tables.py

#!/usr/bin/env python2
# -*- coding: utf-8 -*-

#   Copyright (C) 2021  Andrew Bauer
#   Copyright (C) 2014  Enno Rodegerdts

#   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
#   the Free Software Foundation; either version 3 of the License, or
#   (at your option) any later version.
# 
#   This program is distributed in the hope that it will be useful,
#   but WITHOUT ANY WARRANTY; without even the implied warranty of
#   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
#   GNU General Public License for more details.
# 
#   You should have received a copy of the GNU General Public License along
#   with this program.  If not, see <https://www.gnu.org/licenses/>.

# NOTE: the new format statement requires a literal '{' to be entered as '{{',
#       and a literal '}' to be entered as '}}'. The old '%' format specifier
#       will be removed from Python at some later time. See:
# https://docs.python.org/3/whatsnew/3.0.html#pep-3101-a-new-approach-to-string-formatting

# Standard library imports
import datetime		# required for .timedelta()
import sys			# required for .stdout.write()
import math

# Local application imports
from alma_skyfield import *
from alma_ephem import *
import config

UpperLists = [[], [], []]    # moon GHA per hour for 3 days
LowerLists = [[], [], []]    # moon colong GHA per hour for 3 days

def planetstab(date):
    # generates a LaTeX table for the navigational plantets (traditional style)
    tab = r'''\noindent
\begin{tabular*}{0.74\textwidth}[t]{@{\extracolsep{\fill}}|c|r|rr|rr|rr|rr|}
\multicolumn{1}{c}{\normalsize{}} & \multicolumn{1}{c}{\normalsize{Aries}} &  \multicolumn{2}{c}{\normalsize{Venus}}& \multicolumn{2}{c}{\normalsize{Mars}} & \multicolumn{2}{c}{\normalsize{Jupiter}} & \multicolumn{2}{c}{\normalsize{Saturn}}\\
'''
    # note: 74% table width above removes "Overfull \hbox (1.65279pt too wide)"
    n = 0
    while n < 3:
        tab = tab + r'''\hline
\rule{{0pt}}{{2.4ex}}\textbf{{{}}} & \multicolumn{{1}}{{c|}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c|}}{{\textbf{{Dec}}}} & \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c|}}{{\textbf{{Dec}}}} & \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c|}}{{\textbf{{Dec}}}} & \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c|}}{{\textbf{{Dec}}}}\\
\hline\rule{{0pt}}{{2.6ex}}\noindent
'''.format(date.strftime("%a"))
        aGHA             = ariesGHA(date)
        vGHA, vDEC, vDEG = venusGHA(date)
        mGHA, mDEC, mDEG = marsGHA(date)
        jGHA, jDEC, jDEG = jupiterGHA(date)
        sGHA, sDEC, sDEG = saturnGHA(date)
        h = 0

        if config.decf != '+':	# USNO format for Declination
            while h < 24:
                if h > 0:
                    prevDECv = vDEG[h-1]
                    prevDECm = mDEG[h-1]
                    prevDECj = jDEG[h-1]
                    prevDECs = sDEG[h-1]
                else:
                    prevDECv = vDEG[0]		# hour -1 = hour 0
                    prevDECm = mDEG[0]		# hour -1 = hour 0
                    prevDECj = jDEG[0]		# hour -1 = hour 0
                    prevDECs = sDEG[0]		# hour -1 = hour 0
                if h < 23:
                    nextDECv = vDEG[h+1]
                    nextDECm = mDEG[h+1]
                    nextDECj = jDEG[h+1]
                    nextDECs = sDEG[h+1]
                else:
                    nextDECv = vDEG[23]	    # hour 24 = hour 23
                    nextDECm = mDEG[23]	    # hour 24 = hour 23
                    nextDECj = jDEG[23]	    # hour 24 = hour 23
                    nextDECs = sDEG[23]	    # hour 24 = hour 23

                # format declination checking for hemisphere change
                printNS, printDEG = declCompare(prevDECv,vDEG[h],nextDECv,h)
                vdec = NSdecl(vDEC[h],h,printNS,printDEG,False)

                printNS, printDEG = declCompare(prevDECm,mDEG[h],nextDECm,h)
                mdec = NSdecl(mDEC[h],h,printNS,printDEG,False)

                printNS, printDEG = declCompare(prevDECj,jDEG[h],nextDECj,h)
                jdec = NSdecl(jDEC[h],h,printNS,printDEG,False)

                printNS, printDEG = declCompare(prevDECs,sDEG[h],nextDECs,h)
                sdec = NSdecl(sDEC[h],h,printNS,printDEG,False)

                line = "{} & {} & {} & {} & {} & {} & {} & {} & {} & {}".format(h,aGHA[h],vGHA[h],vdec,mGHA[h],mdec,jGHA[h],jdec,sGHA[h],sdec)
                lineterminator = r'''\\
'''
                if h < 23 and (h+1)%6 == 0:
                    lineterminator = r'''\\[2Pt]
'''
                tab = tab + line + lineterminator
                h += 1

        else:			# Positive/Negative Declinations
            while h < 24:
                line = r'''{} & {} & {} & {} & {} & {} & {} & {} & {} & {}'''.format(h,aGHA[h],vGHA[h],vDEC[h],mGHA[h],mDEC[h],jGHA[h],jDEC[h],sGHA[h],sDEC[h])
                lineterminator = r'''\\
'''
                if h < 23 and (h+1)%6 == 0:
                    lineterminator = r'''\\[2Pt]
'''
                tab = tab + line + lineterminator
                h += 1

        RAc_v, Dc_v = vdm_Venus(date)
        RAc_m, Dc_m = vdm_Mars(date)
        RAc_j, Dc_j = vdm_Jupiter(date)
        RAc_s, Dc_s = vdm_Saturn(date)
        mag_v, mag_m, mag_j, mag_s = magnitudes(date)
        tab = tab + r'''\hline
\multicolumn{{2}}{{|c|}}{{\rule{{0pt}}{{2.4ex}}Mer.pass.:{}}} & \multicolumn{{2}}{{c|}}{{v{} d{} m{}}} & \multicolumn{{2}}{{c|}}{{v{} d{} m{}}} & \multicolumn{{2}}{{c|}}{{v{} d{} m{}}} & \multicolumn{{2}}{{c|}}{{v{} d{} m{}}}\\
\hline
\multicolumn{{10}}{{c}}{{}}\\
'''.format(ariestransit(date+datetime.timedelta(days=1)),RAc_v,Dc_v,mag_v,RAc_m,Dc_m,mag_m,RAc_j,Dc_j,mag_j,RAc_s,Dc_s,mag_s)
        n += 1
        date += datetime.timedelta(days=1)
    tab = tab + r'''\end{tabular*}
'''
    return tab


