blender/release/scripts/bpymodules/eps2obj.py

#----------------------------------------------
# (c) jm soler juillet 2004, released under Blender Artistic Licence 
#    for the Blender 2.34 Python Scripts Bundle.
#----------------------------------------------
# Page officielle :
#   http://jmsoler.free.fr/didacticiel/blender/tutor/cpl_import_eps.htm
# Communiquer les problemes et erreurs sur:
#   http://www.zoo-logique.org/3D.Blender/newsportal/thread.php?group=3D.Blender
#----------------------------------------------

SHARP_IMPORT=0
SCALE=1
scale=1

import sys
#oldpath=sys.path
import Blender
BLversion=Blender.Get('version')

try:
    import nt
    os=nt
    os.sep='\\'

except:    
    import posix
    os=posix
    os.sep='/'
    
def isdir(path):
    try:
        st = os.stat(path)
        return 1 
    except:
        return 0
    
def split(pathname):
         if pathname.find(os.sep)!=-1:
             k0=pathname.split(os.sep)
         else:
            if os.sep=='/':
                k0=pathname.split('\\')
            else:
                k0=pathname.split('/') 

         directory=pathname.replace(k0[len(k0)-1],'')
         Name=k0[len(k0)-1]
         return directory, Name
        
def join(l0,l1):        
     return  l0+os.sep+l1
    
os.isdir=isdir
os.split=split
os.join=join

def filtreFICHIER(nom):
     f=open(nom,'r')
     t=f.readlines()
     f.close()
     if len(t)==1 and t[0].find('\r'):
              t=t[0].split('\r')
     if len(t)>1: 
          return t   
     else:
         name = "OK?%t| Not a valid file or an empty file ... "  # if no %xN int is set, indices start from 1
         result = Draw.PupMenu(name)
         return 'false'
        
#===============================
# Data
#===============================
#===============================
# Blender Curve Data
#===============================
objBEZIER=0
objSURFACE=5
typBEZIER3D=1  #3D
typBEZIER2D=9  #2D

class Bez:
      def __init__(self):
           self.co=[]
           self.ha=[0,0]
           
class ITEM:
      def __init__(self):
               self.type        =  typBEZIER3D,    
               self.pntsUV      =  [0,0]              
               self.resolUV     =  [32,0]            
               self.orderUV     =  [0,0]             
               self.flagUV      =  [0,0]              
               self.Origine     =  [0.0,0.0]
               self.beziers_knot = []

class COURBE:
      def __init__(self):
              self.magic_number='3DG3'              
              self.type            =  objBEZIER        
              self.number_of_items =  0              
              self.ext1_ext2       =  [0,0]             
              self.matrix          =  """0.0 0.0 1.0 0.0
0.0 1.0 0.0 0.0
0.0 0.0 1.0 0.0
0.0 0.0 0.0 1.0 """ #- right-handed object matrix. Used to determine position, rotation and size
              self.ITEM            = {}

courbes=COURBE()
PATTERN={}
BOUNDINGBOX={'rec':[],'coef':1.0}
npat=0
#=====================================================================
#======== name of the curve in teh courbes dictionnary ===============
#=====================================================================
n0=0

#=====================================================================
#====================== current Point ================================
#=====================================================================
CP=[0.0,0.0] #currentPoint

#=====================================================================
#===== to compare last position to the original move to displacement =
#=====  needed for cyclic efinition  =================================
#=====================================================================
def test_egalitedespositions(f1,f2):
    if f1[0]==f2[0] and f1[1]==f2[1]:
       return Blender.TRUE
    else:
       return Blender.FALSE


def Open_GEOfile(dir,nom):
    global SCALE,BOUNDINGBOX, scale
    if BLversion>=233:
       Blender.Load(dir+nom+'OOO.obj', 1)
       BO=Blender.Object.Get()

       BO[-1].RotY=3.1416
       BO[-1].RotZ=3.1416
       BO[-1].RotX=3.1416/2.0
       if scale==1:
          BO[-1].LocY+=BOUNDINGBOX['rec'][3]
       else:
         BO[-1].LocY+=BOUNDINGBOX['rec'][3]/SCALE

