def __init__(self, cusps, ascmc, hsys):
"""Initialize object with swe_houses results.
>>> cusps, ascmc = swe.houses(2454595, 46.5, 6.5, 'P')
>>> res = HousesDataList(cusps, ascmc, 'P')
This procedure also computes additional values for descendant
and Imum Coeli.
:type cusps: sequence
:type ascmc: sequence
:type hsys: str
"""
self._hsys = hsys
# cusps. get their planet objects
if len(cusps) == 12:
for i, num in enumerate(range(-100, -112, -1)):
self.append(PlanetData(num, cusps[i]))
elif len(cusps) == 36: # gauquelin
for i, num in enumerate(range(-112, -148, -1)):
self.append(PlanetData(num, cusps[i]))
else:
raise ValueError('Invalid cusps results.')
# ascmc
for i, num in enumerate(range(-148, -156, -1)):
self.append(PlanetData(num, ascmc[i]))
# additional dsc, ic
self.insert(-6, PlanetData(-156, swe.degnorm(ascmc[0] - 180))) # dsc
self.insert(-6, PlanetData(-157, swe.degnorm(ascmc[1] - 180))) # ic
def __init__(self, cusps, ascmc, hsys):
"""Initialize object with swe_houses results.
>>> cusps, ascmc = swe.houses(2454595, 46.5, 6.5, 'P')
>>> res = HousesDataList(cusps, ascmc, 'P')
This procedure also computes additional values for descendant
and Imum Coeli.
:type cusps: sequence
:type ascmc: sequence
:type hsys: str
"""
self._hsys = hsys
# cusps. get their planet objects
if len(cusps) == 12:
for i, num in enumerate(range(-100, -112, -1)):
self.append(PlanetData(num, cusps[i]))
elif len(cusps) == 36: # gauquelin
for i, num in enumerate(range(-112, -148, -1)):
self.append(PlanetData(num, cusps[i]))
else:
raise ValueError('Invalid cusps results.')
# ascmc
for i, num in enumerate(range(-148, -156, -1)):
self.append(PlanetData(num, ascmc[i]))
# additional dsc, ic
self.insert(-6, PlanetData(-156, swe.degnorm(ascmc[0] - 180))) # dsc
self.insert(-6, PlanetData(-157, swe.degnorm(ascmc[1] - 180))) # ic
def __init__(self, device, chart):
"""Paint on device.
:type device: QPaintDevice
:type chart: BiChart
"""
QPainter.__init__(self, device)
self._chart = chart
# set angle to vernal point
self._vernalAng = swe.degnorm(chart[0]._houses[0]._longitude - 180)
# set canvas
self.setWindow(0, 0, 242, 242) # window is 240 x 240, +2 for antialias
self.translate(121, 121) # set center at 0;0
self.setRenderHints(QPainter.Antialiasing)
# set colors
if chart[0].filter._bg_color == 'black':
self._bgColor = Qt.black
self._drawColor = Qt.white
self._lightColor = Qt.darkGray
self._middleColor = Qt.gray
self._darkColor = Qt.lightGray
else: ## white
self._bgColor = Qt.white
self._drawColor = Qt.black
self._lightColor = Qt.lightGray
self._middleColor = Qt.gray
self._darkColor = Qt.darkGray
# fill background color
self.fillRect(-121, -121, 242, 242, QBrush(self._bgColor))
# set drawing color
self.setPen(self._drawColor)
# draw markers before circles to overwrite lighter pixels
self.draw_zodiac()
self.draw_cusps()
self.draw_circles()
self.draw_signs()
self.draw_houses()
# draw visible charts
visible = [x for x in self._chart if not x._hidden]
lenvisible = len(visible)
if lenvisible == 0: ## all hidden
return
# draw aspects before planets to overwrite
if lenvisible == 1:
self.draw_aspects(visible[0]._all_draw_aspects(), lenvisible)
self.draw_planets(0, lenvisible, visible[0]._all_draw_planets())
