Ok hopefully is not that big!
So it I take all out all the IF's and related cells/variables (like "pdrw") it runs.
If include the IF's back I have the following error:
lbOPDO = Label(root, text="OUTPUT DATA",width=35,font=("bold", 14))
^
SyntaxError: invalid syntax
Process finished with exit code 1
import tkinter
import math
from tkinter import *
root = Tk()
menubar = Menu(root)
root.config(menu=menubar)
root.state("zoomed")
root.title("Fluxo Cruzado")
subMenu = Menu(menubar, tearoff = 0)
menubar.add_cascade(label="File", menu=subMenu)
subMenu.add_command(label="Save")
subMenu.add_command(label="Save As")
subMenu.add_command(label="Open")
subMenu.add_command(label="Print")
subMenu.add_command(label="Exit")
subMenu = Menu(menubar, tearoff = 0)
menubar.add_cascade(label="Help", menu=subMenu)
subMenu.add_command(label="About Us")
subMenu.add_command(label="Version")
########################### IMAGE ##############################
photo = PhotoImage(file="syngg.png")
label = Label(root, image=photo)
label.pack()
########################### INPUT WINDOW AND INFO #######################################
label_17 = Label(root, text="SYNKICK - DEMO",width=35,font=("bold", 14))
label_17.place(x=570,y=130)
lbgd = Label(root, text="GENERAL DATA",width=35,font=("bold", 14))
lbgd.place(x=100,y=160)
lbwn = Label(root, text="WELL NAME: ",width=20,font=("bold", 10))
lbwn.place(x=25,y=190)
wellnameE = Entry(root)
wellnameE.place(x=340,y=190)
lbRIG = Label(root, text="RIG: ",width=20,font=("bold",10))
lbRIG.place(x=25,y=215)
RIGE = Entry(root)
RIGE.place(x=340,y=215)
lbDate = Label(root, text="DATE (MM/DD/YYYY): ",width=20,font=("bold",10))
lbDate.place(x=25,y=240)
dateE = Entry(root)
dateE.place(x=340,y=240)
lbInPD = Label(root, text="INPUT DATA",width=35,font=("bold", 14))
lbInPD.place(x=100,y=265)
#lbResInf = Label(root, text="Reservoir Information",width=20,font=("bold", 13))
#lbResInf.place(x=180,y=290)
lbRTop = Label(root, text="Well Fluid Density (SCOL): ",width=22,font=("bold",10))
lbRTop.place(x=25,y=315)
rte = Entry(root)
rte.place(x=340,y=315)
lbResB = Label(root, text="Vertical Depth Drilled (m): ",width=22,font=("bold",10))
lbResB.place(x=25,y=340)
rbe = Entry(root)
rbe.place(x=340,y=340)
lbResP = Label(root, text="Estimated Fluid Density (PPG): ",width=25,font=("bold",10))
lbResP.place(x=23,y=365)
rpe = Entry(root)
rpe.place(x=340,y=365)
lbRFV = Label(root, text="Water Depth (m): ",width=22,font=("bold",10))
lbRFV.place(x=25,y=390)
rfve = Entry(root)
rfve.place(x=340,y=390)
lbRFD = Label(root, text="Air Gap (m): ",width=22,font=("bold",10))
lbRFD.place(x=25,y=415)
rfde = Entry(root)
rfde.place(x=340,y=415)
lbppgrb = Label(root, text="Reservoir Top (m): ",width=35,font=("bold",10))
lbppgrb.place(x=10-35,y=440)
ppgrbe = Entry(root)
ppgrbe.place(x=340,y=440)
#lbWInfo = Label(root, text="WELL INFORMATION",width=20,font=("bold", 13))
#lbWInfo.place(x=180,y=465)
lbvdd = Label(root, text="BOP Pressure (psi): ",width=22,font=("bold",10))
lbvdd.place(x=25,y=495)
vdde = Entry(root)
vdde.place(x=340,y=495)
lbDFD = Label(root, text="Diameter (in): ",width=22,font=("bold",10))
lbDFD.place(x=25,y=520)
dfde = Entry(root)
dfde.place(x=340,y=520)
lbWDIAM = Label(root, text="Reservoir K (md): ",width=22,font=("bold",10))
lbWDIAM.place(x=25,y=545)
wdiame = Entry(root)
