def testkey():
if results and g.getevent().startswith("key x"):
g.setlayer(results_layer)
g.select(g.getrect())
g.copy()
g.select([])
g.setlayer(work_layer)
def lookforkeys(event, deltax, deltay):
global oldcells, selrect, selpatt
# look for keys used to flip/rotate selection
if event == "key x none" or event == "key y none":
# flip floating selection left-right or top-bottom
if len(oldcells) > 0:
g.clear(0)
g.putcells(selpatt, deltax, deltay)
if " x " in event:
g.flip(0)
else:
g.flip(1)
selpatt = g.transform(g.getcells(selrect), -deltax, -deltay)
if len(oldcells) > 0:
g.clear(0)
g.putcells(oldcells)
g.putcells(selpatt, deltax, deltay)
g.update()
return
if event == "key > none" or event == "key < none":
# rotate floating selection clockwise or anticlockwise;
# because we use g.rotate below we have to use the exact same
# calculation (see Selection::Rotate in wxselect.cpp) for rotrect:
midx = selrect[0] + int((selrect[2]-1)/2)
midy = selrect[1] + int((selrect[3]-1)/2)
newleft = midx + selrect[1] - midy
newtop = midy + selrect[0] - midx
rotrect = [ newleft, newtop, selrect[3], selrect[2] ]
if not rectingrid(rotrect):
g.warn("Rotation is not allowed if selection would be outside grid.")
return
g.clear(0)
if len(oldcells) > 0: g.putcells(oldcells)
oldcells = g.join(oldcells, g.getcells(rotrect))
g.clear(0)
g.select(rotrect)
g.clear(0)
g.select(selrect)
g.putcells(selpatt, deltax, deltay)
if " > " in event:
g.rotate(0)
else:
g.rotate(1)
selrect = g.getselrect()
if selrect != rotrect: g.warn("Bug: selrect != rotrect")
selpatt = g.transform(g.getcells(selrect), -deltax, -deltay)
if len(oldcells) > 0:
g.clear(0)
g.putcells(oldcells)
g.putcells(selpatt, deltax, deltay)
g.update()
return
if event == "key h none":
showhelp2()
return
g.doevent(event)
def rule_boring():
explode = 0
die = 0
num_trial = 8
for i in range(num_trial):
g.new("")
g.select([0, 0, 32, 32])
g.randfill(50)
g.run(16)
if int(g.getpop()) == 0:
die += 1
continue
r = g.getrect()
if r[2] > 60 and r[3] > 60:
explode += 1
continue
return -1
if explode == num_trial:
return 0
if die == num_trial:
return 1
return -1
def draw(self):
xy = []
xz = []
yz = []
proj = []
for (k, v) in self.cur_state.items():
x, y, z = k
xy.append(x)
xy.append(y)
xz.append(x + 128)
xz.append(z)
yz.append(y)
yz.append(z + 128)
proj.append(x + y + z + 128)
proj.append(-x + y + z + 128)
if len(g.getrect()) > 0:
g.select(g.getrect())
g.clear(0)
g.select([])
g.putcells(xy)
g.putcells(xz)
g.putcells(yz)
g.putcells(proj)
g.setpos("64", "64")
g.setmag(1)
g.update()
def loadtopo(maxnum,step,boxwidth): global pboxlist tile=[] for i in range(step,maxnum+step,step): make_text(str(i)).put(boxwidth*(i-1),0) box.put(boxwidth*(i-1),0) boxsel=[boxwidth*(i-1)+1,1,38,38] g.select(boxsel) g.shrink() if g.getselrect()==boxsel: continue else: sel=g.getselrect() pbox=g.getselrect() clist=g.getcells(pbox) for i in range(int(len(clist)/3)): clist[3*i] = clist[3*i]-sel[0] clist[3*i+1] = clist[3*i+1]-sel[1] clist.insert(0,sel[2]) clist.insert(1,sel[3]) tile.append(clist) pboxlist.append(pbox) return tile
def paste(g, fichier, x, y):
g.addlayer()
g.open(fichier)
g.select([-1000, -1000, 2000, 2000])
g.copy()
g.dellayer()
g.paste(x - 1000, y - 1000, 'or')
def lookforkeys(event, deltax, deltay):
global oldcells, selrect, selpatt
# look for keys used to flip/rotate selection
if event == "key x none" or event == "key y none":
# flip floating selection left-right or top-bottom
if len(oldcells) > 0:
g.clear(0)
g.putcells(selpatt, deltax, deltay)
if " x " in event:
g.flip(0)
else:
g.flip(1)
selpatt = g.transform(g.getcells(selrect), -deltax, -deltay)
if len(oldcells) > 0:
g.clear(0)
g.putcells(oldcells)
g.putcells(selpatt, deltax, deltay)
g.update()
return
if event == "key > none" or event == "key < none":
# rotate floating selection clockwise or anticlockwise;
# because we use g.rotate below we have to use the exact same
# calculation (see Selection::Rotate in wxselect.cpp) for rotrect:
midx = selrect[0] + int((selrect[2]-1)/2)
midy = selrect[1] + int((selrect[3]-1)/2)
newleft = midx + selrect[1] - midy
newtop = midy + selrect[0] - midx
rotrect = [ newleft, newtop, selrect[3], selrect[2] ]
if not rectingrid(rotrect):
g.warn("Rotation is not allowed if selection would be outside grid.")