else: ## interaspects
self.draw_aspects(self._chart._all_draw_aspects(), lenvisible)
if self._chart[0]._filter._draw_midp:
self.draw_planets(0, lenvisible,
self._chart._all_draw_planets(0))
else:
self.draw_planets(0, lenvisible,
visible[0]._all_draw_planets())
if self._chart[1]._filter._draw_midp:
self.draw_planets(1, lenvisible,
self._chart._all_draw_planets(1))
else:
self.draw_planets(1, lenvisible,
visible[1]._all_draw_planets())
def arrange(self):
self.sort(self.cmp)
ret = list()
dist = self.orb() - (self.w / 2.0)
for i in range(len(self)):
ret.append((self[i], swe.degnorm(self.center - dist)))
dist -= self.w
return ret
def __init__(self, device, chart): """Paint on device. :type device: QPaintDevice :type chart: BiChart """ QPainter.__init__(self, device) self._chart = chart # set angle to vernal point self._vernalAng = swe.degnorm(chart[0]._houses[0]._longitude - 180) # set canvas self.setWindow(0, 0, 242, 242) # window is 240 x 240, +2 for antialias self.translate(121, 121) # set center at 0;0 self.setRenderHints(QPainter.Antialiasing) # set colors if chart[0].filter._bg_color == 'black': self._bgColor = Qt.black self._drawColor = Qt.white self._lightColor = Qt.darkGray self._middleColor = Qt.gray self._darkColor = Qt.lightGray else: ## white self._bgColor = Qt.white self._drawColor = Qt.black self._lightColor = Qt.lightGray self._middleColor = Qt.gray self._darkColor = Qt.darkGray # fill background color self.fillRect(-121, -121, 242, 242, QBrush(self._bgColor)) # set drawing color self.setPen(self._drawColor) # draw markers before circles to overwrite lighter pixels self.draw_zodiac() self.draw_cusps() self.draw_circles() self.draw_signs() self.draw_houses() # draw visible charts visible = [x for x in self._chart if not x._hidden] lenvisible = len(visible) if lenvisible == 0: ## all hidden return # draw aspects before planets to overwrite if lenvisible == 1: self.draw_aspects(visible[0]._all_draw_aspects(), lenvisible) self.draw_planets(0, lenvisible, visible[0]._all_draw_planets()) else: ## interaspects self.draw_aspects(self._chart._all_draw_aspects(), lenvisible) if self._chart[0]._filter._draw_midp: self.draw_planets(0, lenvisible, self._chart._all_draw_planets(0)) else: self.draw_planets(0, lenvisible, visible[0]._all_draw_planets()) if self._chart[1]._filter._draw_midp: self.draw_planets(1, lenvisible, self._chart._all_draw_planets(1)) else: self.draw_planets(1, lenvisible, visible[1]._all_draw_planets())
def draw_signs(self): """Draw signs glyphs.""" zodiacdir = os.path.join(_baseDir, 'icons', 'zodiac', _zodiacDir) ang = swe.degnorm(self._vernalAng - 15) for i in range(12): im = QImage(os.path.join(zodiacdir, 'sign_%.2d.png' % (i+1))) x, y = _getPointAt(ang, 111, 8, 8) target = QRect(x, y, 16, 16) self.drawImage(target, im, _iconRect) ang -= 30
def draw_signs(self):
"""Draw signs glyphs."""
zodiacdir = os.path.join(_baseDir, 'icons', 'zodiac', _zodiacDir)
ang = swe.degnorm(self._vernalAng - 15)
for i in range(12):
im = QImage(os.path.join(zodiacdir, 'sign_%.2d.png' % (i + 1)))
x, y = _getPointAt(ang, 111, 8, 8)
target = QRect(x, y, 16, 16)
self.drawImage(target, im, _iconRect)
ang -= 30
def part_of_fortune_rudhyar(cht):
"""Calculate part of fortune (Rudhyar).