wdiame.place(x=340,y=545)
lbmll = Label(root, text="Viscosity (cp): ",width=22,font=("bold",10))
lbmll.place(x=25,y=570)
mlle = Entry(root)
mlle.place(x=340,y=570)
######################## Output WINDOW #################################
def show_answer():
################# CALLING INPUT DATA ################################
wnent = wellnameE.get()
rigent = RIGE.get()
dateent = dateE.get()
restop = rte.get() #Well Fluid Density
resbase = rbe.get() #VERTICAL DEPTH DRILLED
resperm = rpe.get() #Estimated Drilling Fluid Density
resfvis = rfve.get() #Water Depth
resfden = rfde.get() #Air Gap
ppgrb = ppgrbe.get() #Reservoir Top
vdd = vdde.get() #BOP Pressure
dfd = dfde.get() #Well Diameter
wdiam = wdiame.get() #ReservoirK
mll = mlle.get() #Viscosity
######################### CALCULATIONS ###############################
#### INSIDE CALCULATIONS for OUTPUT #####
n = float(6)
delta = (float(resbase)-float(ppgrb))/(n-1) #(VDD-RTOP)/(K-1)
#### OUTPUT CALCULATIONS #####
comp = round(((float(resbase)-float(ppgrb))/float(n-1)),2)
sup = round((3.14*(float(dfd)/12)*float(comp)),2)
wdag = round((float(resfvis)+float(resfden)), 2)
mlal = round((float(vdd) / (0.17 * float(restop))), 2)
rmd = round((float(wdag)+float(mlal)+25), 2)
bpatl = round(float(vdd), 2)
ppgb = round(((0.17*float(restop)*(float(resbase)-float(wdag)+float(mlal))/(0.17*float(resbase)))), 2)
bppsi = round(0.17*float(restop)*(float(resbase)-float(wdag)+float(mlal)), 2)
bpppg = round((float(bppsi)/(0.17*float(resbase))), 2)
tppsi = round(float(bppsi)-0.17*float(resperm)*(float(resbase)-float(ppgrb)),2)
tpppg = round(float(tppsi)/(0.1704*float(ppgrb)),2)
#pdrw = round(float(pff1)-float(pfpcp1),2)
#Inside Calculations for Table and Extra Info
#PROFUNDIDADE (depth, prof6>x>prof1)
prof6 = resbase
prof5 = float(prof6) - float(delta)
prof4 = float(prof5) - float(delta)
prof3 = float(prof4) - float(delta)
prof2 = float(prof3) - float(delta)
prof1 = float(prof2) - float(delta)
#pfpSp - #Pressão Fluido Perf SEM Perda
pfpsp1 = float(prof1) * 0.17 * float(restop)
pfpsp2 = float(prof2) * 0.17 * float(restop)
pfpsp3 = float(prof3) * 0.17 * float(restop)
pfpsp4 = float(prof4) * 0.17 * float(restop)
pfpsp5 = float(prof5) * 0.17 * float(restop)
pfpsp6 = float(prof6) * 0.17 * float(restop)
#pfpCp-Pressão Fluido Perf COM Perda
pfpcp6 = bppsi
pfpcp5 = float(pfpcp6) - 0.17 * (float(prof6) - float(prof5)) * float(restop)
pfpcp4 = float(pfpcp5) - 0.17 * (float(prof5) - float(prof4)) * float(restop)
pfpcp3 = float(pfpcp4) - 0.17 * (float(prof4) - float(prof3)) * float(restop)
pfpcp2 = float(pfpcp3) - 0.17 * (float(prof3) - float(prof4)) * float(restop)
pfpcp1 = float(pfpcp2) - 0.17 * (float(prof2) - float(prof1)) * float(restop)
#PFF-PRESSAO FLUIDO FORMACAO
#pff6 = bpppg
#if prof5 < ppgrb:
#pff5 = 0
#else:
#pff5 = (float(bpppg)-0.17*float(resperm)*(float(prof6)-float(prof5)))
#if prof4 < ppgrb:
#pff4 = 0
#else:
#pff4 = (float(pff5)-0.17*float(resperm)*(float(prof5)-float(prof4)))
#if prof3 < ppgrb:
#pff3 = 0
#else:
#pff3 = (float(pff4)-0.17*float(resperm)*(float(prof4)-float(prof3)))
#if prof2 < ppgrb:
#pff2 = 0
#else:
#pff2 = (float(pff3)-0.17*float(resperm)*(float(prof3)-float(prof2)))
#if prof1 < ppgrb:
#pff1 = 0
#else:
#pff1 = (float(pff3)-0.17*(float(resperm)*(float(prof3)-float(prof1)))