return
g.clear(0)
if len(oldcells) > 0: g.putcells(oldcells)
oldcells = g.join(oldcells, g.getcells(rotrect))
g.clear(0)
g.select(rotrect)
g.clear(0)
g.select(selrect)
g.putcells(selpatt, deltax, deltay)
if " > " in event:
g.rotate(0)
else:
g.rotate(1)
selrect = g.getselrect()
if selrect != rotrect: g.warn("Bug: selrect != rotrect")
selpatt = g.transform(g.getcells(selrect), -deltax, -deltay)
if len(oldcells) > 0:
g.clear(0)
g.putcells(oldcells)
g.putcells(selpatt, deltax, deltay)
g.update()
return
if event == "key h none":
showhelp2()
return
g.doevent(event)
def draw(self, addstr = ""):
xy = []
xz = []
yz = []
proj = []
for (k, v) in self.cur_state.items():
x, y, z = k
xy.append(x)
xy.append(y)
xz.append(x + 128)
xz.append(z)
yz.append(y)
yz.append(z + 128)
proj.append(x + y + z + 128)
proj.append(- x + y + z + 128)
if len(g.getrect()) > 0:
g.select(g.getrect())
g.clear(0)
g.select([])
g.putcells(xy)
g.putcells(xz)
g.putcells(yz)
g.putcells(proj)
g.setpos("64", "64")
g.setmag(1)
g.show("Size: {0}, (w, d, h): {1}".format(self.get_pop(), str(self.get_wdh())) + addstr)
g.update()
def clearlayer():
r = g.getrect()
if r:
g.select(r)
g.clear(0)
if withB0:
# Needed with B0 rules to ensure pattern runs correctly
g.setgen('0')
def testRule(rulestr):
r = g.getrect()
if r:
g.select(r)
g.clear(0)
g.putcells(origPatt)
g.setrule(rulestr)
g.run(stabGen)
if g.empty():
return ()
pop = int(g.getpop())
if (pop < minPop or pop > maxPop):
return ()
r = g.getrect()
testPatt = g.transform(g.getcells(r), -r[0], -r[1])
testPop = int(g.getpop())
testRect = g.getrect()
stabPatt = list(testPatt)
stabPop = testPop
for ii in xrange(maxGen):
g.run(1)
pop = int(g.getpop())
if (pop < minPop or pop > maxPop):
break
if (pop == testPop):
# Test for periodicity
r = g.getrect()
if testPatt == g.transform(g.getcells(r), -r[0], -r[1]):
period = ii + 1
dy, dx = sss.minmaxofabs(
(r[0] - testRect[0], r[1] - testRect[1]))
if (dx == 0):
# Oscillator (reject if low period or bOsc is False)
if bOsc and period >= minOscP:
return (0, 0, period)
elif (period >= minShipP):
# Spaceship
return (dx, dy, period)
elif ((dx + dy / 1.9) / (period * 1.0) > minSpeed
and period >= fastShipP):
# Fast spaceship
return (dx, dy, period)
break # Pattern is a low period oscillator or spaceship
# Stability check
if (ii % stabCheckP == 0):
r = g.getrect()
# First check for BBox expansion
if maxDim > 0 and max(r[2:4]) > maxDim:
# Pattern is expanding
# XXX Attempt to separate components expanding in different directions
break
currPatt = g.transform(g.getcells(r), -r[0], -r[1])
if (pop == stabPop and currPatt == stabPatt):
# Pattern has stabilised to low period oscillator / spaceship
break
stabPop = pop
stabPatt = list(currPatt)
return ()
def add_data(PATTERN_FN):
g.select([-2753, 891, 1092, 1397])
g.clear(0)
g.select([])
input_str = open(PATTERN_FN, "r").read()
firstbreak = input_str.find("\n")
if firstbreak == -1:
g.show("Error, no newlines found, invalid format")
g.exit()
info_line = input_str[0:firstbreak]
input_str = input_str[firstbreak:]
#x = 1581, y = 1396, rule = Varlife
dataptrn = re.compile(
br'x = (?P<xval>[0-9]{1,4}), y = (?P<yval>[0-9]{1,4}), rule = .*')
match = dataptrn.match(info_line)
xval = 0
yval = 0
if (match):
xval = int(match.group("xval"), 10)
yval = int(match.group("yval"), 10)
else:
g.show("ERROR invalid format {}".format(info_line))
g.exit()
ipat = pattern(input_str)
minbox = getminbox(ipat)
if max(xval, minbox.x) > 1200:
g.show("ERROR inserted cell area too wide, max width is 1090")
g.exit()
if max(yval, minbox.y) > 1397:
g.show("ERROR inserted cell area too tall, max height is 1397")
g.exit()
startx = -1661 - xval
starty = 891
#blankptrn.put(startx, starty)
g.show(
"width={}, height={} startx={}, starty={}, xval={}, yval={}, bytes={}".
format(minbox.wd, minbox.height, startx, starty, xval, yval,
len(input_str)))
ipat.put(startx, starty)
g.save("/tmp/output.mc", "rle", False)
return "Pattern load data: width={}, height={} startx={}, starty={}, xval={}, yval={}, bytes={}".format(
minbox.wd, minbox.height, startx, starty, xval, yval, len(input_str))
def select_rectangle_for_borders(self, startx, starty, width, height):
"""
Selects the grid to have a border set around it
:param startx: Starting x position of the grid
:param starty: Starting y position of the grid
:param width: Width of the grid
:param height: Height of the grid
"""
g.select([startx, starty, width, height])
def trygliders(ginfo):
gdistance = ginfo / 4
phase = ginfo % 4
bstatus = boxstatus
pstatus = popstatus
for num in xrange(8):
tlist = form(celllist, num)
rect = boxform(fullrect, num)
g.new('')
g.putcells(tlist)
gx = rect[0] - 3 - gdistance
gy = rect[1] - 3 - gdistance
for w in xrange(rect[2] + 5):
g.new('')
g.putcells(tlist)
g.putcells(glider[phase], gx + w, gy)
g.fit()
g.update()
for gen in xrange(1000):
g.run(1)
if int(g.getpop()) <= 2:
g.new('')
g.show("Found clean glider destruction.")
status = 0, num, phase, [gx + w, gy]
putcells_and_fit(result(celllist, status))
g.exit()
box = g.getrect()[2:]
# Checking the bounding box size and population against the current lowest found.
if reduce(mul, box) < reduce(mul, bstatus[0]):
bstatus = (box, num, phase, [gx + w, gy])
pop = int(g.getpop())
if pop < pstatus[0]:
pstatus = (pop, num, phase, [gx + w, gy])
# Show results if the user presses certain keys
event = g.getevent()
if event.startswith("key x"):
g.new('')
put_result_pair(celllist, bstatus, pstatus)
g.select(g.getrect())
g.copy()
g.select([])
g.note(
"Minimum bounding box and population collisions copied to clipboard."
)
if event.startswith("key q"):
g.new('')
g.show("Search stopped.")
put_result_pair(celllist, bstatus, pstatus)
g.fit()
g.exit()
g.show(
"Searching for a 1-glider destruction... press <x> to copy minimum bounding box and population results to clipboard; press <q> to quit. Stats: minimum bounding box %dx%d, minimum population %d"
% (bstatus[0][0], bstatus[0][1], pstatus[0]))
return bstatus, pstatus
def GunsReader(): result = [] for i in xrange(0, 10000): cells = g.getcells([0, i * 650, 500, 550]) if len(cells) == 0: return result g.select([-200, i * 650 - 10, 800, 550]) g.clear(0) result.append(cells)
def shrink(): global d if g.empty(): return g.select(g.getrect()) d=int(10000*float(g.getpop())/(int(g.getselrect()[2])*int(g.getselrect()[3]))) while d<100: bbox=g.getselrect() bbox[0]=bbox[0]+1 bbox[1]=bbox[1]+1 bbox[2]=bbox[2]-2 bbox[3]=bbox[3]-2 g.select(bbox) g.shrink() d=int(10000*float(g.getpop())/(int(g.getselrect()[2])*int(g.getselrect()[3])))
def AdaptiveGoto(hwssRecipe, enablePrinting=True):
#g.setrule("LifeHistory")
fense50 = g.parse(
"F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F!"