def planetstabm(date):
    # generates a LaTeX table for the navigational plantets (modern style)
    tab = r'''\vspace{6Pt}\noindent
\renewcommand{\arraystretch}{1.1}
\setlength{\tabcolsep}{4pt}
\begin{tabular}[t]{crcrrcrrcrrcrr}
\multicolumn{1}{c}{\normalsize{h}} & 
\multicolumn{1}{c}{\normalsize{Aries}} & & 
\multicolumn{2}{c}{\normalsize{Venus}}& & 
\multicolumn{2}{c}{\normalsize{Mars}} & & 
\multicolumn{2}{c}{\normalsize{Jupiter}} & & 
\multicolumn{2}{c}{\normalsize{Saturn}}\\
\cmidrule{2-2} \cmidrule{4-5} \cmidrule{7-8} \cmidrule{10-11} \cmidrule{13-14}'''
    n = 0
    while n < 3:
        tab = tab + r'''
\multicolumn{{1}}{{c}}{{\textbf{{{}}}}} & \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} && 
\multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c}}{{\textbf{{Dec}}}} &&  \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c}}{{\textbf{{Dec}}}} &&  \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c}}{{\textbf{{Dec}}}} &&  \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c}}{{\textbf{{Dec}}}}\\
'''.format(date.strftime("%a"))
        aGHA             = ariesGHA(date)
        vGHA, vDEC, vDEG = venusGHA(date)
        mGHA, mDEC, mDEG = marsGHA(date)
        jGHA, jDEC, jDEG = jupiterGHA(date)
        sGHA, sDEC, sDEG = saturnGHA(date)

        h = 0

        if config.decf != '+':	# USNO format for Declination
            while h < 24:
                band = int(h/6)
                group = band % 2
                if h > 0:
                    prevDECv = vDEG[h-1]
                    prevDECm = mDEG[h-1]
                    prevDECj = jDEG[h-1]
                    prevDECs = sDEG[h-1]
                else:
                    prevDECv = vDEG[0]		# hour -1 = hour 0
                    prevDECm = mDEG[0]		# hour -1 = hour 0
                    prevDECj = jDEG[0]		# hour -1 = hour 0
                    prevDECs = sDEG[0]		# hour -1 = hour 0
                if h < 23:
                    nextDECv = vDEG[h+1]
                    nextDECm = mDEG[h+1]
                    nextDECj = jDEG[h+1]
                    nextDECs = sDEG[h+1]
                else:
                    nextDECv = vDEG[23]	    # hour 24 = hour 23
                    nextDECm = mDEG[23]	    # hour 24 = hour 23
                    nextDECj = jDEG[23]	    # hour 24 = hour 23
                    nextDECs = sDEG[23]	    # hour 24 = hour 23

                # format declination checking for hemisphere change
                printNS, printDEG = declCompare(prevDECv,vDEG[h],nextDECv,h)
                vdec = NSdecl(vDEC[h],h,printNS,printDEG,True)

                printNS, printDEG = declCompare(prevDECm,mDEG[h],nextDECm,h)
                mdec = NSdecl(mDEC[h],h,printNS,printDEG,True)

                printNS, printDEG = declCompare(prevDECj,jDEG[h],nextDECj,h)
                jdec = NSdecl(jDEC[h],h,printNS,printDEG,True)

                printNS, printDEG = declCompare(prevDECs,sDEG[h],nextDECs,h)
                sdec = NSdecl(sDEC[h],h,printNS,printDEG,True)

                line = r'''\color{{blue}}{{{}}} & '''.format(h)
                line = line + r'''{} && {} & {} && {} & {} && {} & {} && {} & {} \\
'''.format(aGHA[h],vGHA[h],vdec,mGHA[h],mdec,jGHA[h],jdec,sGHA[h],sdec)
                if group == 1:
                    tab = tab + r'''\rowcolor{LightCyan}
'''
                tab = tab + line
                h += 1

        else:			# Positive/Negative Declinations
            while h < 24:
                band = int(h/6)
                group = band % 2
                line = r'''\color{{blue}}{{{}}} & '''.format(h)
                line = line + r'''{} && {} & {} && {} & {} && {} & {} && {} & {} \\
'''.format(aGHA[h],vGHA[h],vDEC[h],mGHA[h],mDEC[h],jGHA[h],jDEC[h],sGHA[h],sDEC[h])
                if group == 1:
                    tab = tab + r'''\rowcolor{LightCyan}
'''
                tab = tab + line
                h += 1

        RAc_v, Dc_v = vdm_Venus(date)
        RAc_m, Dc_m = vdm_Mars(date)
        RAc_j, Dc_j = vdm_Jupiter(date)
        RAc_s, Dc_s = vdm_Saturn(date)
        mag_v, mag_m, mag_j, mag_s = magnitudes(date)
        tab = tab + r'''\cmidrule{{1-2}} \cmidrule{{4-5}} \cmidrule{{7-8}} \cmidrule{{10-11}} \cmidrule{{13-14}}
\multicolumn{{2}}{{c}}{{\footnotesize{{Mer.pass.:{}}}}} && 
\multicolumn{{2}}{{c}}{{\footnotesize{{v{} d{} m{}}}}} && 
\multicolumn{{2}}{{c}}{{\footnotesize{{v{} d{} m{}}}}} && 
\multicolumn{{2}}{{c}}{{\footnotesize{{v{} d{} m{}}}}} && 
\multicolumn{{2}}{{c}}{{\footnotesize{{v{} d{} m{}}}}}\\
\cmidrule{{1-2}} \cmidrule{{4-5}} \cmidrule{{7-8}} \cmidrule{{10-11}} \cmidrule{{13-14}}
'''.format(ariestransit(date+datetime.timedelta(days=1)),RAc_v,Dc_v,mag_v,RAc_m,Dc_m,mag_m,RAc_j,Dc_j,mag_j,RAc_s,Dc_s,mag_s)
        if n < 2:
            vsep = ""
            if config.pgsz == "Letter":
                vsep = "[-2.0ex]"
            # add space between tables...
            tab = tab + r'''\multicolumn{{10}}{{c}}{{}}\\{}'''.format(vsep)
        n += 1
        date += datetime.timedelta(days=1)

    tab = tab+r'''\end{tabular}\quad
'''
    return tab


def starstab(date):
    # returns a table with ephemerieds for the navigational stars
    out = r'''\begin{tabular*}{0.251\textwidth}[t]{@{\extracolsep{\fill}}|rrr|}
\multicolumn{3}{c}{\normalsize{Stars}}\\
'''
    # note: 0.251 instead of 0.25 (above) prevents an "Overfull \hbox (0.14297pt too wide)" message on about 5 specific pages in the full year (moonimg=True)

    if config.tbls == "m":
        out = out + r'''\hline
& \multicolumn{1}{c}{\multirow{2}{*}{\textbf{SHA}}} 
& \multicolumn{1}{c|}{\multirow{2}{*}{\textbf{Dec}}}\\
& & \multicolumn{1}{c|}{} \\
'''
    else:
        out = out + r'''\hline
\rule{0pt}{2.4ex} & \multicolumn{1}{c}{\textbf{SHA}} & \multicolumn{1}{c|}{\textbf{Dec}}\\
\hline\rule{0pt}{2.6ex}\noindent
'''
    stars = stellar_info(date + datetime.timedelta(days=1))
    for i in range(len(stars)):
        out = out + r'''{} & {} & {} \\
'''.format(stars[i][0],stars[i][1],stars[i][2])
    m = r'''\hline
'''

