plane of P + if qIntersectP and newfaces == None: + #print "We split Q" + f = Q + plane = P + + newfaces = HSR.splitOn(plane, f) + #print "After" + + # 3. Else slice P in half through the mid-point of + # the longest pair of opposite sides + if newfaces == None: + + print "We ignore P..." + facelist.remove(P) + return facelist + + #f = P + + #if len(P)==3: + # v1 = midpoint(f[0], f[1]) + # v2 = midpoint(f[1], f[2]) + #if len(P)==4: + # v1 = midpoint(f[0], f[1]) + # v2 = midpoint(f[2], f[3]) + #vec3 = (Vector(v2)+10*Vector(f.normal)) + # + #v3 = NMesh.Vert(vec3[0], vec3[1], vec3[2]) + + #plane = NMesh.Face([v1, v2, v3]) + # + #newfaces = splitOn(plane, f) + + + if newfaces == None: + print "Big FAT problem, we weren't able to split POLYGONS!" + raise AssertionError + + #print newfaces + if newfaces: + #for v in f: + # if v not in plane and v in nmesh.verts: + # nmesh.verts.remove(v) + for nf in newfaces: + + nf.mat = f.mat + nf.sel = f.sel + nf.col = [f.col[0]] * len(nf.v) + + nf.smooth = 0 + + for v in nf: + nmesh.verts.append(v) + # insert pieces in the list + facelist.append(nf) + + facelist.remove(f) + + # and resort the faces + facelist.sort(by_furthest_z) + facelist.sort(lambda f1, f2: cmp(f1.smooth, f2.smooth)) + facelist.reverse() + + #print [ f.smooth for f in facelist ] + + return facelist + + facesplit = staticmethod(facesplit) + + def isOnSegment(v1, v2, p, extremes_internal=False): + """Check if point p is in segment v1v2. + """ + + l1 = (v1-p).length + l2 = (v2-p).length + + # Should we consider extreme points as internal ? + # The test: + # if p == v1 or p == v2: + if l1 < EPS or l2 < EPS: + return extremes_internal + + l = (v1-v2).length + + # if the sum of l1 and l2 is circa l, then the point is on segment, + if abs(l - (l1+l2)) < EPS: + return True + else: + return False + + isOnSegment = staticmethod(isOnSegment) + + def Distance(point, face): + """ Calculate the distance between a point and a face. + + An alternative but more expensive method can be: + + ip = Intersect(Vector(face[0]), Vector(face[1]), Vector(face[2]), + Vector(face.no), Vector(point), 0) + + d = Vector(ip - point).length + + See: http://mathworld.wolfram.com/Point-PlaneDistance.html + """ + + p = Vector(point) + plNormal = Vector(face.no) + plVert0 = Vector(face.v[0]) + + d = (plVert0 * plNormal) - (p * plNormal) + + #d = plNormal * (plVert0 - p) + + #print "\nd: %.10f - sel: %d, %s\n" % (d, face.sel, str(point)) + + return d + + Distance = staticmethod(Distance) + + def makeFaces(vl): + # + # make one or two new faces based on a list of vertex-indices + # + newfaces = [] + + if len(vl) <= 4: + nf = NMesh.Face() + + for v in vl: + nf.v.append(v) + + newfaces.append(nf) + + else: + nf = NMesh.Face() + + nf.v.append(vl[0]) + nf.v.append(vl[1]) + nf.v.append(vl[2]) + nf.v.append(vl[3]) + newfaces.append(nf) + + nf = NMesh.Face() + nf.v.append(vl[3]) + nf.v.append(vl[4]) + nf.v.append(vl[0]) + newfaces.append(nf) + + return newfaces + + makeFaces = staticmethod(makeFaces) + + def splitOn(Q, P, return_positive_faces=True, return_negative_faces=True): + """Split P using the plane of Q. + Logic taken from the knife.py python script + """ + + # Check if P and Q are parallel + u = CrossVecs(Vector(Q.no),Vector(P.no)) + ax = abs(u[0]) + ay = abs(u[1]) + az = abs(u[2]) + + if (ax+ay+az) < EPS: + print "PARALLEL planes!!" + return + + + # The final aim is to find the intersection line between P + # and the plane of Q, and split P along this line + + nP = len(P.v) + + # Calculate point-plane Distance between vertices of P and plane Q + d = [] + for i in range(0, nP): + d.append(HSR.Distance(P.v[i], Q)) + + newVertList = [] + + posVertList = [] + negVertList = [] + for i in range(nP): + d0 = d[i-1] + V0 = P.v[i-1] + + d1 = d[i] + V1 = P.v[i] + + #print "d0:", d0, "d1:", d1 + + # if the vertex lies in the cutplane + if abs(d1) < EPS: + #print "d1 On cutplane" + posVertList.append(V1) + negVertList.append(V1) + else: + # if the previous vertex lies in cutplane + if abs(d0) < EPS: + #print "d0 on Cutplane" + if d1 > 0: + #print "d1 on positive Halfspace" + posVertList.append(V1) + else: + #print "d1 on negative Halfspace" + negVertList.append(V1) + else: + # if they are on the same side of the plane + if d1*d0 > 0: + #print "On the same half-space" + if d1 > 0: + #print "d1 on positive Halfspace" + posVertList.append(V1) + else: + #print "d1 on negative Halfspace" + negVertList.append(V1) + + # the vertices are not on the same side of the plane, so we have an intersection + else: + #print "Intersection" + + e = Vector(V0), Vector(V1) + tri = Vector(Q[0]), Vector(Q[1]), Vector(Q[2]) + + inters = Intersect(tri[0], tri[1], tri[2], e[1]-e[0], e[0], 0) + if inters == None: + print "Split Break" + break + + #print "Intersection", inters + + nv = NMesh.Vert(inters[0], inters[1], inters[2]) + newVertList.append(nv) + + posVertList.append(nv) + negVertList.append(nv) + + if d1 > 0: + posVertList.append(V1) + else: + negVertList.append(V1) + + + # uniq for python > 2.4 + #posVertList = [ u for u in posVertList if u not in locals()['_[1]'] ] + #negVertList = [ u for u in negVertList if u not in locals()['_[1]'] ] + + # a more portable way + posVertList = uniq(posVertList) + negVertList = uniq(negVertList) + + + # If vertex are all on the same half-space, return + #if len(posVertList) < 3: + # print "Problem, we created a face with less that 3 vertices??" + # posVertList = [] + #if len(negVertList) < 3: + # print "Problem, we created a face with less that 3 vertices??" + # negVertList = [] + + if len(posVertList) < 3 or len(negVertList) < 3: + #print "RETURN NONE, SURE???" + return None + + if not return_positive_faces: + posVertList = [] + if not return_negative_faces: + negVertList = [] + + newfaces = HSR.addNewFaces(posVertList, negVertList) + + return newfaces + + splitOn = staticmethod(splitOn) + + def addNewFaces(posVertList, negVertList): + # Create new faces resulting from the split + outfaces = [] + if len(posVertList) or len(negVertList): + + #newfaces = [posVertList] + [negVertList] + newfaces = ( [[ NMesh.Vert(v[0], v[1], v[2]) for v in posVertList]] + + [[ NMesh.Vert(v[0], v[1], v[2]) for v in negVertList]] ) + + for nf in newfaces: + if nf and len(nf)>2: + outfaces += HSR.makeFaces(nf) + + return outfaces + + + addNewFaces = staticmethod(addNewFaces) + + +# --------------------------------------------------------------------- +# ## Mesh Utility class # # --------------------------------------------------------------------- + class MeshUtils: def buildEdgeFaceUsersCache(me): - ''' + ''' Takes a mesh and returns a list aligned with the meshes edges. Each item is a list of the faces that use the edge would be the equiv for having ed.face_users as a property @@ -159,23 +783,23 @@ class MeshUtils: i1,i2= i2,i1 return i1, i2 - + face_edges_dict= dict([(sorted_edge_indicies(ed), (ed.index, [])) for ed in me.edges]) for f in me.faces: fvi= [v.index for v in f.v]# face vert idx's for i in xrange(len(f)): i1= fvi[i] i2= fvi[i-1] - + if i1>i2: i1,i2= i2,i1 - + face_edges_dict[i1,i2][1].append(f) - + face_edges= [None] * len(me.edges) for ed_index, ed_faces in face_edges_dict.itervalues(): face_edges[ed_index]= ed_faces - + return face_edges def isMeshEdge(adjacent_faces): @@ -222,6 +846,7 @@ class MeshUtils: ## Shading Utility class # # --------------------------------------------------------------------- + class ShadingUtils: shademap = None @@ -265,10 +890,10 @@ class ShadingUtils: class Projector: """Calculate the projection of an object given the camera. - + A projector is useful to so some per-object transformation to obtain the projection of an object given the camera. - + The main method is #doProjection# see the method description for the parameter list. """ @@ -290,17 +915,26 @@ class Projector: fovy = atan(0.5/aspect/(camera.lens/32)) fovy = fovy * 360.0/pi - + + + if Blender.Get('version') < 243: + camPersp = 0 + camOrtho = 1 + else: + camPersp = 'persp' + camOrtho = 'ortho' + # What projection do we want? - if camera.type == 0: - mP = self._calcPerspectiveMatrix(fovy, aspect, near, far) - elif camera.type == 1: - mP = self._calcOrthoMatrix(fovy, aspect, near, far, scale) - + if camera.type == camPersp: + mP = self._calcPerspectiveMatrix(fovy, aspect, near, far) + elif camera.type == camOrtho: + mP = self._calcOrthoMatrix(fovy, aspect, near, far, scale) + + # View transformation cam = Matrix(cameraObj.getInverseMatrix()) - cam.transpose() - + cam.transpose() + mP = mP * cam self.projectionMatrix = mP @@ -315,13 +949,13 @@ class Projector: Given a vertex calculate the projection using the current projection matrix. """ - + # Note that we have to work on the vertex using homogeneous coordinates # From blender 2.42+ we don't need to resize the vector to be 4d # when applying a 4x4 matrix, but we do that anyway since we need the # 4th coordinate later p = self.projectionMatrix * Vector(v).resize4D() - + # Perspective division if p[3] != 0: p[0] = p[0]/p[3] @@ -338,11 +972,11 @@ class Projector: ## # Private methods # - + def _calcPerspectiveMatrix(self, fovy, aspect, near, far): """Return a perspective projection matrix. """ - + top = near * tan(fovy * pi / 360.0) bottom = -top left = bottom*aspect @@ -353,7 +987,7 @@ class Projector: b = (top+bottom) / (top - bottom) c = - ((far+near) / (far-near)) d = - ((2*far*near)/(far-near)) - + m = Matrix( [x, 0.0, a, 0.0], [0.0, y, b, 0.0], @@ -365,15 +999,15 @@ class Projector: def _calcOrthoMatrix(self, fovy, aspect , near, far, scale): """Return an orthogonal projection matrix. """ - + # The 11 in the formula was found emiprically top = near * tan(fovy * pi / 360.0) * (scale * 11) - bottom = -top + bottom = -top left = bottom * aspect right= top * aspect rl = right-left tb = top-bottom - fn = near-far + fn = near-far tx = -((right+left)/rl) ty = -((top+bottom)/tb) tz = ((far+near)/fn) @@ -383,7 +1017,7 @@ class Projector: [0.0, 2.0/tb, 0.0, ty], [0.0, 0.0, 2.0/fn, tz], [0.0, 0.0, 0.0, 1.0]) - + return m @@ -395,7 +1029,7 @@ class Projector: class Progress: """A model for a progress indicator. - + Do the progress calculation calculation and the view independent stuff of a progress indicator. """ @@ -507,7 +1141,7 @@ class ConsoleProgressIndicator(ProgressIndicator): def show(self, progress, name): ProgressIndicator.show(self, progress, name) - + bar_length = 70 bar_progress = int( (progress/100.0) * bar_length ) bar = ("=" * bar_progress).ljust(bar_length) @@ -585,16 +1219,23 @@ class VectorWriter: - printCanvas(self, scene, doPrintPolygons=True, doPrintEdges=False, showHiddenEdges=False): """ - + def __init__(self, fileName): """Set the output file name and other properties""" + try: + config.writer + except: + config.writer = dict() + config.writer['SETTING'] = True + self.outputFileName = fileName - self.file = None - + context = Scene.GetCurrent().getRenderingContext() self.canvasSize = ( context.imageSizeX(), context.imageSizeY() ) + self.fps = context.fps + self.startFrame = 1 self.endFrame = 1 self.animation = False @@ -603,21 +1244,18 @@ class VectorWriter: ## # Public Methods # - + def open(self, startFrame=1, endFrame=1): if startFrame != endFrame: self.startFrame = startFrame self.endFrame = endFrame self.animation = True - self.file = open(self.outputFileName, "w") print "Outputting to: ", self.outputFileName return def close(self): - if self.file: - self.file.close() return def printCanvas(self, scene, doPrintPolygons=True, doPrintEdges=False, @@ -625,7 +1263,7 @@ class VectorWriter: """This is the interface for the needed printing routine. """ return - + ## SVG Writer @@ -638,6 +1276,8 @@ class SVGVectorWriter(VectorWriter): """ VectorWriter.