)
helixD = CalcHelix(hwssRecipe)
curgen = -helixD * 2
curgen += 2 * distForward
goto(curgen)
g.setbase(8)
g.setstep(3)
delta = 10
lastmaxi = delta
idx = 0
for i in hwssRecipe:
if enablePrinting and (100 * (idx + 1)) / len(hwssRecipe) != (
100 * idx) / len(hwssRecipe):
percent = (100 * (idx + 1)) / len(hwssRecipe)
g.update()
g.show("Iterating forward progress " + str(percent) + "%")
curgen += 2 * distForward
idx += 1
while int(g.getgen()) < curgen:
g.step()
if i == 'SKIP':
continue
if i > lastmaxi:
g.select([fenseX, helixD + fenseY + lastmaxi - delta, 1, delta])
g.clear(0)
lastmaxi += delta
#g.update()
if i < lastmaxi - delta:
g.putcells(fense50, fenseX, helixD + fenseY + lastmaxi - 2 * delta)
lastmaxi -= delta
def AdaptiveGoto(hwssRecipe, enablePrinting = True):
#g.setrule("LifeHistory")
fense50 = g.parse("F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F!")
helixD = CalcHelix(hwssRecipe)
curgen = -helixD * 2
curgen += 2 * distForward
goto(curgen)
g.setbase(8)
g.setstep(3)
delta = 10
lastmaxi = delta
idx = 0
for i in hwssRecipe:
if enablePrinting and (100 * (idx + 1)) / len(hwssRecipe) != (100 * idx) / len(hwssRecipe):
percent = (100 * (idx + 1)) / len(hwssRecipe)
g.update()
g.show("Iterating forward progress " + str(percent) + "%")
curgen += 2 * distForward
idx += 1
while int(g.getgen()) < curgen:
g.step()
if i == 'SKIP':
continue
if i > lastmaxi:
g.select([fenseX, helixD + fenseY + lastmaxi - delta, 1, delta])
g.clear(0)
lastmaxi += delta
#g.update()
if i < lastmaxi - delta:
g.putcells(fense50, fenseX, helixD + fenseY + lastmaxi - 2 * delta)
lastmaxi -= delta
def write(asm):
binary = translateAll(asm)
g.open("computer.mc")
g.duplicate()
g.setname("programmed", 0)
g.movelayer(1, 0)
g.dellayer()
g.select([-25950, 1890, 450, 240])
g.cut()
for i in range(len(binary)):
for j in range(21):
if int(binary[i][j]):
g.select([-23639+i*600+j*300, 2159+i*600-j*300, 450, 240])
g.clear(0)
g.paste(-23639+i*600+j*300, 2159+i*600-j*300, "or")
def better_randfill():
g.new('')
g.select([-10, -10, GRID_SIZE[0], GRID_SIZE[1]])
g.randfill(random.randrange(50))
g.select([])
g.autoupdate(True)
cnt = 0
for x in range(0, GENS):
cnt += 1
if not g.empty():
g.run(1)
if is_static():
break
time.sleep(0.05)
else:
break
if cnt % 10 == 0:
g.fit()
def loadtopo():
for i in range(step, max + step, step):
make_text(str(i)).put(boxwidth * (i - 1), 0)
box.put(boxwidth * (i - 1), 0)
boxsel = [boxwidth * (i - 1) + 1, 1, 38, 38]
g.select(boxsel)
g.shrink()
if g.getselrect() == boxsel:
continue
else:
clist = g.getcells(g.getselrect())
sel = g.getselrect()
for i in range(int(len(clist) / 3)):
clist[3 * i] = clist[3 * i] - sel[0]
clist[3 * i + 1] = clist[3 * i + 1] - sel[1]
clist.insert(0, sel[2])
clist.insert(1, sel[3])
tile.append(clist)
return tile
def canon5Sship(ship, maxgen=2000):
minpop, rulestr, dx, dy, period, shiprle = ship
shipPatt = g.parse(shiprle)
# Transform ship to canonical direction
if abs(dx) >= abs(dy):
a, b, c, d = sign(dx), 0, 0, sign(dy)
else:
a, b, c, d = 0, sign(dy), sign(dx), 0
dy, dx = minmaxofabs((dx, dy))
shipPatt = g.transform(shipPatt, 0, 0, a, b, c, d)
# Clear the layer and place the ship
r = g.getrect()
if r:
g.select(r)
g.clear(0)
g.putcells(shipPatt)
shiprle = giveRLE(g.getcells(g.getrect()))
g.setrule(rulestr)
# Determine the minimal isotropic rule
setminisorule(period)
return minpop, g.getrule(), dx, dy, period, shiprle
def tileit(clist,tilewd): global inc,pbox cliplist=clist # g.select([boxsel[0]-20,boxsel[1]-20,20,20]) # g.clear(0) # make_text(str(posi)).put(boxsel[0]-20,boxsel[1]) pbox = rect( [0, 0] + cliplist[0 : 2] ) wd=tilewd*pbox.wd ht=tilewd*pbox.ht boxsel=[-int(wd/2),-int(wd/2),wd,ht] g.select(boxsel) selrect = rect( g.getselrect() ) inc=2 cliplist[0 : 2] = [] # remove wd,ht p = pattern( cliplist ) if len(cliplist) & 1 == 1: inc = 3 # multi-state? g.clear(inside) if len(cliplist) > 0: # tile selrect with p, clipping right & bottom edges if necessary y = selrect.top while y <= selrect.bottom: bottom = y + pbox.height - 1 x = selrect.left while x <= selrect.right: right = x + pbox.width - 1 if (right <= selrect.right) and (bottom <= selrect.bottom): p.put(x, y) else: clip_rb( p(x, y), selrect.right, selrect.bottom ).put() x += pbox.width y += pbox.height if not selrect.visible(): g.fitsel()
def setupT(dhead, binaryStr, dx, dy):
setupR(dhead, dx, dy)
setupR(len(binaryStr) - 1 - dhead, dx + 310, dy - 506)
setupR(dhead * 16, dx + 130, dy - 3286)
setupR(dhead * 16, dx - 1113, dy - 2062)
if len(binaryStr) == 0:
return
x = dx + 142
y = dy - 3305
g.select([x, y, 3, 3])
g.clear(0)
for i in range(len(binaryStr)):
if binaryStr[i] == '0':
g.putcells(boat, x, y)
else:
g.putcells(boat, x - 3, y - 3)
x -= 16
y -= 16
def AdaptiveGoto(hwssRecipe):
#g.setrule("LifeHistory")
fense50 = g.parse("F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F!")