    # returns 3 tables with SHA & Mer.pass for Venus, Mars, Jupiter and Saturn
    for i in range(3):
        dt = date + datetime.timedelta(days=i)
        datestr = r'''{} {} {}'''.format(dt.strftime("%b"), dt.strftime("%d"), dt.strftime("%a"))
        m = m + '''\hline
'''
        if config.tbls == "m":
            m = m + r'''& & \multicolumn{{1}}{{r|}}{{}}\\[-2.0ex]
\multicolumn{{1}}{{|r}}{{\textbf{{{}}}}} 
& \multicolumn{{1}}{{c}}{{\textbf{{SHA}}}} 
& \multicolumn{{1}}{{r|}}{{\textbf{{Mer.pass}}}}\\
'''.format(datestr)
        else:
            m = m + r'''& & \multicolumn{{1}}{{r|}}{{}}\\[-2.0ex]
\textbf{{{}}} & \textbf{{SHA}} & \textbf{{Mer.pass}}\\
'''.format(datestr)
        datex = date + datetime.timedelta(days=i)
        p = planetstransit(datex)
        m = m + r'''Venus & {} & {} \\
'''.format(p[0],p[1])
        m = m + r'''Mars & {} & {} \\
'''.format(p[2],p[3])
        m = m + r'''Jupiter & {} & {} \\
'''.format(p[4],p[5])
        m = m + r'''Saturn & {} & {} \\
'''.format(p[6],p[7])
        m = m + r'''\hline
'''
    out = out + m

    # returns a table with Horizontal parallax for Venus and Mars
    hp = r'''\hline
'''
    hp = hp + r'''& & \multicolumn{1}{r|}{}\\[-2.5ex]
\multicolumn{2}{|r}{\rule{0pt}{2.6ex}\textbf{Horizontal parallax}} & \multicolumn{1}{c|}{}\\
'''
    hp = hp + r'''\multicolumn{{2}}{{|r}}{{Venus:}} & \multicolumn{{1}}{{c|}}{{{}}} \\
'''.format(p[9])
    hp = hp + r'''\multicolumn{{2}}{{|r}}{{Mars:}} & \multicolumn{{1}}{{c|}}{{{}}} \\
'''.format(p[8])
    hp = hp + r'''\hline
'''
    out = out + hp
    
    out = out + r'''\end{tabular*}'''
    return out


def buildUPlists(n, ghaSoD, ghaPerHour, ghaEoD):
    # build list of hourly GHA values with modified start and end time to
    #  account for rounding times to the minute where 23:59:>30 rounds up
    #  00:00 the next day.
    UpperLists[n] = [-1.0 for x in range(25)]
    UpperLists[n][0] = ghaSoD
    for i in range(23):
        UpperLists[n][i+1] = ghaPerHour[i+1]
    UpperLists[n][24] = ghaEoD
    return

def buildLOWlists(n, ghaSoD, ghaPerHour, ghaEoD):
    # build list of hourly GHA colong values with modified start and end
    #   time to account for rounding times to the minute where 23:59:>30
    #   rounds up 00:00 the next day.
    LowerLists[n] = [-1.0 for x in range(25)]
    LowerLists[n][0] = GHAcolong(ghaSoD)
    for i in range(23):
        LowerLists[n][i+1] = GHAcolong(ghaPerHour[i+1])
    LowerLists[n][24] = GHAcolong(ghaEoD)
    return

def GHAcolong(gha):
    # return the colongitude, e.g. 270° returns 90° and 90° returns 270°
    coGHA = gha + 180
    while coGHA > 360:
        coGHA = coGHA - 360
    return coGHA

def sunmoontab(date):
    # generates LaTeX table for sun and moon (traditional style)
    tab = r'''\noindent
\begin{tabular*}{0.54\textwidth}[t]{@{\extracolsep{\fill}}|c|rr|rrrrr|}
\multicolumn{1}{c}{\normalsize{h}}& \multicolumn{2}{c}{\normalsize{Sun}} & \multicolumn{5}{c}{\normalsize{Moon}}\\
'''
    # note: 54% table width above removes "Overfull \hbox (1.65279pt too wide)"
    #                 and "Underfull \hbox (badness 10000)"
    n = 0
    while n < 3:
        tab = tab + r'''\hline
\multicolumn{{1}}{{|c|}}{{\rule{{0pt}}{{2.6ex}}\textbf{{{}}}}} &\multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c|}}{{\textbf{{Dec}}}}  & \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c}}{{\textbf{{\(\nu\)}}}} & \multicolumn{{1}}{{c}}{{\textbf{{Dec}}}} & \multicolumn{{1}}{{c}}{{\textbf{{d}}}} & \multicolumn{{1}}{{c|}}{{\textbf{{HP}}}}\\
\hline\rule{{0pt}}{{2.6ex}}\noindent
'''.format(date.strftime("%a"))

        date0 = date - datetime.timedelta(days=1)
        ghas, decs, degs = sunGHA(date)
        gham, decm, degm, HPm, GHAupper, GHAlower, ghaSoD, ghaEoD = moonGHA(date)
        vmin, dmin = moonVD(date0,date)

        buildUPlists(n, ghaSoD, GHAupper, ghaEoD)
        buildLOWlists(n, ghaSoD, GHAupper, ghaEoD)

        h = 0
        if config.decf != '+':	# USNO format for Declination
            mlastNS = ''
            while h < 24:
                if h > 0:
                    prevDEC = degs[h-1]
                else:
                    prevDEC = degs[0]		# hour -1 = hour 0
                if h < 23:
                    nextDEC = degs[h+1]
                else:
                    nextDEC = degs[23]	# hour 24 = hour 23
                
                # format declination checking for hemisphere change
                printNS, printDEG = declCompare(prevDEC,degs[h],nextDEC,h)
                sdec = NSdecl(decs[h],h,printNS,printDEG,False)

                mdec, mNS = NSdeg(decm[h],False,h)
                if h < 23:
                    if mNS != mlastNS or math.copysign(1.0,degm[h]) != math.copysign(1.0,degm[h+1]):
                        mdec, mNS = NSdeg(decm[h],False,h,True)	# force N/S
                mlastNS = mNS

                line = r'''{} & {} & {} & {} & {} & {} & {} & {}'''.format(h,ghas[h],sdec,gham[h],vmin[h],mdec,dmin[h],HPm[h])
                lineterminator = r'''\\
'''
                if h < 23 and (h+1)%6 == 0:
                    lineterminator = r'''\\[2Pt]
'''
                tab = tab + line + lineterminator
                h += 1

        else:			# Positive/Negative Declinations
            while h < 24:
                line = r'''{} & {} & {} & {} & {} & {} & {} & {}'''.format(h,ghas[h],decs[h],gham[h],vmin[h],decm[h],dmin[h],HPm[h])
                lineterminator = r'''\\
'''
                if h < 23 and (h+1)%6 == 0:
                    lineterminator = r'''\\[2Pt]
'''
                tab = tab + line + lineterminator
                h += 1
                