__init__(self, fileName) + self.file = None + ## # Public Methods @@ -647,6 +1287,9 @@ class SVGVectorWriter(VectorWriter): """Do some initialization operations. """ VectorWriter.open(self, startFrame, endFrame) + + self.file = open(self.outputFileName, "w") + self._printHeader() def close(self): @@ -654,16 +1297,19 @@ class SVGVectorWriter(VectorWriter): """ self._printFooter() - # remember to call the close method of the parent + if self.file: + self.file.close() + + # remember to call the close method of the parent as last VectorWriter.close(self) - + def printCanvas(self, scene, doPrintPolygons=True, doPrintEdges=False, showHiddenEdges=False): """Convert the scene representation to SVG. """ - Objects = scene.getChildren() + Objects = scene.objects context = scene.getRenderingContext() framenumber = context.currentFrame() @@ -672,7 +1318,7 @@ class SVGVectorWriter(VectorWriter): framestyle = "display:none" else: framestyle = "display:block" - + # Assign an id to this group so we can set properties on it using DOM self.file.write("\n" % (framenumber, framestyle) ) @@ -692,22 +1338,22 @@ class SVGVectorWriter(VectorWriter): if doPrintEdges: self._printEdges(mesh, showHiddenEdges) - + self.file.write("\n") self.file.write("\n") - - ## + + ## # Private Methods # - + def _calcCanvasCoord(self, v): """Convert vertex in scene coordinates to canvas coordinates. """ pt = Vector([0, 0, 0]) - + mW = float(self.canvasSize[0])/2.0 mH = float(self.canvasSize[1])/2.0 @@ -715,12 +1361,12 @@ class SVGVectorWriter(VectorWriter): pt[0] = v.co[0]*mW + mW pt[1] = v.co[1]*mH + mH pt[2] = v.co[2] - + # For now we want (0,0) in the top-left corner of the canvas. # Mirror and translate along y pt[1] *= -1 pt[1] += self.canvasSize[1] - + return pt def _printHeader(self): @@ -735,15 +1381,17 @@ class SVGVectorWriter(VectorWriter): self.canvasSize) if self.animation: + delay = 1000/self.fps self.file.write("""\n\n - \n""" % (self.startFrame, self.endFrame, self.startFrame) ) - + \n""") + def _printFooter(self): """Print the SVG footer.""" self.file.write("\n\n") - def _printPolygons(self, mesh): + def _printPolygons(self, mesh): """Print the selected (visible) polygons. """ @@ -791,92 +1439,271 @@ class SVGVectorWriter(VectorWriter): self.file.write("\n") + + self.file.write("\n") + + def _printEdges(self, mesh, showHiddenEdges=False): + """Print the wireframe using mesh edges. + """ + + stroke_width = config.edges['WIDTH'] + stroke_col = config.edges['COLOR'] + + self.file.write("\n") + + for e in mesh.edges: + + hidden_stroke_style = "" + + if e.sel == 0: + if showHiddenEdges == False: + continue + else: + hidden_stroke_style = ";\n stroke-dasharray:3, 3" + + p1 = self._calcCanvasCoord(e.v1) + p2 = self._calcCanvasCoord(e.v2) + + self.file.write("\n") + + self.file.write("\n") + + +## SWF Writer + +try: + from ming import * + SWFSupported = True +except: + SWFSupported = False + +class SWFVectorWriter(VectorWriter): + """A concrete class for writing SWF output. + """ + + def __init__(self, fileName): + """Simply call the parent Contructor. + """ + VectorWriter.__init__(self, fileName) + + self.movie = None + self.sprite = None + + + ## + # Public Methods + # + + def open(self, startFrame=1, endFrame=1): + """Do some initialization operations. + """ + VectorWriter.open(self, startFrame, endFrame) + self.movie = SWFMovie() + self.movie.setDimension(self.canvasSize[0], self.canvasSize[1]) + if self.animation: + self.movie.setRate(self.fps) + numframes = endFrame - startFrame + 1 + self.movie.setFrames(numframes) + + def close(self): + """Do some finalization operation. + """ + self.movie.save(self.outputFileName) + + # remember to call the close method of the parent + VectorWriter.close(self) + + def printCanvas(self, scene, doPrintPolygons=True, doPrintEdges=False, + showHiddenEdges=False): + """Convert the scene representation to SVG. + """ + context = scene.getRenderingContext() + framenumber = context.currentFrame() + + Objects = scene.objects + + if self.sprite: + self.movie.remove(self.sprite) + + sprite = SWFSprite() + + for obj in Objects: + + if(obj.getType() != 'Mesh'): + continue + + mesh = obj.getData(mesh=1) + + if doPrintPolygons: + self._printPolygons(mesh, sprite) + + if doPrintEdges: + self._printEdges(mesh, sprite, showHiddenEdges) + + sprite.nextFrame() + i = self.movie.add(sprite) + # Remove the instance the next time + self.sprite = i + if self.animation: + self.movie.nextFrame() + + + ## + # Private Methods + # + + def _calcCanvasCoord(self, v): + """Convert vertex in scene coordinates to canvas coordinates. + """ + + pt = Vector([0, 0, 0]) + + mW = float(self.canvasSize[0])/2.0 + mH = float(self.canvasSize[1])/2.0 + + # rescale to canvas size + pt[0] = v.co[0]*mW + mW + pt[1] = v.co[1]*mH + mH + pt[2] = v.co[2] + + # For now we want (0,0) in the top-left corner of the canvas. + # Mirror and translate along y + pt[1] *= -1 + pt[1] += self.canvasSize[1] + + return pt + + def _printPolygons(self, mesh, sprite): + """Print the selected (visible) polygons. + """ + + if len(mesh.faces) == 0: + return + + for face in mesh.faces: + if not face.sel: + continue + if face.col: fcol = face.col[0] color = [fcol.r, fcol.g, fcol.b, fcol.a] else: color = [255, 255, 255, 255] - # Convert the color to the #RRGGBB form - str_col = "#%02X%02X%02X" % (color[0], color[1], color[2]) - - # Handle transparent polygons - opacity_string = "" - if color[3] != 255: - opacity = float(color[3])/255.0 - opacity_string = " fill-opacity: %g; stroke-opacity: %g; opacity: 1;" % (opacity, opacity) - #opacity_string = "opacity: %g;" % (opacity) + s = SWFShape() + f = s.addFill(color[0], color[1], color[2], color[3]) + s.setRightFill(f) - self.file.write("\tstyle=\"fill:" + str_col + ";") - self.file.write(opacity_string) + # The starting point of the shape + p0 = self._calcCanvasCoord(face.verts[0]) + s.movePenTo(p0[0], p0[1]) - # use the stroke property to alleviate the "adjacent edges" problem, - # we simulate polygon expansion using borders, - # see http://www.antigrain.com/svg/index.html for more info - stroke_width = 1.0 + for v in face.verts[1:]: + p = self._calcCanvasCoord(v) + s.drawLineTo(p[0], p[1]) - # EXPANSION TRICK is not that useful where there is transparency - if config.polygons['EXPANSION_TRICK'] and color[3] == 255: - # str_col = "#000000" # For debug - self.file.write(" stroke:%s;\n" % str_col) - self.file.write(" stroke-width:" + str(stroke_width) + ";\n") - self.file.write(" stroke-linecap:round;stroke-linejoin:round") + # Closing the shape + s.drawLineTo(p0[0], p0[1]) - self.file.write("\"/>\n") + s.end() + sprite.add(s) - self.file.write("\n") - def _printEdges(self, mesh, showHiddenEdges=False): + def _printEdges(self, mesh, sprite, showHiddenEdges=False): """Print the wireframe using mesh edges. """ stroke_width = config.edges['WIDTH'] stroke_col = config.edges['COLOR'] - - self.file.write("\n") + + s = SWFShape() for e in mesh.edges: - - hidden_stroke_style = "" - + + # Next, we set the line width and color for our shape. + s.setLine(stroke_width, stroke_col[0], stroke_col[1], stroke_col[2], + 255) + if e.sel == 0: if showHiddenEdges == False: continue else: - hidden_stroke_style = ";\n stroke-dasharray:3, 3" + # SWF does not support dashed lines natively, so -for now- + # draw hidden lines thinner and half-trasparent + s.setLine(stroke_width/2, stroke_col[0], stroke_col[1], + stroke_col[2], 128) p1 = self._calcCanvasCoord(e.v1) p2 = self._calcCanvasCoord(e.v2) - - self.file.write("\n") - self.file.write("\n") + s.movePenTo(p1[0], p1[1]) + s.drawLineTo(p2[0], p2[1]) + s.end() + sprite.add(s) -## SWF Writer -from ming import * +## PDF Writer -class SWFVectorWriter(VectorWriter): - """A concrete class for writing SWF output. +try: + from reportlab.pdfgen import canvas + PDFSupported = True +except: + PDFSupported = False + +class PDFVectorWriter(VectorWriter): + """A concrete class for writing PDF output. """ def __init__(self, fileName): @@ -884,8 +1711,7 @@ class SWFVectorWriter(VectorWriter): """ VectorWriter.__init__(self, fileName) - self.movie = None - self.sprite = None + self.canvas = None ## @@ -896,17 +1722,13 @@ class SWFVectorWriter(VectorWriter): """Do some initialization operations. """ VectorWriter.open(self, startFrame, endFrame) - self.movie = SWFMovie() - self.movie.setDimension(self.canvasSize[0], self.canvasSize[1]) - # set fps - self.movie.setRate(25) - numframes = endFrame - startFrame + 1 - self.movie.setFrames(numframes) + size = (self.canvasSize[0], self.canvasSize[1]) + self.canvas = canvas.Canvas(self.outputFileName, pagesize=size, bottomup=0) def close(self): """Do some finalization operation. """ - self.movie.save(self.outputFileName) + self.canvas.save() # remember to call the close method of the parent VectorWriter.close(self) @@ -918,12 +1740,7 @@ class SWFVectorWriter(VectorWriter): context = scene.getRenderingContext() framenumber = context.currentFrame() - Objects = scene.getChildren() - - if self.sprite: - self.movie.remove(self.sprite) - - sprite = SWFSprite() + Objects = scene.objects for obj in Objects: @@ -933,29 +1750,23 @@ class SWFVectorWriter(VectorWriter): mesh = obj.getData(mesh=1) if doPrintPolygons: - self._printPolygons(mesh, sprite) + self._printPolygons(mesh) if doPrintEdges: - self._printEdges(mesh, sprite, showHiddenEdges) - - sprite.nextFrame() - i = self.movie.add(sprite) - # Remove the instance the next time - self.sprite = i - if self.animation: - self.movie.nextFrame() + self._printEdges(mesh, showHiddenEdges) + + self.canvas.showPage() - - ## + ## # Private Methods # - + def _calcCanvasCoord(self, v): """Convert vertex in scene coordinates to canvas coordinates. """ pt = Vector([0, 0, 0]) - + mW = float(self.canvasSize[0])/2.0 mH = float(self.canvasSize[1])/2.0 @@ -963,15 +1774,15 @@ class SWFVectorWriter(VectorWriter): pt[0] = v.co[0]*mW + mW pt[1] = v.co[1]*mH + mH pt[2] = v.co[2] - + # For now we want (0,0) in the top-left corner of the canvas. # Mirror and translate along y pt[1] *= -1 pt[1] += self.canvasSize[1] - + return pt - - def _printPolygons(self, mesh, sprite): + + def _printPolygons(self, mesh): """Print the selected (visible) polygons. """ @@ -984,81 +1795,60 @@ class