helixD = -step * len(hwssRecipe) - 1000
while helixD % 7500 != 0:
helixD -= 1
curgen = -helixD * 2
curgen += 2 * distForward
goto(curgen)
g.setstep(3)
delta = 10
lastmaxi = delta
for i in hwssRecipe:
curgen += 2 * distForward
while int(g.getgen()) < curgen:
g.step()
if i == 'SKIP':
continue
if i > lastmaxi:
g.select([240, helixD + fenseY + lastmaxi - delta, 1, delta])
g.clear(0)
lastmaxi += delta
#g.update()
if i < lastmaxi - delta:
g.putcells(fense50, 240, helixD + fenseY + lastmaxi - 2 * delta)
lastmaxi -= delta
def AdaptiveGoto(hwssRecipe):
#g.setrule("LifeHistory")
fense50 = g.parse("F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F$F!")
helixD = -step * len(hwssRecipe) - 1000
while helixD % 7500 != 0:
helixD -= 1
curgen = -helixD * 2
curgen += 2 * distForward
goto(curgen)
g.setstep(3)
delta = 10
lastmaxi = delta
for i in hwssRecipe:
curgen += 2 * distForward
while int(g.getgen()) < curgen:
g.step()
if i == 'SKIP':
continue
if i > lastmaxi:
g.select([240, helixD + fenseY + lastmaxi - delta, 1, delta])
g.clear(0)
lastmaxi += delta
#g.update()
if i < lastmaxi - delta:
g.putcells(fense50, 240, helixD + fenseY + lastmaxi - 2 * delta)
lastmaxi -= delta
def explode_dense():
num_trial = 2
for i in range(num_trial):
g.new("")
g.select([0, 0, 32, 32])
g.randfill(50)
g.run(128)
total = 0
for i in range(32):
total += len(g.getcells([0, 0, 32, 32])) / 2
g.run(32)
total /= 32
if total >= 300:
return True
return False
def CanApplyRecipe(self, recipe, expected):
g.new("")
g.setstep(3)
g.putcells(blck)
g.putcells(self.init)
for r in self.recipe:
g.putcells(gld, 80, 80 + r)
g.step()
g.select([self.block0[0], self.block0[1], 2, 2])
g.clear(0)
cells = g.getcells(g.getrect())
g.putcells(blck, self.block0[0], self.block0[1])
delta = self.block0[1] - self.block0[0]
for r in recipe:
g.putcells(gld, 80, 80 + r + delta)
g.step()
for i in xrange(0, len(cells), 2):
x = cells[i]
y = cells[i + 1]
if g.getcell(x, y) == 0:
return False
for i in xrange(0, len(expected), 2):
x = expected[i] + self.block0[0]
y = expected[i + 1] + self.block0[1]
if g.getcell(x, y) == 0:
return False
return True
def getoctohash(clist):
ptr = 0
g.new("Octotest" + str(count))
for orientation in [[1, 0, 0, 1], [0, -1, 1, 0], [-1, 0, 0, -1],
[0, 1, -1, 0], [-1, 0, 0, 1], [1, 0, 0, -1],
[0, 1, 1, 0], [0, -1, -1, 0]]:
g.putcells(clist, ptr * 2048, 0, *orientation)
ptr += 1
for j in range(8):
g.select([2048 * j - 1024, -1024, 2048, 2048])
g.shrink()
r = g.getselrect()
if r == []: r = [0, 0, 1, 1]
pat = g.getcells(r)
deltax, deltay = 0, 0
if pat != []:
deltax, deltay = -pat[0], -pat[1]
if j == 0:
minstr = str(g.transform(pat, deltax, deltay))
else:
strpat = str(g.transform(pat, deltax, deltay))
if strpat < minstr:
minstr = strpat
return " " + get9char(minstr)
def find_best_selection():
r = g.getrect()
all = g.getcells(r)
sep = 1
# - run the pattern for 4096 ticks, get the new settled pattern
# - try XORing new pattern with original pattern for every possible offset up to 512
# - one of the offsets should give the lowest total population
# (will probably decrease the population instead of increasing it,
# unless what is being built is a prolific puffer or gun or some such)
bestscore, bestsep = len(all), -1 # = population * 2
allplus4096 = g.evolve(all, 4096)
g.addlayer()
while sep <= 512:
g.show("Finding stage spacing -- testing " + str(sep))
g.new("sep=" + str(sep))
g.putcells(all)
g.putcells(allplus4096, sep, 0, 1, 0, 0, 1, "xor")
score = int(g.getpop())
if bestscore > score: bestscore, bestsep = score, sep
sep += 1
g.dellayer()
sep = bestsep
g.show("found separation: " + str(sep))
bestblockscore, bestoffset = -999999, -1
for offset in range(sep):
g.select([r[0] - offset, r[1], sep, r[3]])
g.update()
blockscore = 0
for blockx in range(r[0] - offset, r[0] + r[2], sep):
g.select([blockx, r[1], sep, r[3]])
blockrect = g.getselrect()
block = g.getcells(blockrect)
if len(
block
) == 0: # ran into empty block, this must not be the right separation
g.exit("Invalid pattern format found at separation = " +
str(sep) + ": selected block is empty.")
g.shrink(1)
shrunkblockrect = g.getselrect()
leftdiff = shrunkblockrect[0] - blockrect[0]
rightdiff = (blockrect[0] + blockrect[2]) - (shrunkblockrect[0] +
shrunkblockrect[2])
blockscore += leftdiff + rightdiff
if leftdiff < 10: blockscore -= (10 - leftdiff)**2
if rightdiff < 10: blockscore -= (10 - rightdiff)**2
if blockscore > bestblockscore:
bestblockscore, bestoffset = blockscore, offset
g.select([r[0] - bestoffset, r[1], r[2] + offset, r[3]])
return sep
rawentry2 = g.getstring(
"What is the maximum number of generations to run each soup?")
rawentry3 = g.getstring("How many soups do you want to test?")