        sds, dsm = sunSD(date)
        sdmm = moonSD(date)
        tab = tab + r'''\hline
\rule{{0pt}}{{2.4ex}} & \multicolumn{{1}}{{c}}{{SD.={}}} & \multicolumn{{1}}{{c|}}{{d={}}} & \multicolumn{{5}}{{c|}}{{S.D.={}}}\\
\hline
'''.format(sds,dsm,sdmm)
        if n < 2:
            # add space between tables...
            tab = tab + r'''\multicolumn{7}{c}{}\\[-1.5ex]'''
        n += 1
        date += datetime.timedelta(days=1)
    tab = tab + r'''\end{tabular*}'''
    return tab


def sunmoontabm(date):
    # generates LaTeX table for sun and moon (modern style)
    tab = r'''\noindent
\renewcommand{\arraystretch}{1.1}
\setlength{\tabcolsep}{4pt}
\quad\quad
\begin{tabular}[t]{crrcrrrrr}
\multicolumn{1}{c}{\normalsize{h}} & 
\multicolumn{2}{c}{\normalsize{Sun}} & &
\multicolumn{5}{c}{\normalsize{Moon}}\\
\cmidrule{2-3} \cmidrule{5-9}'''
    # note: \quad\quad above shifts all tables to the right (still within margins)
    n = 0
    while n < 3:
        tab = tab + r'''
\multicolumn{{1}}{{c}}{{\textbf{{{}}}}} & \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c}}{{\textbf{{Dec}}}} & & \multicolumn{{1}}{{c}}{{\textbf{{GHA}}}} & \multicolumn{{1}}{{c}}{{\textbf{{\(\nu\)}}}} & \multicolumn{{1}}{{c}}{{\textbf{{Dec}}}} & \multicolumn{{1}}{{c}}{{\textbf{{d}}}} & \multicolumn{{1}}{{c}}{{\textbf{{HP}}}}\\
'''.format(date.strftime("%a"))

        date0 = date - datetime.timedelta(days=1)
        ghas, decs, degs = sunGHA(date)
        gham, decm, degm, HPm, GHAupper, GHAlower, ghaSoD, ghaEoD = moonGHA(date)
        vmin, dmin = moonVD(date0,date)

        buildUPlists(n, ghaSoD, GHAupper, ghaEoD)
        buildLOWlists(n, ghaSoD, GHAupper, ghaEoD)

        h = 0
        if config.decf != '+':	# USNO format for Declination
            mlastNS = ''
            while h < 24:
                band = int(h/6)
                group = band % 2
                if h > 0:
                    prevDEC = degs[h-1]
                else:
                    prevDEC = degs[0]		# hour -1 = hour 0
                if h < 23:
                    nextDEC = degs[h+1]
                else:
                    nextDEC = degs[23]	# hour 24 = hour 23
                
                # format declination checking for hemisphere change
                printNS, printDEG = declCompare(prevDEC,degs[h],nextDEC,h)
                sdec = NSdecl(decs[h],h,printNS,printDEG,True)

                mdec, mNS = NSdeg(decm[h],True,h)
                if h < 23:
                    if mNS != mlastNS or math.copysign(1.0,degm[h]) != math.copysign(1.0,degm[h+1]):
                        mdec, mNS = NSdeg(decm[h],True,h,True)	# force NS
                mlastNS = mNS

                line = r'''\color{{blue}}{{{}}} & '''.format(h)
                line = line + r'''{} & {} && {} & {} & {} & {} & {} \\
'''.format(ghas[h],sdec,gham[h],vmin[h],mdec,dmin[h],HPm[h])

                if group == 1:
                    tab = tab + r'''\rowcolor{LightCyan}
'''
                tab = tab + line
                h += 1

        else:			# Positive/Negative Declinations
            while h < 24:
                band = int(h/6)
                group = band % 2
                line = r'''\color{{blue}}{{{}}} & '''.format(h)
                line = line + r'''{} & {} && {} & {} & {} & {} & {} \\
'''.format(ghas[h],decs[h],gham[h],vmin[h],decm[h],dmin[h],HPm[h])
                if group == 1:
                    tab = tab + r'''\rowcolor{LightCyan}
'''
                tab = tab + line
                h += 1

        sds, dsm = sunSD(date)
        sdmm = moonSD(date)
        tab = tab + r'''\cmidrule{{2-3}} \cmidrule{{5-9}}
\multicolumn{{1}}{{c}}{{}} & \multicolumn{{1}}{{c}}{{\footnotesize{{SD.={}}}}} & 
\multicolumn{{1}}{{c}}{{\footnotesize{{d={}}}}} && \multicolumn{{5}}{{c}}{{\footnotesize{{S.D.={}}}}}\\
\cmidrule{{2-3}} \cmidrule{{5-9}}
'''.format(sds,dsm,sdmm)
        if n < 2:
            vsep = "[-1.5ex]"
            if config.pgsz == "Letter":
                vsep = "[-2.0ex]"
            # add space between tables...
            tab = tab + r'''\multicolumn{{7}}{{c}}{{}}\\{}'''.format(vsep)
        n += 1
        date += datetime.timedelta(days=1)
    tab = tab + r'''\end{tabular}
\quad\quad'''
    return tab


def declCompare(prev_deg, curr_deg, next_deg, hr):
    # for Declinations only...
    # decide if to print N/S; decide if to print degrees
    # note: the first three arguments are declinations in degrees (float)
    prNS = False
    prDEG = False
    psign = math.copysign(1.0,prev_deg)
    csign = math.copysign(1.0,curr_deg)
    nsign = math.copysign(1.0,next_deg)
    pdeg = abs(prev_deg)
    cdeg = abs(curr_deg)
    ndeg = abs(next_deg)
    pdegi = int(pdeg)
    cdegi = int(cdeg)
    ndegi = int(ndeg)
    pmin = round((pdeg-pdegi)*60, 1)	# minutes (float), rounded to 1 decimal place
    cmin = round((cdeg-cdegi)*60, 1)	# minutes (float), rounded to 1 decimal place
    nmin = round((ndeg-ndegi)*60, 1)	# minutes (float), rounded to 1 decimal place
    pmini = int(pmin)
    cmini = int(cmin)
    nmini = int(nmin)
    if pmini == 60:
        pmin -= 60
        pdegi += 1
    if cmini == 60:
        cmin -= 60
        cdegi += 1
    if nmini == 60:
        nmin -= 60
        ndegi += 1
    # now we have the values in degrees+minutes as printed

    if hr%6 == 0:
        prNS = True			# print N/S for hour = 0, 6, 12, 18
    else:
        if psign != csign:
            prNS = True		# print N/S if previous sign different
    if hr < 23:
        if csign != nsign:
            prNS = True		# print N/S if next sign different
    if prNS == False:
        if pdegi != cdegi:
            prDEG = True	# print degrees if changed since previous value
        if cdegi != ndegi:
            prDEG = True	# print degrees if next value is changed
    else:
        prDEG= True			# print degrees is N/S to be printed
    return prNS, prDEG