SWFVectorWriter(VectorWriter): if face.col: fcol = face.col[0] - color = [fcol.r, fcol.g, fcol.b, fcol.a] + color = [fcol.r/255.0, fcol.g/255.0, fcol.b/255.0, + fcol.a/255.0] else: - color = [255, 255, 255, 255] + color = [1, 1, 1, 1] - s = SWFShape() - f = s.addFill(color[0], color[1], color[2], color[3]) - s.setRightFill(f) + self.canvas.setFillColorRGB(color[0], color[1], color[2]) + # For debug + self.canvas.setStrokeColorRGB(0, 0, 0) - # The starting point of the shape - p0 = self._calcCanvasCoord(face.verts[0]) - s.movePenTo(p0[0], p0[1]) + path = self.canvas.beginPath() + # The starting point of the path + p0 = self._calcCanvasCoord(face.verts[0]) + path.moveTo(p0[0], p0[1]) for v in face.verts[1:]: p = self._calcCanvasCoord(v) - s.drawLineTo(p[0], p[1]) - - # Closing the shape - s.drawLineTo(p0[0], p0[1]) - s.end() - sprite.add(s) - - - """ - # use the stroke property to alleviate the "adjacent edges" problem, - # we simulate polygon expansion using borders, - # see http://www.antigrain.com/svg/index.html for more info - stroke_width = 1.0 + path.lineTo(p[0], p[1]) - # EXPANSION TRICK is not that useful where there is transparency - if config.polygons['EXPANSION_TRICK'] and color[3] == 255: - # str_col = "#000000" # For debug - self.file.write(" stroke:%s;\n" % str_col) - self.file.write(" stroke-width:" + str(stroke_width) + ";\n") - self.file.write(" stroke-linecap:round;stroke-linejoin:round") + # Closing the shape + path.close() - """ + self.canvas.drawPath(path, stroke=0, fill=1) - def _printEdges(self, mesh, sprite, showHiddenEdges=False): + def _printEdges(self, mesh, showHiddenEdges=False): """Print the wireframe using mesh edges. """ stroke_width = config.edges['WIDTH'] stroke_col = config.edges['COLOR'] - s = SWFShape() + self.canvas.setLineCap(1) + self.canvas.setLineJoin(1) + self.canvas.setLineWidth(stroke_width) + self.canvas.setStrokeColorRGB(stroke_col[0]/255.0, stroke_col[1]/255.0, + stroke_col[2]/255) for e in mesh.edges: - #Next, we set the line width and color for our shape. - s.setLine(stroke_width, stroke_col[0], stroke_col[1], stroke_col[2], - 255) - + self.canvas.setLineWidth(stroke_width) + if e.sel == 0: if showHiddenEdges == False: continue else: - # SWF does not support dashed lines natively, so -for now- - # draw hidden lines thinner and half-trasparent - s.setLine(stroke_width/2, stroke_col[0], stroke_col[1], - stroke_col[2], 128) + # PDF does not support dashed lines natively, so -for now- + # draw hidden lines thinner + self.canvas.setLineWidth(stroke_width/2.0) p1 = self._calcCanvasCoord(e.v1) p2 = self._calcCanvasCoord(e.v2) - # FIXME: this is just a qorkaround, remove that after the - # implementation of propoer Viewport clipping - if abs(p1[0]) < 3000 and abs(p2[0]) < 3000 and abs(p1[1]) < 3000 and abs(p1[2]) < 3000: - s.movePenTo(p1[0], p1[1]) - s.drawLineTo(p2[0], p2[1]) - + self.canvas.line(p1[0], p1[1], p2[0], p2[1]) - s.end() - sprite.add(s) - # --------------------------------------------------------------------- @@ -1080,12 +1870,15 @@ edgeStyles['SILHOUETTE'] = MeshUtils.isSilhouetteEdge # A dictionary to collect the supported output formats outputWriters = dict() outputWriters['SVG'] = SVGVectorWriter -outputWriters['SWF'] = SWFVectorWriter +if SWFSupported: + outputWriters['SWF'] = SWFVectorWriter +if PDFSupported: + outputWriters['PDF'] = PDFVectorWriter class Renderer: """Render a scene viewed from the active camera. - + This class is responsible of the rendering process, transformation and projection of the objects in the scene are invoked by the renderer. @@ -1101,7 +1894,7 @@ class Renderer: # Render the current Scene, this should be a READ-ONLY property self._SCENE = Scene.GetCurrent() - + # Use the aspect ratio of the scene rendering context context = self._SCENE.getRenderingContext() @@ -1110,21 +1903,10 @@ class Renderer: float(context.aspectRatioY()) ) - # Render from the currently active camera - self.cameraObj = self._SCENE.getCurrentCamera() - - # Get the list of lighting sources - obj_lst = self._SCENE.getChildren() - self.lights = [ o for o in obj_lst if o.getType() == 'Lamp'] + # Render from the currently active camera + #self.cameraObj = self._SCENE.objects.camera - # When there are no lights we use a default lighting source - # that have the same position of the camera - if len(self.lights) == 0: - l = Lamp.New('Lamp') - lobj = Object.New('Lamp') - lobj.loc = self.cameraObj.loc - lobj.link(l) - self.lights.append(lobj) + self.lights = [] ## @@ -1133,13 +1915,13 @@ class Renderer: def doRendering(self, outputWriter, animation=False): """Render picture or animation and write it out. - + The parameters are: - a Vector writer object that will be used to output the result. - a flag to tell if we want to render an animation or only the current frame. """ - + context = self._SCENE.getRenderingContext() origCurrentFrame = context.currentFrame() @@ -1152,17 +1934,24 @@ class Renderer: startFrame = context.startFrame() endFrame = context.endFrame() outputWriter.open(startFrame, endFrame) - + # Do the rendering process frame by frame - print "Start Rendering of %d frames" % (endFrame-startFrame) + print "Start Rendering of %d frames" % (endFrame-startFrame+1) for f in xrange(startFrame, endFrame+1): print "\n\nFrame: %d" % f - context.currentFrame(f) + + # FIXME To get the correct camera position we have to use +1 here. + # Is there a bug somewhere in the Scene module? + context.currentFrame(f+1) + self.cameraObj = self._SCENE.objects.camera # Use some temporary workspace, a full copy of the scene inputScene = self._SCENE.copy(2) - # And Set our camera accordingly - self.cameraObj = inputScene.getCurrentCamera() + + # To get the objects at this frame remove the +1 ... + ctx = inputScene.getRenderingContext() + ctx.currentFrame(f) + # Get a projector for this camera. # NOTE: the projector wants object in world coordinates, @@ -1178,7 +1967,7 @@ class Renderer: print traceback.print_exc() self._SCENE.makeCurrent() - Scene.unlink(inputScene) + Scene.Unlink(inputScene) del inputScene return @@ -1186,10 +1975,10 @@ class Renderer: doPrintPolygons = config.polygons['SHOW'], doPrintEdges = config.edges['SHOW'], showHiddenEdges = config.edges['SHOW_HIDDEN']) - + # delete the rendered scene self._SCENE.makeCurrent() - Scene.unlink(renderedScene) + Scene.Unlink(renderedScene) del renderedScene outputWriter.close() @@ -1199,13 +1988,17 @@ class Renderer: def doRenderScene(self, workScene): """Control the rendering process. - + Here we control the entire rendering process invoking the operation needed to transform and project the 3D scene in two dimensions. """ - + # global processing of the scene + self._filterHiddenObjects(workScene) + + self._buildLightSetup(workScene) + self._doSceneClipping(workScene) self._doConvertGeometricObjsToMesh(workScene) @@ -1214,10 +2007,11 @@ class Renderer: self._joinMeshObjectsInScene(workScene) self._doSceneDepthSorting(workScene) - + # Per object activities - Objects = workScene.getChildren() + Objects = workScene.objects + print "Total Objects: %d" % len(Objects) for i,obj in enumerate(Objects): print "\n\n-------" @@ -1284,7 +2078,7 @@ class Renderer: def _isFaceVisible(self, face): """Determine if a face of an object is visible from the current camera. - + The view vector is calculated from the camera location and one of the vertices of the face (expressed in World coordinates, after applying modelview transformations). @@ -1321,7 +2115,7 @@ class Renderer: # if d > 0 the face is visible from the camera d = view_vect * normal - + if d > 0: return True else: @@ -1330,13 +2124,45 @@ class Renderer: # Scene methods + def _filterHiddenObjects(self, scene): + """Discard object that are on hidden layers in the scene. + """ + + Objects = scene.objects + + visible_obj_list = [ obj for obj in Objects if + set(obj.layers).intersection(set(scene.getLayers())) ] + + for o in Objects: + if o not in visible_obj_list: + scene.objects.unlink(o) + + scene.update() + + + + def _buildLightSetup(self, scene): + # Get the list of lighting sources + obj_lst = scene.objects + self.lights = [ o for o in obj_lst if o.getType() == 'Lamp' ] + + # When there are no lights we use a default lighting source + # that have the same position of the camera + if len(self.lights) == 0: + l = Lamp.New('Lamp') + lobj = Object.New('Lamp') + lobj.loc = self.cameraObj.loc + lobj.link(l) + self.lights.append(lobj) + + def _doSceneClipping(self, scene): """Clip whole objects against the View Frustum. For now clip away only objects according to their center position. """ - cpos = self._getObjPosition(self.cameraObj) + cam_pos = self._getObjPosition(self.cameraObj) view_vect = self._cameraViewVector() near = self.cameraObj.data.clipStart @@ -1346,18 +2172,44 @@ class Renderer: fovy = atan(0.5/aspect/(self.cameraObj.data.lens/32)) fovy = fovy * 360.0/pi - Objects = scene.getChildren() + Objects = scene.objects + for o in Objects: if o.getType() != 'Mesh': continue; - obj_vect = Vector(cpos) - self._getObjPosition(o) + """ + obj_vect = Vector(cam_pos) - self._getObjPosition(o) d = obj_vect*view_vect theta = AngleBetweenVecs(obj_vect, view_vect) - + # if the object is outside the view frustum, clip it away if (d < near) or (d > far) or (theta > fovy): - scene.unlink(o) + scene.objects.unlink(o) + """ + + # Use the object bounding box + # (whose points are already in WorldSpace Coordinate) + + bb = o.getBoundBox() + + points_outside = 0 + for p in bb: + p_vect = Vector(cam_pos) - Vector(p) + + d = p_vect * view_vect + theta = AngleBetweenVecs(p_vect, view_vect) + + # Is this point outside the view frustum? + if (d < near) or (d > far) or (theta > fovy): + points_outside += 1 + + # If the bb is all outside the view frustum we clip the whole + # object away + if points_outside == len(bb): + scene.objects.unlink(o) + + def _doConvertGeometricObjsToMesh(self, scene): """Convert all "geometric" objects to mesh ones. @@ -1365,13 +2217,14 @@ class Renderer: geometricObjTypes = ['Mesh', 'Surf', 'Curve', 'Text'] #geometricObjTypes = ['Mesh', 'Surf', 'Curve'] - Objects = scene.getChildren() + Objects = scene.objects + objList = [ o for o in Objects if o.getType() in geometricObjTypes ] for obj in objList: old_obj = obj obj = self._convertToRawMeshObj(obj) - scene.link(obj) - scene.unlink(old_obj) + scene.objects.link(obj) + scene.objects.unlink(old_obj) # XXX Workaround for Text and Curve which have some normals @@ -1395,29 +2248,37 @@ class Renderer: c = self._getObjPosition(self.cameraObj) - by_center_pos = (lambda o1, o2: + by_obj_center_pos = (lambda o1, o2: (o1.getType() == 'Mesh' and o2.getType() == 'Mesh') and cmp((self._getObjPosition(o1) - Vector(c)).length, (self._getObjPosition(o2) - Vector(c)).length) ) - # TODO: implement sorting by bounding box, if obj1.bb is inside obj2.bb, - # then ob1 goes farther than obj2, useful when obj2 has holes - by_bbox = None - - Objects = scene.getChildren() - Objects.sort(by_center_pos) - + # Implement