periodlist = map(int, rawentry1.split(','))
maxgens = int(rawentry2)
soups = int(rawentry3)
totalperiod = 1
for period in periodlist:
totalperiod = lcm(period, totalperiod)
longest = [], 0
for soupnum in range(soups):
g.new('')
g.select([0, 0, 5, 5])
g.randfill(50)
currsoup = g.getcells([0, 0, 5, 5])
currpop = g.getpop()
sameaslast = 0
totalgens = 0
success = False
while totalgens < maxgens:
g.run(totalperiod)
totalgens += totalperiod
if g.getpop() == currpop:
sameaslast += 1
else:
sameaslast == 0
currpop = g.getpop()
if sameaslast == 5:
def CreateWssMovementData(recipes, dir, isUp = True): result = [] for i in xrange(0, len(recipes.WssCreator)): recipes.Reset() if isUp: recipes.Goto(-23, 1) recipes.AddWss(i) PlaceReadingHeads(recipes.recipe) if isUp: gen = period * (len(recipes.recipe) + 10) while gen % (2 * distForward) != 0: gen += 1 goto(gen) g.fit() g.update() rect = g.getrect() g.select([rect[0], -6 * distBack, rect[2], 7 * distBack]) g.clear(1) x, y, res = FindWssByDirection(isUp, distForward)[0] x += 23 y += -21 y = y % distForward else: gen = period * (len(recipes.recipe) + 10) while gen % (2 * distBack) != 0: gen += 1 goto(gen) g.fit() g.update() rect = g.getrect() helixy = CalcHelix(recipes.recipe) g.select([rect[0], helixy - distBack, rect[2], 7 * distBack]) g.clear(1) x, y, res = FindWssByDirection(isUp, distBack)[0] y = y % distBack result.append((x, y, res)) if isUp: pickle.dump(result, open(path.join(dir, str(step) + "_" + str(period) + "_ForwardWssBaseAuto.pkl"), "wb")) else: pickle.dump(result, open(path.join(dir, str(step) + "_" + str(period) + "_BackwardWssBaseAuto.pkl"), "wb")) recipes.Reset()
def moveselection():
global oldcells, selrect, selpatt
# wait for 1st click in selection
while True:
event = g.getevent()
if event.startswith("click"):
# event is a string like "click 10 20 left none"
evt, xstr, ystr, butt, mods = event.split()
x = int(xstr)
y = int(ystr)
if cellinrect(x, y, selrect):
oldmouse = xstr + ' ' + ystr
firstx = x
firsty = y
xoffset = firstx - selrect[0]
yoffset = firsty - selrect[1]
if mods == "alt":
# don't delete pattern in selection
oldcells = g.getcells(selrect)
break
elif event == "key h none":
showhelp1()
else:
g.doevent(event)
# wait for 2nd click while moving selection
g.show("Move mouse and click again..." + helpmsg)
gotclick = False
while not gotclick:
event = g.getevent()
if event.startswith("click"):
evt, x, y, butt, mods = event.split()
mousepos = x+' '+y
gotclick = True
else:
if len(event) > 0:
lookforkeys(event, x - firstx, y - firsty)
# update xoffset,yoffset in case selection was rotated
xoffset = x - selrect[0]
yoffset = y - selrect[1]
mousepos = g.getxy()
if len(mousepos) > 0 and mousepos != oldmouse:
# mouse has moved, so move selection rect and pattern
g.clear(0)
if len(oldcells) > 0: g.putcells(oldcells)
xstr, ystr = mousepos.split()
x = int(xstr)
y = int(ystr)
selrect[0] = x - xoffset
selrect[1] = y - yoffset
if g.getwidth() > 0:
# ensure selrect doesn't move beyond left/right edge of grid
if selrect[0] < gridl:
selrect[0] = gridl
x = selrect[0] + xoffset
elif selrect[0] + selrect[2] - 1 > gridr:
selrect[0] = gridr + 1 - selrect[2]
x = selrect[0] + xoffset
if g.getheight() > 0:
# ensure selrect doesn't move beyond top/bottom edge of grid
if selrect[1] < gridt:
selrect[1] = gridt
y = selrect[1] + yoffset
elif selrect[1] + selrect[3] - 1 > gridb:
selrect[1] = gridb + 1 - selrect[3]
y = selrect[1] + yoffset
g.select(selrect)
oldcells = g.getcells(selrect)
g.putcells(selpatt, x - firstx, y - firsty)
oldmouse = mousepos
g.update()
g.update()
# ------------------------------------------------------------------------------
selrect = g.getselrect()
if len(selrect) == 0: g.exit("There is no selection.")
selpatt = g.getcells(selrect)
# remember initial selection in case user aborts script
firstrect = g.getselrect()
firstpatt = g.getcells(selrect)
g.show("Click anywhere in selection, move mouse and click again..." + helpmsg)
oldcursor = g.getcursor()
g.setcursor("Move")
oldcells = []
try:
aborted = True
moveselection()
aborted = False
finally:
g.setcursor(oldcursor)
if aborted:
g.clear(0)
if len(oldcells) > 0: g.putcells(oldcells)
g.putcells(firstpatt)
g.select(firstrect)
else:
g.show(" ")
def __init__(self):
try:
g.show('setting up test')
testSize = 100 #this is the size of one side of the square testing area
g.select([-testSize/2,-testSize/2,testSize,testSize])
#clear the canvas
g.clear(1)
g.clear(0)
g.randfill(50)
g.update()
g.show('stressTest started')
startTime = time()
lg_envmt = lifegenes_environment()
endTime = time()
logging.debug('\tsetup t\t=\t\t'+str(endTime-startTime))
g.update()
startTime = time()
lg_envmt.drawColor()
endTime = time()
logging.debug('\tcolorDraw t\t=\t' + str( endTime - startTime))
g.update()
startTime = time()
lg_envmt.cellMotions()
endTime = time()
logging.debug('\tmovement t\t=\t' + str( endTime - startTime))
g.update()
startTime = time()
lg_envmt.drawColor()
endTime = time()
logging.debug('\tcolor update t \t= ' + str( endTime - startTime))
g.update()
g.step()
startTime = time()
lg_envmt.update()
endTime = time()
logging.debug('\tevolve update t\t= ' + str( endTime - startTime))
startTime = time()
lg_envmt.cellMotions()
endTime = time()
logging.debug('\tmovement t\t=\t' + str( endTime - startTime))
g.update()
startTime = time()
lg_envmt.drawColor()
endTime = time()
logging.debug('\tcolor update t\t= ' + str( endTime - startTime))
g.update()
g.update()
g.show('test complete')
finally:
logging.info('cycling halted from external source (probably golly)')
def CreateWssMovementData(recipes, dir, isUp=True):
result = []
for i in xrange(0, len(recipes.WssCreator)):
recipes.Reset()
if isUp:
recipes.Goto(-23, 1)
recipes.AddWss(i)
PlaceReadingHeads(recipes.recipe)
if isUp:
gen = period * (len(recipes.recipe) + 10)
while gen % (2 * distForward) != 0:
gen += 1
goto(gen)
g.fit()
g.update()
rect = g.getrect()
g.select([rect[0], -6 * distBack, rect[2], 7 * distBack])
g.clear(1)
x, y, res = FindWssByDirection(isUp, distForward)[0]
x += 23
y += -21
y = y % distForward
else:
gen = period * (len(recipes.recipe) + 10)
while gen % (2 * distBack) != 0:
gen += 1
goto(gen)
g.fit()
g.update()
rect = g.getrect()
helixy = CalcHelix(recipes.recipe)
g.select([rect[0], helixy - distBack, rect[2], 7 * distBack])
g.clear(1)
x, y, res = FindWssByDirection(isUp, distBack)[0]
y = y % distBack
result.append((x, y, res))
if isUp:
pickle.dump(
result,
open(
path.join(
dir,
str(step) + "_" + str(period) + "_ForwardWssBaseAuto.pkl"),
"wb"))
else:
pickle.dump(
result,
open(
path.join(
dir,
str(step) + "_" + str(period) +
"_BackwardWssBaseAuto.pkl"), "wb"))
recipes.Reset()
halfbreeder = pattern("2bo$bo$2o3b2o$obo3b2o$bo3b2o$5bo!",0,1)
breeder=halfbreeder + halfbreeder(0,14,flip_y)
hwss=pattern("2b2o$o4bo$6bo$o5bo$b6o!")