:type cht: Chart
"""
flag = cht._filter.get_calcflag()
sun = swe.calc_ut(cht.julday, swe.SUN, flag)
moon = swe.calc_ut(cht.julday, swe.MOON, flag)
pos = swe.degnorm(
cht._houses.get_positions('Asc')._longitude +
(swe.difdegn(moon[0], sun[0])))
return (pos, 0, 0, 0, 0, 0)
def part_of_fortune_rudhyar(cht):
"""Calculate part of fortune (Rudhyar).
:type cht: Chart
"""
flag = cht._filter.get_calcflag()
sun = swe.calc_ut(cht.julday, swe.SUN, flag)
moon = swe.calc_ut(cht.julday, swe.MOON, flag)
pos = swe.degnorm(
cht._houses.get_positions('Asc')._longitude + (
swe.difdegn(moon[0], sun[0])))
return (pos, 0, 0, 0, 0, 0)
def calc_ut(self, jd, flag, chart=None):
"""Return calculations results.
Houses cusps are calculated in block (see chartcalc).
Parts require that you pass the chart object.
:type jd: numeric
:type flag: int
:type chart: ChartCalc
:raise ValueError: invalid planet (houses)
"""
if self._family == 4:
raise ValueError('Cannot calculate houses.')
# "inverted objects". Should invert latitude too??
elif self._num == -2: # ketu (mean)
r = swe.calc_ut(jd, 10, flag)
return (swe.degnorm(r[0]-180),
r[1], r[2], r[3], r[4], r[5])
elif self._num == -3: # ketu (true)
r = swe.calc_ut(jd, 11, flag)
return (swe.degnorm(r[0]-180),
r[1], r[2], r[3], r[4], r[5])
elif self._num == -4: # priapus (mean)
r = swe.calc_ut(jd, 12, flag)
return (swe.degnorm(r[0]-180),
r[1], r[2], r[3], r[4], r[5])
elif self._num == -5: # priapus (true)
r = swe.calc_ut(jd, 13, flag)
return (swe.degnorm(r[0]-180),
r[1], r[2], r[3], r[4], r[5])
# planets, asteroids, etc
elif self._family in (0, 1, 3):
return swe.calc_ut(jd, self._num, flag)
# fixed stars
elif self._family == 2:
return swe.fixstar_ut(self._name, jd, flag)
# parts
elif self._family == 5:
return oroboros.core.parts.calc_ut(self._name, chart)
def updatePandC(date, observer, houses, entries): day = datetime_to_julian(date) obliquity = swisseph.calc_ut(day, swisseph.ECL_NUT)[0] cusps, asmc = swisseph.houses(day, observer.lat, observer.lng) fill_houses(date, observer, houses=houses, data=cusps) for i in range(10): calcs = swisseph.calc_ut(day, i) hom = swisseph.house_pos(asmc[2], observer.lat, obliquity, calcs[0], objlat=calcs[1]) if i == swisseph.SUN or i == swisseph.MOON: retrograde = 'Not Applicable' else: retrograde = str(calcs[3] < 0) entries[i].retrograde = retrograde entries[i].m.longitude = calcs[0] entries[i].m.latitude = calcs[1] entries[i].m.progress = hom % 1.0 entries[i].m.house_info = houses[int(hom-1)] if len(entries) > 10: #add node entries calcs = swisseph.calc_ut(day, swisseph.TRUE_NODE) hom = swisseph.house_pos(asmc[2], observer.lat, obliquity, calcs[0], objlat=calcs[1]) retrograde = "Always" entries[10].retrograde = retrograde entries[10].m.longitude = calcs[0] entries[10].m.latitude = calcs[1] entries[10].m.progress = hom%1.0 entries[10].m.house_info = houses[int(hom-1)] #do some trickery to display the South Node reverse = swisseph.degnorm(calcs[0]-180.0) revhouse = (int(hom)+6)%12 #revprogress = 1-hom%1.0 revprogress = hom%1.0 entries[11].retrograde = retrograde entries[11].m.longitude = reverse entries[11].m.latitude = calcs[1] entries[11].m.progress = revprogress entries[11].m.house_info = houses[int(revhouse-1)] if len(entries) > 12: ascendant = asmc[0] descendant = cusps[6] mc = asmc[1] ic = cusps[3] retrograde = 'Not a Planet' entries[12].m.longitude = ascendant entries[13].m.longitude = descendant entries[14].m.longitude = mc entries[15].m.longitude = ic swisseph.close()