sorting by bounding box, the object with the bb + # nearest to the camera should be drawn as last. + by_nearest_bbox_point = (lambda o1, o2: + (o1.getType() == 'Mesh' and o2.getType() == 'Mesh') and + cmp( min( [(Vector(p) - Vector(c)).length for p in o1.getBoundBox()] ), + min( [(Vector(p) - Vector(c)).length for p in o2.getBoundBox()] ) + ) + ) + + + Objects = list(scene.objects) + + #Objects.sort(by_obj_center_pos) + Objects.sort(by_nearest_bbox_point) + # update the scene for o in Objects: - scene.unlink(o) - scene.link(o) + scene.objects.unlink(o) + scene.objects.link(o) def _joinMeshObjectsInScene(self, scene): """Merge all the Mesh Objects in a scene into a single Mesh Object. """ - oList = [o for o in scene.getChildren() if o.getType()=='Mesh'] + oList = [o for o in scene.objects if o.getType()=='Mesh'] # FIXME: Object.join() do not work if the list contains 1 object if len(oList) == 1: @@ -1427,23 +2288,23 @@ class Renderer: bigObj = Object.New('Mesh', 'BigOne') bigObj.link(mesh) - scene.link(bigObj) + scene.objects.link(bigObj) try: bigObj.join(oList) except RuntimeError: print "\nWarning! - Can't Join Objects\n" - scene.unlink(bigObj) + scene.objects.unlink(bigObj) return except TypeError: print "Objects Type error?" - + for o in oList: - scene.unlink(o) + scene.objects.unlink(o) scene.update() - + # Per object/mesh methods def _convertToRawMeshObj(self, object): @@ -1479,16 +2340,16 @@ class Renderer: def _doBackFaceCulling(self, mesh): """Simple Backface Culling routine. - + At this level we simply do a visibility test face by face and then select the vertices belonging to visible faces. """ - + # Select all vertices, so edges can be displayed even if there are no # faces for v in mesh.verts: v.sel = 1 - + Mesh.Mode(Mesh.SelectModes['FACE']) # Loop on faces for f in mesh.faces: @@ -1553,7 +2414,7 @@ class Renderer: light_obj = l light_pos = self._getObjPosition(l) light = light_obj.getData() - + L = Vector(light_pos).normalize() V = (Vector(camPos) - Vector(f.cent)).normalize() @@ -1641,6 +2502,72 @@ class Renderer: """Clip faces against the View Frustum. """ + # The Canonical View Volume, 8 vertices, and 6 faces, + # We consider its face normals pointing outside + + v1 = NMesh.Vert(1, 1, -1) + v2 = NMesh.Vert(1, -1, -1) + v3 = NMesh.Vert(-1, -1, -1) + v4 = NMesh.Vert(-1, 1, -1) + v5 = NMesh.Vert(1, 1, 1) + v6 = NMesh.Vert(1, -1, 1) + v7 = NMesh.Vert(-1, -1, 1) + v8 = NMesh.Vert(-1, 1, 1) + + cvv = [] + f1 = NMesh.Face([v1, v4, v3, v2]) + cvv.append(f1) + f2 = NMesh.Face([v5, v6, v7, v8]) + cvv.append(f2) + f3 = NMesh.Face([v1, v2, v6, v5]) + cvv.append(f3) + f4 = NMesh.Face([v2, v3, v7, v6]) + cvv.append(f4) + f5 = NMesh.Face([v3, v4, v8, v7]) + cvv.append(f5) + f6 = NMesh.Face([v4, v1, v5, v8]) + cvv.append(f6) + + nmesh = NMesh.GetRaw(mesh.name) + clippedfaces = nmesh.faces[:] + facelist = clippedfaces[:] + + for clipface in cvv: + + clippedfaces = [] + + for f in facelist: + + #newfaces = HSR.splitOn(clipface, f, return_positive_faces=False) + newfaces = None + + if not newfaces: + # Check if the face is all outside the view frustum + # TODO: Do this test before, it is more efficient + points_outside = 0 + for v in f: + if abs(v[0]) > 1-EPS or abs(v[1]) > 1-EPS or abs(v[2]) > 1-EPS: + points_outside += 1 + + if points_outside != len(f): + clippedfaces.append(f) + else: + for nf in newfaces: + for v in nf: + nmesh.verts.append(v) + + nf.mat = f.mat + nf.sel = f.sel + nf.col = [f.col[0]] * len(nf.v) + + clippedfaces.append(nf) + facelist = clippedfaces[:] + + + nmesh.faces = facelist + nmesh.update() + + # HSR routines def __simpleDepthSort(self, mesh): """Sort faces by the furthest vertex. @@ -1673,7 +2600,6 @@ class Renderer: """Newell's depth sorting. """ - from hsrtk import * #global progress @@ -1712,7 +2638,7 @@ class Renderer: progress.setActivity("HSR: Newell", len(facelist)) #progress.setQuiet(True) - + while len(facelist): debug("\n----------------------\n") debug("len(facelits): %d\n" % len(facelist)) @@ -1736,7 +2662,7 @@ class Renderer: qSign = sign(Q.normal[2]) # TODO: check also if Q is parallel?? - + # Test 0: We need to test only those Qs whose furthest vertex # is closer to the observer than the closest vertex of P. @@ -1754,7 +2680,7 @@ class Renderer: debug("met a marked face\n") continue - + # Test 1: X extent overlapping xP = [v.co[0] for v in P.v] xQ = [v.co[0] for v in Q.v] @@ -1777,12 +2703,12 @@ class Renderer: debug("\nTest 2\n") debug("NOT Y OVERLAP!\n") continue - + # Test 3: P vertices are all behind the plane of Q n = 0 for Pi in P: - d = qSign * Distance(Vector(Pi), Q) + d = qSign * HSR.Distance(Vector(Pi), Q) if d <= EPS: n += 1 pVerticesBehindPlaneQ = (n == len(P)) @@ -1796,7 +2722,7 @@ class Renderer: # Test 4: Q vertices in front of the plane of P n = 0 for Qi in Q: - d = pSign * Distance(Vector(Qi), P) + d = pSign * HSR.Distance(Vector(Qi), P) if d >= -EPS: n += 1 qVerticesInFrontPlaneP = (n == len(Q)) @@ -1810,7 +2736,8 @@ class Renderer: # Test 5: Check if projections of polygons effectively overlap, # in previous tests we checked only bounding boxes. - if not projectionsOverlap(P, Q): + #if not projectionsOverlap(P, Q): + if not ( HSR.projectionsOverlap(P, Q) or HSR.projectionsOverlap(Q, P)): debug("\nTest 5\n") debug("Projections do not overlap!\n") continue @@ -1824,9 +2751,9 @@ class Renderer: debug("Possibly a cycle detected!\n") debug("Split here!!