def NSdecl(deg, hr, printNS, printDEG, modernFMT):
    # reformat degrees latitude to Ndd°mm.m or Sdd°mm.m
    if deg[0:1] == '-':
        hemisph = 'S'
        deg = deg[1:]
    else:
        hemisph = 'N'
    if not(printDEG):
        deg = deg[10:]	# skip the degrees (always dd°mm.m) - note: the degree symbol '$^\circ$' is eight bytes long
        if (hr+3)%6 == 0:
            deg = r'''\raisebox{0.24ex}{\boldmath$\cdot$~\boldmath$\cdot$~~}''' + deg
    if modernFMT:
        if printNS or hr%6 == 0:
            sdeg = r'''\textcolor{{blue}}{{{}}}'''.format(hemisph) + deg
        else:
            sdeg = deg
    else:
        if printNS or hr%6 == 0:
            sdeg = r'''\textbf{{{}}}'''.format(hemisph) + deg
        else:
            sdeg = deg
    #print("sdeg: ", sdeg)
    return sdeg


def NSdeg(deg, modern=False, hr=0, forceNS=False):
    # reformat degrees latitude to Ndd°mm.m or Sdd°mm.m
    if deg[0:1] == '-':
        hemisph = 'S'
        deg = deg[1:]
    else:
        hemisph = 'N'
    if modern:
        if forceNS or hr%6 == 0:
            sdeg = r'''\textcolor{{blue}}{{{}}}'''.format(hemisph) + deg
        else:
            sdeg = deg
    else:
        if forceNS or hr%6 == 0:
            sdeg = r'''\textbf{{{}}}'''.format(hemisph) + deg
        else:
            sdeg = deg
    return sdeg, hemisph


def twilighttab(date):
    # returns the twilight and moonrise tables, finally EoT data

# Twilight tables ...........................................
    #lat = [72,70,68,66,64,62,60,58,56,54,52,50,45,40,35,30,20,10,0, -10,-20,-30,-35,-40,-45,-50,-52,-54,-56,-58,-60]
    latNS = [72, 70, 58, 40, 10, -10, -50, -60]
    tab = r'''
\begin{tabular*}{0.45\textwidth}[t]{@{\extracolsep{\fill}}|r|ccc|ccc|}
\multicolumn{7}{c}{\normalsize{}}\\
'''

    if config.tbls == "m":
    # The header begins with a thin empty row as top padding; and the top row with
    # bold text has some padding below it. This result gives a balanced impression.
        tab = tab + r'''\hline
\multicolumn{1}{|c|}{} & & & \multicolumn{1}{|c|}{} & \multicolumn{1}{c|}{} & & \multicolumn{1}{c|}{}\\[-2.0ex]
\multicolumn{1}{|c|}{\multirow{2}{*}{\textbf{Lat.}}} & 
\multicolumn{2}{c}{\footnotesize{\textbf{Twilight}}} & 
\multicolumn{1}{|c|}{\multirow{2}{*}{\textbf{Sunrise}}} & 
\multicolumn{1}{c|}{\multirow{2}{*}{\textbf{Sunset}}} & 
\multicolumn{2}{c|}{\footnotesize{\textbf{Twilight}}}\\[0.6ex]
\multicolumn{1}{|c|}{} & 
\multicolumn{1}{c}{Naut.} & 
\multicolumn{1}{c}{Civil} & 
\multicolumn{1}{|c|}{} & 
\multicolumn{1}{c|}{} & 
\multicolumn{1}{c}{Civil} & 
\multicolumn{1}{c|}{Naut.}\\
\hline\rule{0pt}{2.6ex}\noindent
'''
    else:
        tab = tab + r'''\hline
\multicolumn{1}{|c|}{\rule{0pt}{2.4ex}\multirow{2}{*}{\textbf{Lat.}}} & 
\multicolumn{2}{c}{\textbf{Twilight}} & 
\multicolumn{1}{|c|}{\multirow{2}{*}{\textbf{Sunrise}}} & 
\multicolumn{1}{c|}{\multirow{2}{*}{\textbf{Sunset}}} & 
\multicolumn{2}{c|}{\textbf{Twilight}}\\
\multicolumn{1}{|c|}{} & 
\multicolumn{1}{c}{Naut.} & 
\multicolumn{1}{c}{Civil} & 
\multicolumn{1}{|c|}{} & 
\multicolumn{1}{c|}{} & 
\multicolumn{1}{c}{Civil} & 
\multicolumn{1}{c|}{Naut.}\\
\hline\rule{0pt}{2.6ex}\noindent
'''
    lasthemisph = ""
    j = 5
    for i in config.lat:
        if i >= 0:
            hemisph = 'N'
        else:
            hemisph = 'S'
        if not(i in latNS):
            hs = ""
        else:
            hs = hemisph
            if j%6 == 0:
                tab = tab + r'''\rule{0pt}{2.6ex}
'''
        lasthemisph = hemisph
        # day+1 to calculate for the second day (three days are printed on one page)
        twi = twilight(date+datetime.timedelta(days=1), i, hemisph)
        line = r'''\textbf{{{}}}'''.format(hs) + " " + r'''{}$^\circ$'''.format(abs(i))
        line = line + r''' & {} & {} & {} & {} & {} & {} \\
'''.format(twi[0],twi[1],twi[2],twi[3],twi[4],twi[5])
        tab = tab + line
        j += 1
    # add space between tables...
    tab = tab + r'''\hline\multicolumn{7}{c}{}\\[-1.5ex]
'''

# Moonrise & Moonset ...........................................
    if config.tbls == "m":
        tab = tab + r'''\hline
\multicolumn{1}{|c|}{} & & & \multicolumn{1}{c|}{} & & & \multicolumn{1}{c|}{}\\[-2.0ex]
\multicolumn{1}{|c|}{\multirow{2}{*}{\textbf{Lat.}}} & 
\multicolumn{3}{c|}{\footnotesize{\textbf{Moonrise}}} & 
\multicolumn{3}{c|}{\footnotesize{\textbf{Moonset}}}\\[0.6ex]
'''
    else:
        tab = tab + r'''\hline
\multicolumn{1}{|c|}{\rule{0pt}{2.4ex}\multirow{2}{*}{\textbf{Lat.}}} & 
\multicolumn{3}{c|}{\textbf{Moonrise}} & 
\multicolumn{3}{c|}{\textbf{Moonset}}\\
'''

    weekday = [date.strftime("%a"),(date+datetime.timedelta(days=1)).strftime("%a"),(date+datetime.timedelta(days=2)).strftime("%a")]
    tab = tab + r'''\multicolumn{{1}}{{|c|}}{{}} & 
\multicolumn{{1}}{{c}}{{{}}} & 
\multicolumn{{1}}{{c}}{{{}}} & 
\multicolumn{{1}}{{c|}}{{{}}} & 
\multicolumn{{1}}{{c}}{{{}}} & 
\multicolumn{{1}}{{c}}{{{}}} & 
\multicolumn{{1}}{{c|}}{{{}}} \\
\hline\rule{{0pt}}{{2.6ex}}\noindent
'''.format(weekday[0],weekday[1],weekday[2],weekday[0],weekday[1],weekday[2])