       BO[-1].makeDisplayList() 
       Blender.Window.RedrawAll()
    else:
       print "Not yet implemented"

def create_GEOtext(courbes):
    global SCALE, B, BOUNDINGBOX,scale
    r=BOUNDINGBOX['rec']

    if scale==1:
       SCALE=1.0
    elif scale==2:
       SCALE=r[2]-r[0]
    elif scale==3:
       SCALE=r[3]-r[1]
 
    t=[]
    t.append(courbes.magic_number+'\n')
    t.append(str(courbes.type)+'\n')
    t.append(str(courbes.number_of_items)+'\n')
    t.append(str(courbes.ext1_ext2[0])+' '+str(courbes.ext1_ext2[1])+'\n')
    t.append(courbes.matrix+'\n')
    
    for k in courbes.ITEM.keys():
        t.append("%s\n"%courbes.ITEM[k].type)
        t.append("%s %s \n"%(courbes.ITEM[k].pntsUV[0],courbes.ITEM[k].pntsUV[1]))
        t.append("%s %s \n"%(courbes.ITEM[k].resolUV[0],courbes.ITEM[k].resolUV[1]))
        t.append("%s %s \n"%(courbes.ITEM[k].orderUV[0],courbes.ITEM[k].orderUV[1]))
        t.append("%s %s \n"%(courbes.ITEM[k].flagUV[0],courbes.ITEM[k].flagUV[1]))

        flag =courbes.ITEM[k].flagUV[0]

        for k2 in range(flag,len(courbes.ITEM[k].beziers_knot)):
           k1 =courbes.ITEM[k].beziers_knot[k2]
           t.append("%4f 0.0 %4f \n"%(float(k1.co[0])/SCALE,float(k1.co[1])/SCALE))
           t.append("%4f 0.0 %4f \n"%(float(k1.co[2])/SCALE,float(k1.co[3])/SCALE))
           t.append("%4f 0.0 %4f \n"%(float(k1.co[4])/SCALE,float(k1.co[5])/SCALE))
           t.append(str(k1.ha[0])+' '+str(k1.ha[1])+'\n')
    return t

def save_GEOfile(dir,nom,t):
     f=open(dir+nom+'OOO.obj','w')
     f.writelines(t)
     f.close()

     #name = "REMINDER : %t | Do not forget to rename your blender file NOW ! %x1"
     #result = Blender.Draw.PupMenu(name)


#=====================================================================
#=====      EPS format   :  DEBUT             =========================
#=====================================================================
def mouvement_vers(l,n0,CP):
    if n0 in courbes.ITEM.keys():
       #if  test_egalitedespositions(courbes.ITEM[n0].Origine,CP):
       #   courbes.ITEM[n0].flagUV[0]=1 
       n0+=1
       CP=[l[-3].replace('d',''),l[-2]]        
    else:
       CP=[l[-3].replace('d',''),l[-2]] 
    #i=
    courbes.ITEM[n0]=ITEM() 
    courbes.ITEM[n0].Origine=[l[-3].replace('d',''),l[-2]] 
    
    B=Bez()
    B.co=[CP[0],CP[1],CP[0],CP[1],CP[0],CP[1]]
    B.ha=[0,0]    
    courbes.ITEM[n0].beziers_knot.append(B)       

    return  courbes,n0,CP     

def rmouvement_vers(l,n0,CP):
    if n0 in courbes.ITEM.keys():
       #if  test_egalitedespositions(courbes.ITEM[n0].Origine,CP):
       #   courbes.ITEM[n0].flagUV[0]=1 
       n0+=1
       CP=["%4f"%(float(l[-3])+float(CP[0])),"%4f"%(float(l[-2])+float(CP[1]))] 
    else:
       CP=["%4f"%(float(l[-3])+float(CP[0])),"%4f"%(float(l[-2])+float(CP[1]))] 
    #i=
    courbes.ITEM[n0]=ITEM() 
    courbes.ITEM[n0].Origine=[l[-3].replace('d',''),l[-2]] 
    
    B=Bez()
    B.co=[CP[0],CP[1],CP[0],CP[1],CP[0],CP[1]]
    B.ha=[0,0]    
    courbes.ITEM[n0].beziers_knot.append(B)       
    return  courbes,n0,CP     
       
def courbe_vers_c(l, l2, n0,CP): #c,C
    """
    B=Bez()
    B.co=[l[0],l[1],l[2],l[3],l[4],l[5]]
    B.ha=[0,0]

    courbes.ITEM[n0].beziers_knot.append(B)
    """
    B=Bez()
    B.co=[l[2],l[3],l[4],l[5],l[0],l[1]]
    if len(courbes.ITEM[n0].beziers_knot)==1:
       CP=[l[0],l[1]]
       courbes.ITEM[n0].Origine=[l[0],l[1]]
    if l[-1]=='C':  
        B.ha=[2,2]
    else:
        B.ha=[0,0]
    courbes.ITEM[n0].beziers_knot.append(B)
    if len(l2)>1 and l2[-1] in Actions.keys():
       B.co[-2]=l2[0]
       B.co[-1]=l2[1]
    else:
       B.co[-2]=CP[0]
       B.co[-1]=CP[1]
    return  courbes,n0,CP
      
def ligne_tracee_l(l,n0,CP):
    B=Bez()
    B.co=[l[0],l[1],l[0],l[1],l[0],l[1]]
    B.ha=[0,0]
    courbes.ITEM[n0].beziers_knot.append(B)    
    CP=[l[0],l[1]]
    return  courbes,n0,CP    