def updatePandC(date, observer, houses, entries):
day = datetime_to_julian(date)
obliquity = swisseph.calc_ut(day, swisseph.ECL_NUT)[0]
cusps, asmc = swisseph.houses(day, observer.lat, observer.lng)
fill_houses(date, observer, houses=houses, data=cusps)
for i in range(10):
calcs = swisseph.calc_ut(day, i)
hom = swisseph.house_pos(asmc[2], observer.lat, obliquity, calcs[0], objlat=calcs[1])
if i == swisseph.SUN or i == swisseph.MOON:
retrograde = "Not Applicable"
else:
retrograde = str(calcs[3] < 0)
entries[i].retrograde = retrograde
entries[i].m.longitude = calcs[0]
entries[i].m.latitude = calcs[1]
entries[i].m.progress = hom % 1.0
entries[i].m.house_info = houses[int(hom - 1)]
if len(entries) > 10: # add node entries
calcs = swisseph.calc_ut(day, swisseph.TRUE_NODE)
hom = swisseph.house_pos(asmc[2], observer.lat, obliquity, calcs[0], objlat=calcs[1])
retrograde = "Always"
entries[10].retrograde = retrograde
entries[10].m.longitude = calcs[0]
entries[10].m.latitude = calcs[1]
entries[10].m.progress = hom % 1.0
entries[10].m.house_info = houses[int(hom - 1)]
# do some trickery to display the South Node
reverse = swisseph.degnorm(calcs[0] - 180.0)
revhouse = (int(hom) + 6) % 12
# revprogress = 1-hom%1.0
revprogress = hom % 1.0
entries[11].retrograde = retrograde
entries[11].m.longitude = reverse
entries[11].m.latitude = calcs[1]
entries[11].m.progress = revprogress
entries[11].m.house_info = houses[int(revhouse - 1)]
if len(entries) > 12:
ascendant = asmc[0]
descendant = cusps[6]
mc = asmc[1]
ic = cusps[3]
retrograde = "Not a Planet"
entries[12].m.longitude = ascendant
entries[13].m.longitude = descendant
entries[14].m.longitude = mc
entries[15].m.longitude = ic
swisseph.close()
def add_pos(self, value):
"""Add degrees to positions.
Chart positions must be computed before.
:see: calc()
:type value: numeric
"""
pl = PlanetDataList()
value = float(value)
for pos in self._planets:
##if pos._planet._family == 4: # houses
##continue
pos._longitude = swe.degnorm(pos._longitude + value)
pl.append(pos)
self._planets = pl
# recalc
self._calc_aspects()
if self._filter._calc_midp:
self._calc_midpoints()
self._calc_midp_aspects()
def get_signs(date, observer, nodes, axes, prefix=None):
entries = []
houses = fill_houses(date, observer)
day = datetime_to_julian(date)
obliquity = swisseph.calc_ut(day, swisseph.ECL_NUT)[0]
cusps, asmc = swisseph.houses(day, observer.lat, observer.lng)
for i in range(10):
calcs = swisseph.calc_ut(day, i)
hom = swisseph.house_pos(asmc[2], observer.lat, obliquity, calcs[0], objlat=calcs[1])
zm = ActiveZodiacalMeasurement(calcs[0], calcs[1], houses[int(hom-1)], progress=hom % 1.0)
if i == swisseph.SUN or i == swisseph.MOON:
retrograde = 'Not Applicable'
else:
retrograde = str(calcs[3] < 0)
planet = Planet(swisseph.get_planet_name(i), prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
if nodes: #add node entries
calcs = swisseph.calc_ut(day, swisseph.TRUE_NODE)
hom = swisseph.house_pos(asmc[2], observer.lat, obliquity, calcs[0], objlat=calcs[1])
zm = ActiveZodiacalMeasurement(calcs[0], calcs[1], houses[int(hom-1)], progress=hom % 1.0)
retrograde = "Always"
planet = Planet("North Node", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