    moon = [0,0,0,0,0,0]
    moon2 = [0,0,0,0,0,0]
    lasthemisph = ""
    j = 5
    for i in config.lat:
        if i >= 0:
            hemisph = 'N'
        else:
            hemisph = 'S'
        if not(i in latNS):
            hs = ""
        else:
            hs = hemisph
            if j%6 == 0:
                tab = tab + r'''\rule{0pt}{2.6ex}
'''
        lasthemisph = hemisph
        moon, moon2 = moonrise_set(date,i,hemisph)
        if not(double_events_found(moon,moon2)):
            tab = tab + r'''\textbf{{{}}}'''.format(hs) + " " + r'''{}$^\circ$'''.format(abs(i))
            tab = tab + r''' & {} & {} & {} & {} & {} & {} \\
'''.format(moon[0],moon[1],moon[2],moon[3],moon[4],moon[5])
        else:
# print a row with two moonrise/moonset events on the same day & latitude
            tab = tab + r'''\multirow{{2}}{{*}}{{\textbf{{{}}} {}$^\circ$}}'''.format(hs,abs(i))
# top row...
            for k in range(len(moon)):
                if moon2[k] != '--:--':
                    tab = tab + r''' & {}'''.format(moon[k])
                else:
                    tab = tab + r''' & \multirow{{2}}{{*}}{{{}}}'''.format(moon[k])
            tab = tab + r'''\\'''	# terminate top row
# bottom row...
            for k in range(len(moon)):
                if moon2[k] != '--:--':
                    tab = tab + r''' & {}'''.format(moon2[k])
                else:
                    tab = tab + r'''&'''
            tab = tab + r'''\\'''	# terminate bottom row
        j += 1
    # add space between tables...
    tab = tab + r'''\hline\multicolumn{7}{c}{}\\[-1.5ex]
'''

# Equation of Time section ...........................................
    #------------------  if moon image displayed... ------------------
    if config.moonimg:
        d = date
        d1 = d + datetime.timedelta(days=1)
        d2 = d + datetime.timedelta(days=2)
        d3 = d + datetime.timedelta(days=3)
        age0, pct0 = moonage(d, d1)
        phase = moonphase(d1)       # moon phase (0:new to π:full to 2π:new)
        age2, pct2 = moonage(d2, d3)
        ages = '{}-{}'.format(age0,age2)
        pcts = '{}-{}\%'.format(pct0,pct2)

        if config.tbls == "m":
            tab = tab + r'''\hline
\multicolumn{1}{|c|}{} & & & \multicolumn{1}{c|}{} & & & \multicolumn{1}{c|}{}\\[-2.0ex]
\multicolumn{1}{|c|}{\multirow{4}{*}{\footnotesize{\textbf{Day}}}} & 
\multicolumn{3}{c|}{\footnotesize{\textbf{Sun}}} & 
\multicolumn{3}{c|}{\footnotesize{\textbf{Moon}}}\\[0.6ex]
\multicolumn{1}{|c|}{} & \multicolumn{2}{c}{Eqn.of Time} & \multicolumn{1}{|c|}{Mer.} & \multicolumn{2}{c}{Mer.Pass.} & \multicolumn{1}{|c|}{Age}\\
'''

            tab = tab + r'''\multicolumn{1}{|c|}{} &\multicolumn{1}{c}{00\textsuperscript{h}} & 
\multicolumn{1}{c}{12\textsuperscript{h}} & \multicolumn{1}{|c|}{Pass} & \multicolumn{1}{c}{Upper} & \multicolumn{1}{c}{Lower} & '''
            tab = tab + r'''\multicolumn{{1}}{{|c|}}{{{}}}\\
'''.format(ages)
            
            tab = tab + r'''\multicolumn{1}{|c|}{} &\multicolumn{1}{c}{mm:ss} & 
\multicolumn{1}{c}{mm:ss} & \multicolumn{1}{|c|}{hh:mm} & \multicolumn{1}{c}{hh:mm} & \multicolumn{1}{c}{hh:mm} & '''
            tab = tab + r'''\multicolumn{{1}}{{|c|}}{{{}}}\\
\hline\rule{{0pt}}{{3.0ex}}\noindent
'''.format(pcts)

        else:
            tab = tab + r'''\hline
\multicolumn{1}{|c|}{\rule{0pt}{2.4ex}\multirow{4}{*}{\textbf{Day}}} & 
\multicolumn{3}{c|}{\textbf{Sun}} & \multicolumn{3}{c|}{\textbf{Moon}}\\
\multicolumn{1}{|c|}{} & \multicolumn{2}{c}{Eqn.of Time} & \multicolumn{1}{|c|}{Mer.} & \multicolumn{2}{c}{Mer.Pass.} & \multicolumn{1}{|c|}{Age}\\
\multicolumn{1}{|c|}{} & \multicolumn{1}{c}{00\textsuperscript{h}} & \multicolumn{1}{c}{12\textsuperscript{h}} & \multicolumn{1}{|c|}{Pass} & \multicolumn{1}{c}{Upper} & \multicolumn{1}{c}{Lower} & '''
            tab = tab + r'''\multicolumn{{1}}{{|c|}}{{{}}}\\
'''.format(ages)
            tab = tab + r'''\multicolumn{1}{|c|}{} & \multicolumn{1}{c}{mm:ss} & \multicolumn{1}{c}{mm:ss} & 
\multicolumn{1}{|c|}{hh:mm} & \multicolumn{1}{c}{hh:mm} & \multicolumn{1}{c}{hh:mm} & '''
            tab = tab + r'''\multicolumn{{1}}{{|c|}}{{{}}}\\
\hline\rule{{0pt}}{{3.0ex}}\noindent
'''.format(pcts)