################## Output DATA #######################################
lbOPDO = Label(root, text="OUTPUT DATA",width=35,font=("bold", 14))
lbOPDO.place(x=720,y=160)
lbcompo = Label(root, text="Comprimento (m): ",width=35,font=("bold",10))
lbcompo.place(x=15*45,y=190)
lbcompe = Label(root, text=comp,width=22,font=("bold",10))
lbcompe.place(x=1000,y=190)
lbsupo = Label(root, text="Sup Area (m2): ",width=35,font=("bold",10))
lbsupo.place(x=15*45,y=215)
lbsupe = Label(root, text=sup,width=22,font=("bold",10))
lbsupe.place(x=1000,y=215)
lbwdago= Label(root, text="Water Depth + Air Gap (m): ",width=35,font=("bold",10))
lbwdago.place(x=15*45,y=240)
lbwdage = Label(root, text=wdag,width=22,font=("bold",10))
lbwdage.place(x=1000,y=240)
lbmlalo = Label(root, text="Mud Line After Loss (m): ",width=35,font=("bold",10))
lbmlalo.place(x=15*45,y=265)
lbmlale = Label(root, text=mlal,width=22,font=("bold",10))
lbmlale.place(x=1000,y=265)
lbrmdo = Label(root, text="Riser Mud Depth (m): ",width=35,font=("bold",10))
lbrmdo.place(x=15*45,y=290)
lbrmde = Label(root, text=rmd,width=22,font=("bold",10))
lbrmde.place(x=1000,y=290)
lbbpatlo = Label(root, text="BOP Pressure After TotaL Loss (psi): ",width=35,font=("bold",10))
lbbpatlo.place(x=15*45,y=315)
lbbpatle = Label(root, text=bpatl,width=22,font=("bold",10))
lbbpatle.place(x=1000,y=315)
lbppgbo = Label(root, text="Pore Pressure Gradient at Base (ppg): ",width=35,font=("bold", 10))
lbppgbo.place(x=15*45,y=340)
lbppgbe = Label(root, text=ppgb,width=22,font=("bold",10))
lbppgbe.place(x=1000,y=340)
lbCONCO = Label(root, text="Conclusions",width=35,font=("bold",14))
lbCONCO.place(x=720,y=395)
lbbppsio = Label(root, text="Bottom Pore Pressure / Gradient (psi): ", width=35, font=("bold", 10))
lbbppsio.place(x=15 * 45, y=425)
lbbppsie = Label(root, text=bppsi, width=22, font=("bold", 10))
lbbppsie.place(x=1000, y=425)
lbbpppgo = Label(root, text="Bottom Pore Pressure / Gradient (ppg): ", width=35, font=("bold", 10))
lbbpppgo.place(x=15 * 45, y=450)
lbbpppge = Label(root, text=bpppg, width=22, font=("bold", 10))
lbbpppge.place(x=1000, y=450)
lbtppsio = Label(root, text="Top Pore Pressure / Gradient (psi): ", width=35, font=("bold", 10))
lbtppsio.place(x=15 * 45, y=475)
lbtppsie = Label(root, text=tppsi, width=22, font=("bold", 10))
lbtppsie.place(x=1000, y=475)
lbtpppgo = Label(root, text="Top Pore Pressure / Gradient (ppg): ", width=35, font=("bold", 10))
lbtpppgo.place(x=15 * 45, y=500)
lbtpppge = Label(root, text=tpppg, width=22, font=("bold", 10))
lbtpppge.place(x=1000, y=500)
#lbpdrwo = Label(root, text="Pressure Differential Reservoir/Well Res. Top (psi): ", width=35, font=("bold", 10))
#lbpdrwo.place(x=15 * 45, y=525)
#lbpdrwe = Label(root, text=pdrw,width=22,font=("bold",10))
#lbpdrwe.place(x=1000, y=525)
# lbkfrdo = Label(root, text="Kick Flow Rate (bbl/day): ", width=35, font=("bold", 10))
# lbkfrdo.place(x=15 * 45, y=425)
# lbkfrde = Label(root, text=kfrd,width=22,font=("bold",10))
# lbkfrde.place(x=1000, y=425)
# lbkfrho = Label(root, text="Kick Flow Rate (bbl/hour): ", width=35, font=("bold", 10))
# lbkfrho.place(x=15 * 45, y=450)
# lbkfrhe = Label(root, text=kfrh, width=22, font=("bold", 10))
# lbkfrhe.place(x=1000, y=450)
btn = Button(root, text = 'Calculate', command=show_answer)
btn.pack(side='bottom')
root.mainloop()