mwss=pattern("2bo$o3bo$5bo$o4bo$b5o!")
lwss=pattern("o2bo$4bo$o3bo$b4o!",0,1)
glider=pattern("b2o$obo$2bo!",0,1)
breederpuffer = breeder(15,-45) + hwss(16,-30) + hwss(16,-46,flip_y)\
+ hwss(5,-54) + hwss(5,-22,flip_y)
breederrake11 = breederpuffer(71,37) + lwss(66,20,flip_y)\
+ mwss(51,12,flip_y) + mwss(51,-14)
breederrake00 = breederrake11 + mwss(-9,10,flip_y) + mwss(-9,-12)
breederrake01 = breederrake11 + mwss(-9,-12)
breederrake10 = breederrake11 + mwss(-9,10,flip_y)
g.new("breeder.life")
g.select([400,50,600,350])
g.fitsel()
g.select(getminbox(breederrake11(314,242)))
pause(.5)
breederrake11.put(314,242)
pause(.5)
g.select(getminbox(breederrake11(312,201,flip_y)))
runn(4,.01)
breederrake11.put(312,201,flip_y)
pause(.5)
g.select(getminbox(breederrake00(368,286)))
runn(101,.01)
breederrake00.put(368,286)
pause(.5)
g.select(getminbox(breederrake10(359,158,flip_y)))
runn(33,.01)
soupfilepath = "/home/scorbie/Apps/ptbtest/random"
nsoups = int(g.getstring("How many soups?", "1000"))
soupsize = 10 # int(g.getstring('Soup size?', '10'))
if g.getrule() == "LifeHistory":
g.setrule("B3/S23")
if g.numstates() > 2:
g.exit("This script only works with two-state rules.")
soups = []
x, y, w, h = r = [0, 0, soupsize, soupsize]
cellchar = [".", "a"]
while len(soups) < nsoups:
g.new("Generating Soups")
g.select(r)
g.randfill(40)
g.run(250)
# To avoid 'Empty Pattern!' messages in status bar.
if int(g.getpop()) == 0:
continue
if not q.testquiescence(60):
g.reset()
soupstr = "!".join(
"".join(cellchar[g.getcell(i, j)] for j in xrange(0, soupsize + 1)) for i in xrange(0, soupsize + 1)
)
soups.append(soupstr)
g.show("Soup {}/{}".format(len(soups), nsoups))
with open(soupfilepath, "w") as soupfile:
soupfile.write("\n".join(soups))
g.show("Soups successfully saved in {}.".format(soupfilepath))
def main ():
g.update ()
g.check (False)
path = g.getstring ("Output directory:")
files = glob.glob (os.path.join (path, "*.out"))
mingls = g.getstring ("Min number of gliders at accept:")
if mingls == "":
mingl = 0
minpop = 0
maxpop = 1024
else:
mingl = int (mingls)
minpops = g.getstring ("Min population except catalyzers:")
if minpops == "":
minpop = 0
maxpop = 1024
else:
minpop = int (minpops)
maxpop = int (g.getstring ("Max population except catalyzers:"))
if g.getname () != "catbellman_temp":
g.addlayer ()
hashdir = {}
catlist = []
catix = 0
g.new ("catbellman_temp")
g.setrule ("LifeBellman")
for fix, filename in enumerate (files):
patt = g.getrect ()
if patt != []:
g.select (patt)
g.clear (0)
g.setgen ("0")
with open(filename, 'r') as f:
filetext = f.read ()
if fix % 16 == 0:
g.show ("Analysing " + str (fix) + "/" + str (len (files)))
(gogen, glcnt) = convbellman (filetext, 0, 0)
if gogen == -1:
gogen = 128
(use, hash) = analyse (gogen, glcnt, minpop, maxpop, mingl)
if use:
if not hash in hashdir:
catlist.append ([])
hashdir [hash] = catix
catix += 1
cat = hashdir [hash]
catlist [cat].append (filetext)
g.new ("catbellman_temp")
g.setrule ("LifeBellman")
fix = 0
y = 0
for cat in catlist:
x = 96 * (len (cat) - 1)
for filetext in cat:
convbellman (filetext, x, y)
x -= 96
fix += 1
if fix % 32 == 0:
g.show ("Rendering " + str (fix) + "/" + str (len (files)))
g.fit ()
g.check (True)
g.update ()
g.check (False)
y += 96
g.show ("Done")
g.fit ()
g.setstep (-1)
g.check (True)
g.update()
if g.getcell(signal[0], signal[1]) == 1: done = 1
g.run(finaladjustment)
g.run(100 * iperiod / subperiod)
if subperiod > 1 and outputmatch(output) != 1:
countdown = subperiod
g.setgen("0")
while countdown >= 0:
countdown -= 1
g.run(iperiod / subperiod)
if outputmatch(output) == 1:
break
if outputmatch(output) != 1:
g.exit("Looks like something went wrong at period " + period \
+ ". Output is not showing up after any reasonable number of subperiod cycles.")
g.select(r)
g.clear(1)
g.select([])
g.setgen("0")
g.show("Done! " + os.path.join(outfolder, str(period)))
g.putcells(fixedbb)
g.putcells(movablebb, iadjustment * dx, iadjustment * dy)
g.save(
os.path.join(
outfolder,
"p" + str(iperiod + 100000)[1:] + "_" + basegun + ".rle"),
"rle")
countbuilt += 1
#check we get the expected size
if usebb == 1:
if g.getrule() != 'LifeHistory':
g.exit('The rule should be in LifeHistory.')