#do some trickery to display the South Node
reverse = swisseph.degnorm(calcs[0]+180.0)
revhouse = (int(hom)+6) % 12
#revprogress = 1-hom%1.0
revprogress = hom % 1.0
zm = ActiveZodiacalMeasurement(reverse, calcs[1], houses[revhouse-1], progress=revprogress)
planet = Planet("South Node", prefix=prefix ,m=zm, retrograde=retrograde)
entries.append(planet)
if axes:
ascendant = asmc[0]
descendant = cusps[6]
mc = asmc[1]
ic = cusps[3]
retrograde = 'Not a Planet'
zm = ActiveZodiacalMeasurement(ascendant, 0.0, houses[0], progress=0.0)
planet = Planet("Ascendant", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
zm = ActiveZodiacalMeasurement(descendant, 0.0, houses[6], progress=0.0)
planet = Planet("Descendant", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
zm = ActiveZodiacalMeasurement(mc, 0.0, houses[9], progress=0.0)
planet = Planet("MC", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
zm = ActiveZodiacalMeasurement(ic, 0.0, houses[3], progress=0.0)
planet = Planet("IC", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
#if stars:
#print "Todo"
swisseph.close()
return houses, entries
def get_signs(date, observer, nodes, axes, prefix=None):
entries = []
houses = fill_houses(date, observer)
day = datetime_to_julian(date)
obliquity = swisseph.calc_ut(day, swisseph.ECL_NUT)[0]
cusps, asmc = swisseph.houses(day, observer.lat, observer.lng)
for i in range(10):
calcs = swisseph.calc_ut(day, i)
hom = swisseph.house_pos(asmc[2], observer.lat, obliquity, calcs[0], objlat=calcs[1])
zm = ActiveZodiacalMeasurement(calcs[0], calcs[1], houses[int(hom - 1)], progress=hom % 1.0)
if i == swisseph.SUN or i == swisseph.MOON:
retrograde = "Not Applicable"
else:
retrograde = str(calcs[3] < 0)
planet = Planet(swisseph.get_planet_name(i), prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
if nodes: # add node entries
calcs = swisseph.calc_ut(day, swisseph.TRUE_NODE)
hom = swisseph.house_pos(asmc[2], observer.lat, obliquity, calcs[0], objlat=calcs[1])
zm = ActiveZodiacalMeasurement(calcs[0], calcs[1], houses[int(hom - 1)], progress=hom % 1.0)
retrograde = "Always"
planet = Planet("North Node", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
# do some trickery to display the South Node
reverse = swisseph.degnorm(calcs[0] + 180.0)
revhouse = (int(hom) + 6) % 12
# revprogress = 1-hom%1.0
revprogress = hom % 1.0
zm = ActiveZodiacalMeasurement(reverse, calcs[1], houses[revhouse - 1], progress=revprogress)
planet = Planet("South Node", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
if axes:
ascendant = asmc[0]
descendant = cusps[6]
mc = asmc[1]
ic = cusps[3]
retrograde = "Not a Planet"
zm = ActiveZodiacalMeasurement(ascendant, 0.0, houses[0], progress=0.0)
planet = Planet("Ascendant", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
zm = ActiveZodiacalMeasurement(descendant, 0.0, houses[6], progress=0.0)
planet = Planet("Descendant", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
zm = ActiveZodiacalMeasurement(mc, 0.0, houses[9], progress=0.0)
planet = Planet("MC", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
zm = ActiveZodiacalMeasurement(ic, 0.0, houses[3], progress=0.0)
planet = Planet("IC", prefix=prefix, m=zm, retrograde=retrograde)
entries.append(planet)
# if stars:
# print "Todo"
swisseph.close()
return houses, entries