        d = date
        for k in range(3):
            eq = equation_of_time(d,d + datetime.timedelta(days=1),UpperLists[k],LowerLists[k], False)
            if k == 0:
                tab = tab + r'''%s & %s & %s & %s & %s & %s & ''' %(d.strftime("%d"),eq[0],eq[1],eq[2],eq[3],eq[4])
                tab = tab + lunatikz(phase)
            elif k == 1:
                tab = tab + r'''{} & {} & {} & {} & {} & {} & \multicolumn{{1}}{{|c|}}{{}}\\
'''.format(d.strftime("%d"),eq[0],eq[1],eq[2],eq[3],eq[4])
            else:
                tab = tab + r'''{} & {} & {} & {} & {} & {} & \multicolumn{{1}}{{|c|}}{{}}\\[0.3ex]
'''.format(d.strftime("%d"),eq[0],eq[1],eq[2],eq[3],eq[4])
            d += datetime.timedelta(days=1)
        tab = tab + r'''\hline
\end{tabular*}'''
    #-----------------  if no moon image displayed... -----------------
    else:
        if config.tbls == "m":
            tab = tab + r'''\hline
\multicolumn{1}{|c|}{} & & & \multicolumn{1}{c|}{} & & & \multicolumn{1}{c|}{}\\[-2.0ex]
\multicolumn{1}{|c|}{\multirow{4}{*}{\footnotesize{\textbf{Day}}}} & 
\multicolumn{3}{c|}{\footnotesize{\textbf{Sun}}} & 
\multicolumn{3}{c|}{\footnotesize{\textbf{Moon}}}\\[0.6ex]
\multicolumn{1}{|c|}{} & 
\multicolumn{2}{c}{Eqn.of Time} & 
\multicolumn{1}{|c|}{Mer.} & 
\multicolumn{2}{c}{Mer.Pass.} & 
\multicolumn{1}{|c|}{}\\
\multicolumn{1}{|c|}{} &\multicolumn{1}{c}{00\textsuperscript{h}} & \multicolumn{1}{c}{12\textsuperscript{h}} & \multicolumn{1}{|c|}{Pass} & \multicolumn{1}{c}{Upper} & \multicolumn{1}{c}{Lower} &\multicolumn{1}{|c|}{Age}\\
\multicolumn{1}{|c|}{} &\multicolumn{1}{c}{mm:ss} & \multicolumn{1}{c}{mm:ss} & \multicolumn{1}{|c|}{hh:mm} & \multicolumn{1}{c}{hh:mm} & \multicolumn{1}{c}{hh:mm} &\multicolumn{1}{|c|}{}\\
\hline\rule{0pt}{3.0ex}\noindent
'''
        else:
            tab = tab + r'''\hline
\multicolumn{1}{|c|}{\rule{0pt}{2.4ex}\multirow{4}{*}{\textbf{Day}}} & 
\multicolumn{3}{c|}{\textbf{Sun}} & \multicolumn{3}{c|}{\textbf{Moon}}\\
\multicolumn{1}{|c|}{} & \multicolumn{2}{c}{Eqn.of Time} & \multicolumn{1}{|c|}{Mer.} & \multicolumn{2}{c}{Mer.Pass.} & \multicolumn{1}{|c|}{}\\
\multicolumn{1}{|c|}{} & \multicolumn{1}{c}{00\textsuperscript{h}} & \multicolumn{1}{c}{12\textsuperscript{h}} & \multicolumn{1}{|c|}{Pass} & \multicolumn{1}{c}{Upper} & \multicolumn{1}{c}{Lower} &\multicolumn{1}{|c|}{Age}\\
\multicolumn{1}{|c|}{} & \multicolumn{1}{c}{mm:ss} & \multicolumn{1}{c}{mm:ss} & \multicolumn{1}{|c|}{hh:mm} & \multicolumn{1}{c}{hh:mm} & \multicolumn{1}{c}{hh:mm} &\multicolumn{1}{|c|}{}\\
\hline\rule{0pt}{3.0ex}\noindent
'''

        d = date
        for k in range(3):
            eq = equation_of_time(d,d + datetime.timedelta(days=1),UpperLists[k],LowerLists[k], True)
            if k == 2:
                tab = tab + r'''{} & {} & {} & {} & {} & {} & {}({}\%) \\[0.3ex]
'''.format(d.strftime("%d"),eq[0],eq[1],eq[2],eq[3],eq[4],eq[5],eq[6])
            else:
                tab = tab + r'''{} & {} & {} & {} & {} & {} & {}({}\%) \\
'''.format(d.strftime("%d"),eq[0],eq[1],eq[2],eq[3],eq[4],eq[5],eq[6])
            d += datetime.timedelta(days=1)
        tab = tab + r'''\hline
\end{tabular*}'''
    return tab


##NEW##
def lunatikz(phase):
    # argument: moon phase (0:new to π:full to 2π:new)
    # returns the code for a moon image overlaid with a shadow (pardon the function name)
    f      = 0.01     # empirical fudge factor to position moon's shadow exactly over image
    radius = 0.375    # moon image radius (cm)
    xstart = radius + f
    diam   = 0.75     # moon image diameter (cm)
    top    = diam + f # top of moon (cm)
    bottom = 0.0 + f  # bottom of moon (cm)
    if phase < math.pi*0.5:    # new moon to 1st quarter
        ystart = top
        fr_angle = 90           # trace a semicircle anticlockwise from top to bottom
        to_angle = 270
        ret_angle = -90         # trace an ellipse anticlockwise from bottom to top
        end_angle = 90
        xradius = math.cos(phase) * radius
    elif phase < math.pi:      # 1st quarter to full moon
        ystart = top
        fr_angle = 90           # trace a semicircle anticlockwise from top to bottom
        to_angle = 270
        ret_angle = 270         # trace an ellipse clockwise from bottom to top
        end_angle = 90
        xradius = abs(math.cos(phase)) * radius
    elif phase < math.pi*1.5:  # full moon to 3rd quarter
        ystart = bottom
        fr_angle = -90          # trace a semicircle anticlockwise from bottom to top
        to_angle = 90
        ret_angle = 90          # trace an ellipse clockwise from top to bottom
        end_angle = -90
        xradius = abs(math.cos(phase)) * radius
    else:                       # 3rd quarter to new moon
        ystart = bottom
        fr_angle = -90          # trace a semicircle anticlockwise from bottom to top
        to_angle = 90
        ret_angle = 90          # trace an ellipse anticlockwise from top to bottom
        end_angle = 270
        xradius = math.cos(phase) * radius

    tikz = r'''\multicolumn{{1}}{{|c|}}{{\multirow{{3}}{{*}}
{{\begin{{tikzpicture}}
\node[anchor=south west,inner sep=0] at (0,0) {{\includegraphics[width=0.75cm]{{croppedmoon.png}}}};
\path [fill=darknight, opacity=0.75] ({:5.3f},{:5.3f}) arc [x radius=0.375, y radius=0.375, start angle={:d}, end angle={:d}]  arc [x radius={:f}, y radius=0.375, start angle={:d}, end angle={:d}];
\end{{tikzpicture}}}}}}\\
'''.format(xstart, ystart, fr_angle, to_angle, xradius, ret_angle, end_angle)
    return tikz


def double_events_found(m1, m2):
    # check for two moonrise/moonset events on the same day & latitude
    dbl = False
    for i in range(len(m1)):
        if m2[i] != '--:--':
            dbl = True
    return dbl


def doublepage(date, page1):
    # creates a doublepage (3 days) of the nautical almanac

    # time delta values for the initial date&time...
    dut1, deltat = getParams(date)
    timedelta = r"DUT1 = UT1-UTC = {:+.4f} sec\quad$\Delta$T = TT-UT1 = {:+.4f} sec".format(dut1, deltat)

    find_new_moon(date)
    #import alma_skyfield
    #print("previous  new moon: {}".format(alma_skyfield.PreviousNewMoon))
    #print("previous full moon: {}".format(alma_skyfield.PreviousFullMoon))
    #print("next      new moon: {}".format(alma_skyfield.NextNewMoon))
    #print("next     full moon: {}".format(alma_skyfield.NextFullMoon))

    page = ''
    if not(page1):
        page = r'''
% ------------------ N E W   P A G E ------------------
\newpage'''

    leftindent = ""
    rightindent = ""
    if config.tbls == "m":
        leftindent = "\quad"
        rightindent = "\hphantom{\quad}"

    page = page + r'''
\sffamily
\noindent
{}\textbf{{{}, {}, {} UT ({}.,  {}.,  {}.)}}'''.format(leftindent,date.strftime("%B %d"),(date+datetime.timedelta(days=1)).strftime("%d"),(date+datetime.timedelta(days=2)).strftime("%d"),date.strftime("%a"),(date+datetime.timedelta(days=1)).strftime("%a"),(date+datetime.timedelta(days=2)).strftime("%a"))

    if config.tbls == "m":
        page = page + r'\par'
    else:
        page = page + r'\\[1.0ex]'

    page = page + r'''
\begin{scriptsize}
'''

    if config.tbls == "m":
        page = page + planetstabm(date)
    else:
        page = page + planetstab(date)
    page = page + starstab(date)
    str1 = r'''