def rligne_tracee_l(l,n0,CP):
    B=Bez()
    B.co=["%4f"%(float(l[0])+float(CP[0])),
          "%4f"%(float(l[1])+float(CP[1])),
          "%4f"%(float(l[0])+float(CP[0])),
          "%4f"%(float(l[1])+float(CP[1])),
          "%4f"%(float(l[0])+float(CP[0])),
          "%4f"%(float(l[1])+float(CP[1]))]   
    B.ha=[0,0]
    courbes.ITEM[n0].beziers_knot.append(B)    
    CP=[l[0],l[1]]
    return  courbes,n0,CP    
     
Actions=   {     "curveto" : courbe_vers_c,
                 "curveto" : courbe_vers_c,
                 "moveto" : mouvement_vers,
                 "rmoveto" : mouvement_vers,
                 "lineto" : ligne_tracee_l,
                 "rlineto" : rligne_tracee_l
}
     
TAGcourbe=Actions.keys()

"""                 
def pik_pattern(t,l):
    global npat, PATTERN, BOUNDINGBOX
    while t[l].find('%%EndSetup')!=0:   
          if t[l].find('%%BoundingBox:')!=-1:
             l0=t[l].split()
             BOUNDINGBOX['rec']=[float(l0[-4]),float(l0[-3]),float(l0[-2]),float(l0[-1])]
             r=BOUNDINGBOX['rec']
             BOUNDINGBOX['coef']=(r[3]-r[1])/(r[2]-r[0])
          print l,
          if  t[l].find('BeginPatternLayer')!=-1:
               npat+=1
               PATTERN[npat]=[]
               while t[l].find('EndPatternLayer')==-1:
                     print t[l] 
                     PATTERN[npat].append(l) 
                     l+=1   
          if l+1<len(t):
             l=l+1
          else:
             return 1,l
    return 1,l
"""
             
def scan_FILE(nom):
  global CP, courbes, SCALE, scale
  dir,name=split(nom)
  name=name.split('.')
  n0=0
  result=0
  t=filtreFICHIER(nom)

  if nom.upper().find('.EPS')!=-1 or nom.upper().find('.PS')!=-1 and t!='false':
     if not SHARP_IMPORT:
         warning = "Select Size : %t| As is %x1 | Scale on Height %x2| Scale on Width %x3" 
         scale = Blender.Draw.PupMenu(warning)
     npat=0
     l=0
     do=0
     while l <len(t)-1 :
       if t[l].find('%%BoundingBox:')!=-1:
             l0=t[l].split()
             BOUNDINGBOX['rec']=[float(l0[-4]),float(l0[-3]),float(l0[-2]),float(l0[-1])]
             r=BOUNDINGBOX['rec']
             BOUNDINGBOX['coef']=(r[3]-r[1])/(r[2]-r[0])
       """
       if not do:
          do,l=pik_pattern(t,l)
       """
       #print 'len(t)',len(t)        
       t[l].replace('\n','') 
       if t[l][0]!='%':
            l0=t[l].split()
            if l0!=[] and l0[-1] in TAGcourbe:
                if l0[-1] in ['curveto']:
                   l2=t[l+1].split()
                   courbes,n0,CP=Actions[l0[-1]](l0,l2,n0,CP)
                else: 
                   courbes,n0,CP=Actions[l0[-1]](l0,n0,CP)

       l=l+1#; print l                    
     t=[]
     
  if  t!='false':
      courbes.number_of_items=len(courbes.ITEM.keys())

      for k in courbes.ITEM.keys():
         courbes.ITEM[k].pntsUV[0] =len(courbes.ITEM[k].beziers_knot)

         if  test_egalitedespositions(courbes.ITEM[k].Origine,
                                      [courbes.ITEM[k].beziers_knot[-1].co[-2],
                                       courbes.ITEM[k].beziers_knot[-1].co[-1]]):
              courbes.ITEM[k].flagUV[0]=1 
              courbes.ITEM[k].pntsUV[0] -=1

      if courbes.number_of_items>0:
         if len(PATTERN.keys() )>0:
            #print len(PATTERN.keys() )
            pass
         t=create_GEOtext(courbes)
         save_GEOfile(dir,name[0],t)
         Open_GEOfile(dir,name[0])
      else:
          pass

    
#=====================================================================
#====================== EPS format mouvements =========================
#=====================================================================
#=========================================================          
# une sorte de contournement qui permet d'utiliser la fonction
# et de documenter les variables Window.FileSelector
#=========================================================
def fonctionSELECT(nom):
    scan_FILE(nom)

#Blender.Window.FileSelector (fonctionSELECT, 'SELECT .EPS/.PS FILE')
#sys.path=oldpath