# Get catalyst in various positions
if g.getselrect() != []:
g.shrink()
pattern = g.getcells(r)
patrlelist = []
translist =[(1,0,0,1), (1,0,0,-1), (-1,0,0,1), (-1,0,0,-1),
(0,1,1,0), (0,-1,1,0), (0,1,-1,0), (0,-1,-1,0)]
# Get unique transformed patterns
for trans in translist:
g.new('')
g.putcells(g.transform(pattern, 0, 0, *trans))
g.select(g.getrect())
g.copy()
patrle = ''.join(g.getclipstr().split('\n')[1:])
if patrle not in patrlelist:
patrlelist.append(patrle)
patrles = '\n'.join(patrlelist)
# Save data to file
catpath = g.savedialog('Catalyst File', 'all files(*.*)|*', catdir)
try:
with open(catpath, 'w') as catfile:
catfile.write(patrles)
g.exit('Catalyst file successfully generated at {}'.format(catpath))
except:
if catpath == '':
g.setclipstr(patrles)
# Use the current selection to create a toroidal universe. # Author: Andrew Trevorrow ([email protected]), Sept 2010. from glife import inside, outside import golly as g selrect = g.getselrect() if len(selrect) == 0: g.exit("There is no selection.") x = selrect[0] y = selrect[1] wd = selrect[2] ht = selrect[3] selcells = g.getcells(selrect) if not g.empty(): g.clear(inside) g.clear(outside) # get current rule, remove any existing suffix, then add new suffix rule = g.getrule().split(":")[0] g.setrule(rule + ":T" + str(wd) + "," + str(ht)) newx = -int(wd/2) newy = -int(ht/2) selrect[0] = newx selrect[1] = newy g.select(selrect) if len(selcells) > 0: g.putcells(selcells, newx - x, newy - y) g.fitsel()
def burp():
test_signal=pattern("""
40bo$41bo$39b3o17$40bo4bo4bo4bo4bo$41bo4bo4bo4bo4bo$39b3o2b3o2b3o2b3o
2b3o3$40bo4bo4bo4bo4bo$41bo4bo4bo4bo4bo$39b3o2b3o2b3o2b3o2b3o3$40bo4bo
4bo4bo4bo$41bo4bo4bo4bo4bo$39b3o2b3o2b3o2b3o2b3o3$40bo4bo4bo4bo4bo$41b
o4bo4bo4bo4bo$39b3o2b3o2b3o2b3o2b3o3$bo38bo4bo4bo4bo4bo18bo$2bo38bo4bo
4bo4bo4bo18bo$3o36b3o2b3o2b3o2b3o2b3o16b3o37$40bo$41bo$39b3o!""")
prepare_burp()
ticks=0
tickstep=5
last_signal=-99999
viewport_speed=16
sel_speed=0.0
delta_sel=0.0
delay=-1.0
run_flag=False
ch=""
selx=600.0
sely=365.0
place_signal=3
helpstring="""Use ENTER and SPACE to run or halt the pattern;
use + and - to change the step size or delay value;
use arrow keys and mouse tools to pan and zoom in any pane;
T toggles between a tiled view and a single-pane view;
S creates another signal fleet near the detection mechanism;
R resets the Heisenburp device to its initial state;
Q quits out of the script and restores original settings."""
instr="Press H for help. "
g.show(instr + str(tickstep))
g.select([selx,sely,50,50])
# keyboard handling
while ch<>"q":
if place_signal>0:
if ticks-last_signal>1846:
test_signal.put(-150,60)
last_signal=ticks
place_signal-=1
if place_signal>0 and run_flag==True:
show_status_text("Next signal placement in " \
+ str(1847 - ticks + last_signal) + " ticks. " + instr, delay, tickstep)
else:
show_status_text(instr,delay,tickstep)
event = g.getevent()
if event.startswith("key"):
evt, ch, mods = event.split()
else:
ch = ""
if ch=="r":
prepare_burp()
ticks=0
last_signal=-99999
viewport_speed=16
sel_speed=0
run_flag=False
selx=600.0
sely=365.0
place_signal=3
g.select([selx,sely,50,50])
elif ch=="h":
g.note(helpstring)
elif ch=="t":
g.setoption("tilelayers",1-g.getoption("tilelayers"))
elif ch=="=" or ch=="+":
if delay>.01:
delay/=2
elif delay==.01:
delay=-1
else:
if tickstep==1:
tickstep=3
elif tickstep<250:
tickstep=(tickstep-1)*2+1
elif ch=="-" or ch=="_":
if delay==-1:
if tickstep==1:
delay=.01
else:
if tickstep==3:
tickstep=1
else:
tickstep=(tickstep-1)/2+1
else:
if delay<1:
delay*=2
elif ch=="space":
run_flag=False
elif ch=="return":
run_flag=not run_flag
elif ch=="s":
place_signal+=1
else:
# just pass any other keyboard/mouse event through to Golly
g.doevent(event)
# generation and selection speed handling
if ch=="space" or run_flag==True:
g.run(tickstep)
currlayer = g.getlayer()
if currlayer != 4:
# user has switched layer so temporarily change it back
# so we only change location of bottom right layer
g.check(False)
g.setlayer(4)
x, y = getposint()
oldticks=ticks
ticks+=tickstep
delta_view=int(ticks/viewport_speed) - int(oldticks/viewport_speed)
if delta_view <> 0: # assumes diagonal motion for now
setposint(x + delta_view, y + delta_view)
sel = g.getselrect()
if len(sel)<>0:
x, y, w, h = sel
if int(selx)<>x: # user changed selection
# prepare to move new selection instead (!?!)
# -- use floating-point selx, sely to account for fractional speeds
selx=x
sely=y
else:
selx+=sel_speed*tickstep
sely+=sel_speed*tickstep
g.select([selx, sely, w, h])
else:
g.select([selx, sely, 50, 50])
if currlayer != 4:
g.setlayer(currlayer)
g.check(True)
# change viewport speed at appropriate times to follow the action
if oldticks<4570 and ticks>=4570:
sel_speed=.666667
# one-time correction to catch up with the signal at high sim speeds
g.select([600+(ticks-4570)*1.5, 365+(ticks-4570)*1.5, w, h])
if selx>2125:
sel_speed=0
g.select([2125, sely+2125-selx, w, h])
if oldticks<4750 and ticks>=4750: viewport_speed=1.5
if oldticks<6125 and ticks>=6125: viewport_speed=16
if oldticks>=11995: viewport_speed=99999.9
# stop automatically after the last signal passes through the device
if oldticks - last_signal<8705 and ticks - last_signal>=8705:
run_flag=False
if run_flag==True and delay>0:
sleep(delay)
g.update()
def oscillating():
# return True if the pattern is empty, stable or oscillating
# first get current pattern's bounding box
csel = g.getselrect()
g.shrink()
prect = g.getselrect()
g.select(csel)
pbox = rect(prect)
if pbox.empty:
g.show("The pattern is empty.")