\end{{scriptsize}}
% ------------------ N E W   P A G E ------------------
\newpage
\begin{{flushleft}}     % required so that \par works
{{\footnotesize {}}}\hfill\textbf{{{} to {} UT}}
\end{{flushleft}}\par
\begin{{scriptsize}}
'''.format(timedelta, date.strftime("%Y %B %d"),(date+datetime.timedelta(days=2)).strftime("%b. %d"),rightindent)
    page = page + str1
    if config.tbls == "m":
        page = page + sunmoontabm(date)
    else:
        page = page + sunmoontab(date)
    page = page + twilighttab(date)
    page = page + r'''

\end{scriptsize}'''
    # to avoid "Overfull \hbox" messages, always leave a paragraph end before the end of a size change. (See lines above)
    return page


def pages(first_day, p):
    # make 'p' doublepages beginning with first_day
    out = ''
    page1 = True
    pmth = ''
    for i in range(p):
        if p == 122:	# if Full Almanac for a year...
            cmth = first_day.strftime("%b ")
            if cmth != pmth:
                print		# progress indicator - next month
                print cmth,
            else:
                sys.stdout.write('.')	# progress indicator
                sys.stdout.flush()
            pmth = cmth
        out = out + doublepage(first_day,page1)
        page1 = False
        first_day += datetime.timedelta(days=3)
    if p == 122:	# if Full Almanac for a year...
        print		# newline to terminate progress indicator
    return out


def almanac(first_day, pagenum):

    # make almanac starting from first_day
    year = first_day.year
    mth = first_day.month
    day = first_day.day

    # page size specific parameters
    if config.pgsz == "A4":
        paper = "a4paper"
        vsep1 = "1.5cm"
        vsep2 = "1.0cm"
        tm1 = "21mm"    # title page...
        bm1 = "15mm"
        lm1 = "10mm"
        rm1 = "10mm"
        tm = "21mm"     # data pages...
        bm = "18mm"
        lm = "10mm"
        rm = "9mm"
        if config.tbls == "m":
            tm = "10mm"
            bm = "15mm"
            lm = "10mm"
            rm = "10mm"
    else:
        paper = "letterpaper"
        vsep1 = "0.8cm"
        vsep2 = "0.7cm"
        tm1 = "12mm"    # title page...
        bm1 = "15mm"
        lm1 = "12mm"
        rm1 = "12mm"
        tm = "12.2mm"   # data pages...
        bm = "13mm"
        lm = "15mm"
        rm = "11mm"
        if config.tbls == "m":
            tm = "4mm"
            bm = "10mm"
            lm = "13mm"
            rm = "13mm"

    alm = r'''\documentclass[10pt, twoside, {}]{{report}}
'''.format(paper)

    alm = alm + r'''
%\usepackage[utf8]{inputenc}
\usepackage[english]{babel}
\usepackage{fontenc}'''

    # to troubleshoot add "showframe, verbose," below:
    alm = alm + r'''
\usepackage[nomarginpar, top={}, bottom={}, left={}, right={}]{{geometry}}'''.format(tm,bm,lm,rm)

    if config.tbls == "m":
        alm = alm + r'''
\usepackage[table]{xcolor}
\definecolor{LightCyan}{rgb}{0.88,1,1}
\usepackage{booktabs}'''

    if config.moonimg:
            alm = alm + r'''
\usepackage[table]{xcolor}
\definecolor{darknight}{rgb}{0.18, 0.27, 0.33}'''

    # Note: \DeclareUnicodeCharacter is not compatible with some versions of pdflatex
    alm = alm + r'''
\usepackage{multirow}
\newcommand{\HRule}{\rule{\linewidth}{0.5mm}}
\setlength{\footskip}{15pt}
\usepackage[pdftex]{graphicx}	% for \includegraphics
\usepackage{tikz}				% for \draw  (load after 'graphicx')
%\showboxbreadth=50  % use for logging
%\showboxdepth=50    % use for logging
%\DeclareUnicodeCharacter{00B0}{\ensuremath{{}^\circ}}
\setlength\fboxsep{1.5pt}       % ONLY used by \colorbox in alma_skyfield.py
\begin{document}'''

    alm = alm + r'''
% for the title page only...
\newgeometry{{nomarginpar, top={}, bottom={}, left={}, right={}}}'''.format(tm1,bm1,lm1,rm1)

    alm = alm + r'''
    \begin{titlepage}
    \begin{center}
    \textsc{\Large Generated using Skyfield}\\
    \large http://rhodesmill.org/skyfield/\\[0.7cm]
    % TRIM values: left bottom right top
    \includegraphics[clip, trim=12mm 20cm 12mm 21mm, width=0.92\textwidth]{./A4chart0-180_P.pdf}\\[0.3cm]
    \includegraphics[clip, trim=12mm 20cm 12mm 21mm, width=0.92\textwidth]{./A4chart180-360_P.pdf}\\'''
    
    alm = alm + r'''[{}]
    \textsc{{\huge The Nautical Almanac}}\\[{}]'''.format(vsep1,vsep2)

    if pagenum == 122:
        alm = alm + r'''
    \HRule \\[0.5cm]
    {{ \Huge \bfseries {}}}\\[0.2cm]
    \HRule \\'''.format(year)
    else:
        alm = alm + r'''
    \HRule \\[0.5cm]
    {{ \Huge \bfseries from {}.{}.{}}}\\[0.2cm]
    \HRule \\'''.format(day,mth,year)

    alm = alm + r'''
    \begin{center}\begin{tabular}[t]{rl}
    \large\emph{Author:} & \large Andrew \textsc{Bauer}\\
    \large\emph{Original concept from:} & \large Enno \textsc{Rodegerdts}\\
    \end{tabular}\end{center}'''

    alm = alm + r'''
    {\large \today}
    \HRule \\[0.2cm]
    \end{center}
    \begin{description}\footnotesize
    \item[Disclaimer:] These are computer generated tables - use them at your own risk.
    The accuracy has been randomly checked with JPL HORIZONS System, but cannot be guaranteed.
    This means I cannot be held liable if you get lost on the oceans because of errors in this publication.
    Besides, this publication only contains the 'daily pages' of the Nautical Almanac: an official version of the Nautical Almanac is indispensable.
    \end{description}
\end{titlepage}
\restoregeometry    % so it does not affect the rest of the pages'''

    alm = alm + pages(first_day,pagenum)
    alm = alm + '''
\end{document}'''
    return alm