\n") - facelist = facesplit(P, Q, facelist, nmesh) + facelist = HSR.facesplit(P, Q, facelist, nmesh) split_done = 1 - break + break # The question now is: Does Q obscure P? @@ -1834,7 +2761,7 @@ class Renderer: # Test 3bis: Q vertices are all behind the plane of P n = 0 for Qi in Q: - d = pSign * Distance(Vector(Qi), P) + d = pSign * HSR.Distance(Vector(Qi), P) if d <= EPS: n += 1 qVerticesBehindPlaneP = (n == len(Q)) @@ -1847,7 +2774,7 @@ class Renderer: # Test 4bis: P vertices in front of the plane of Q n = 0 for Pi in P: - d = qSign * Distance(Vector(Pi), Q) + d = qSign * HSR.Distance(Vector(Pi), Q) if d >= -EPS: n += 1 pVerticesInFrontPlaneQ = (n == len(P)) @@ -1856,7 +2783,7 @@ class Renderer: debug("\nTest 4bis\n") debug("P IN FRONT OF Q!\n") - + # We don't even know if Q does obscure P, so they should # intersect each other, split one of them in two parts. if not qVerticesBehindPlaneP and not pVerticesInFrontPlaneQ: @@ -1864,24 +2791,29 @@ class Renderer: debug("Test 3bis or 4bis failed\n") debug("Split here!!2\n") - facelist = facesplit(P, Q, facelist, nmesh) + facelist = HSR.facesplit(P, Q, facelist, nmesh) split_done = 1 - break - + break + facelist.remove(Q) facelist.insert(0, Q) Q.smooth = 1 face_marked = 1 debug("Q marked!\n") break - - # Write P! + + # Write P! if split_done == 0 and face_marked == 0: facelist.remove(P) maplist.append(P) + dumpfaces(maplist, "dump"+str(len(maplist)).zfill(4)+".svg") progress.update() + if len(facelist) == 870: + dumpfaces([P, Q], "loopdebug.svg") + + #if facelist == None: # maplist = [P, Q] # print [v.co for v in P] @@ -1889,11 +2821,11 @@ class Renderer: # break # end of while len(facelist) - + nmesh.faces = maplist - for f in nmesh.faces: - f.sel = 1 + #for f in nmesh.faces: + # f.sel = 1 nmesh.update() @@ -1943,7 +2875,7 @@ class Renderer: if edgestyleSelect(e, mesh): e.sel = 1 """ - + # # --------------------------------------------------------------------- @@ -1957,10 +2889,10 @@ from Blender import BGL, Draw from Blender.BGL import * class GUI: - + def _init(): - # Output Format menu + # Output Format menu output_format = config.output['FORMAT'] default_value = outputWriters.keys().index(output_format)+1 GUI.outFormatMenu = Draw.Create(default_value) @@ -1977,7 +2909,7 @@ class GUI: # Render filled polygons GUI.polygonsToggle = Draw.Create(config.polygons['SHOW']) - # Shading Style menu + # Shading Style menu shading_style = config.polygons['SHADING'] default_value = shadingStyles.keys().index(shading_style)+1 GUI.shadingStyleMenu = Draw.Create(default_value) @@ -1994,7 +2926,7 @@ class GUI: GUI.showHiddenEdgesToggle = Draw.Create(config.edges['SHOW_HIDDEN']) GUI.evtShowHiddenEdgesToggle = 5 - # Edge Style menu + # Edge Style menu edge_style = config.edges['STYLE'] default_value = edgeStyles.keys().index(edge_style)+1 GUI.edgeStyleMenu = Draw.Create(default_value) @@ -2015,6 +2947,9 @@ class GUI: # Exit Button GUI.evtExitButton = 9 + # Save default button + GUI.evtSaveDefaultButton = 99 + def draw(): # initialize static members @@ -2022,9 +2957,12 @@ class GUI: glClear(GL_COLOR_BUFFER_BIT) glColor3f(0.0, 0.0, 0.0) - glRasterPos2i(10, 350) + glRasterPos2i(10, 380) Draw.Text("VRM: Vector Rendering Method script. Version %s." % __version__) + glRasterPos2i(10, 365) + Draw.Text("%s (c) 2006, 2007" % __author__) + glRasterPos2i(10, 335) Draw.Text("Press Q or ESC to quit.") @@ -2052,6 +2990,9 @@ class GUI: "Start Rendering") Draw.Button("Exit", GUI.evtExitButton, 95, 210-25, 75, 25+18, "Exit!") + Draw.Button("Save settings as default", GUI.evtSaveDefaultButton, 10, 210-50, 160, 18, + "Save settings as default") + # Rendering Styles glRasterPos2i(200, 310) Draw.Text("Rendering Style:") @@ -2078,7 +3019,7 @@ class GUI: "Render polygon edges") if GUI.showEdgesToggle.val == 1: - + # Edge Style edgeStyleMenuStruct = "Edge Style %t" for t in edgeStyles.keys(): @@ -2102,8 +3043,6 @@ class GUI: 200, 160, 160, 18, GUI.showHiddenEdgesToggle.val, "Render hidden edges as dashed lines") - glRasterPos2i(10, 160) - Draw.Text("%s (c) 2006" % __author__) def event(evt, val): @@ -2122,6 +3061,9 @@ class GUI: elif evt == GUI.evtOutFormatMenu: i = GUI.outFormatMenu.val - 1 config.output['FORMAT']= outputWriters.keys()[i] + # Set the new output file + global outputfile + outputfile = Blender.sys.splitext(basename)[0] + "." + str(config.output['FORMAT']).lower() elif evt == GUI.evtAnimToggle: config.output['ANIMATION'] = bool(GUI.animToggle.val) @@ -2158,6 +3100,9 @@ class GUI: global outputfile Blender.Window.FileSelector(vectorize, label, outputfile) + elif evt == GUI.evtSaveDefaultButton: + config.saveToRegistry() + else: print "Event: %d not handled!" % evt @@ -2181,7 +3126,7 @@ class GUI: # A wrapper function for the vectorizing process def vectorize(filename): """The vectorizing process is as follows: - + - Instanciate the writer and the renderer - Render! """ @@ -2196,17 +3141,26 @@ def vectorize(filename): actualWriter = outputWriters[config.output['FORMAT']] writer = actualWriter(filename) - + renderer = Renderer() renderer.doRendering(writer, config.output['ANIMATION']) - if editmode: Window.EditMode(1) + if editmode: Window.EditMode(1) + + # Here the main if __name__ == "__main__": global progress + config.loadFromRegistry() + + # initialize writer setting also here to configure writer specific + # settings on startup + actualWriter = outputWriters[config.output['FORMAT']] + writer = actualWriter("") + outputfile = "" basename = Blender.sys.basename(Blender.Get('filename')) if basename != "":