return True
# get current pattern and create hash of "normalized" version -- ie. shift
# its top left corner to 0,0 -- so we can detect spaceships and knightships
## currpatt = pattern( g.getcells(prect) )
## h = hash( tuple( currpatt(-pbox.left, -pbox.top) ) )
# use Golly's hash command (3 times faster than above code)
h = g.hash(prect)
# check if outer-totalistic rule has B0 but not S8
rule = g.getrule().split(":")[0]
hasB0notS8 = rule.startswith("B0") and (rule.find("/") >
1) and not rule.endswith("8")
# determine where to insert h into hashlist
pos = 0
listlen = len(hashlist)
while pos < listlen:
if h > hashlist[pos]:
pos += 1
elif h < hashlist[pos]:
# shorten lists and append info below
del hashlist[pos:listlen]
del genlist[pos:listlen]
del poplist[pos:listlen]
del boxlist[pos:listlen]
break
else:
# h == hashlist[pos] so pattern is probably oscillating, but just in
# case this is a hash collision we also compare pop count and box size
if (pbox.wd == boxlist[pos].wd) and \
(pbox.ht == boxlist[pos].ht):
# (int(g.getpop()) == poplist[pos])
period = int(g.getgen()) - genlist[pos]
if hasB0notS8 and (period % 2 > 0) and (pbox == boxlist[pos]):
# ignore this hash value because B0-and-not-S8 rules are
# emulated by using different rules for odd and even gens,
# so it's possible to have identical patterns at gen G and
# gen G+p if p is odd
return False
if period == 1:
if pbox == boxlist[pos]:
g.show("The pattern is stable.")
else:
show_spaceship_speed(1, 0, 0)
elif pbox == boxlist[pos]:
g.show("Oscillator detected (period = " + str(period) +
")")
else:
deltax = abs(boxlist[pos].x - pbox.x)
deltay = abs(boxlist[pos].y - pbox.y)
show_spaceship_speed(period, deltax, deltay)
return True
else:
# look at next matching hash value or insert if no more
pos += 1
# store hash/gen/pop/box info at same position in various lists
hashlist.insert(pos, h)
genlist.insert(pos, int(g.getgen()))
poplist.insert(pos, int(g.getpop()))
boxlist.insert(pos, pbox)
return False
g.update()
# ------------------------------------------------------------------------------
selrect = g.getselrect()
if len(selrect) == 0: g.exit("There is no selection.")
selpatt = g.getcells(selrect)
# remember initial selection in case user aborts script
firstrect = g.getselrect()
firstpatt = g.getcells(selrect)
g.show("Click anywhere in selection, move mouse and click again..." + helpmsg)
oldcursor = g.getcursor()
g.setcursor("Move")
oldcells = []
try:
aborted = True
moveselection()
aborted = False
finally:
g.setcursor(oldcursor)
if aborted:
g.clear(0)
if len(oldcells) > 0: g.putcells(oldcells)
g.putcells(firstpatt)
g.select(firstrect)
else:
g.show(" ")
def moveselection():
global oldcells, selrect, selpatt
# wait for 1st click in selection
while True:
event = g.getevent()
if event.startswith("click"):
# event is a string like "click 10 20 left none"
evt, xstr, ystr, butt, mods = event.split()
x = int(xstr)
y = int(ystr)
if cellinrect(x, y, selrect):
oldmouse = xstr + ' ' + ystr
firstx = x
firsty = y
xoffset = firstx - selrect[0]
yoffset = firsty - selrect[1]
if mods == "alt":
# don't delete pattern in selection
oldcells = g.getcells(selrect)
break
elif event == "key h none":
showhelp1()
else:
g.doevent(event)
# wait for 2nd click while moving selection
g.show("Move mouse and click again..." + helpmsg)
gotclick = False
while not gotclick:
event = g.getevent()
if event.startswith("click"):
evt, x, y, butt, mods = event.split()
mousepos = x+' '+y
gotclick = True
else:
if len(event) > 0:
lookforkeys(event, x - firstx, y - firsty)
# update xoffset,yoffset in case selection was rotated
xoffset = x - selrect[0]
yoffset = y - selrect[1]
mousepos = g.getxy()
if len(mousepos) > 0 and mousepos != oldmouse:
# mouse has moved, so move selection rect and pattern
g.clear(0)
if len(oldcells) > 0: g.putcells(oldcells)
xstr, ystr = mousepos.split()
x = int(xstr)
y = int(ystr)
selrect[0] = x - xoffset
selrect[1] = y - yoffset
if g.getwidth() > 0:
# ensure selrect doesn't move beyond left/right edge of grid
if selrect[0] < gridl:
selrect[0] = gridl
x = selrect[0] + xoffset
elif selrect[0] + selrect[2] - 1 > gridr:
selrect[0] = gridr + 1 - selrect[2]
x = selrect[0] + xoffset
if g.getheight() > 0:
# ensure selrect doesn't move beyond top/bottom edge of grid
if selrect[1] < gridt:
selrect[1] = gridt
y = selrect[1] + yoffset
elif selrect[1] + selrect[3] - 1 > gridb:
selrect[1] = gridb + 1 - selrect[3]
y = selrect[1] + yoffset
g.select(selrect)
oldcells = g.getcells(selrect)
g.putcells(selpatt, x - firstx, y - firsty)
oldmouse = mousepos
g.update()
''' setconf2.py clears grid and sets just as specified by configuration conf2 in parameters.py ''' import parameters reload(parameters) from parameters import conf2, nstates from golly import setcell, clear, select, getrect, fit, show if len(getrect()) > 0: select(getrect()) clear(0) for i in range(0,len(conf2),2): c = conf2[i] if i+1 < len(conf2): c += conf2[i+1] * nstates setcell(i//2,0,c) show(str(i)) select([]) fit()
l = len(recipes.recipe) * step
iters = int(l / speed + l * 2 + l * (1 + 2 * speed) / (0.5 - speed))
iters = (1 + int(iters / distForward)) * distForward
g.show("Iterating Tail to reach " + str(iters) + " iter")
g.fit()
g.update()
#The speed is negative
Head = -speed * iters + 576
Tail = -speed * (iters - l * 2) + l + 576
GotoLimited(iters, 5)
rect = g.getrect()
g.select([rect[0], Head - 3 * distBack, rect[2], Tail - Head + 3 * distBack + 1500])
g.clear(1)
g.save(path.join(dir, str(step) + "_" + str(period) + "_Back.rle"), "rle", False)
#'''
#This code synchronize the backward recipes to fit with forward created at 0,0
g.show("synchronize the backward recipes to fit with forward")
g.new("")
MakeForwardSalvo(step, 0, 0, 0, True, True)
forwardRecipe = FindWssByDirection(True, distForward)
x0, y0, id = forwardRecipe[0]
ConvertToRelative(forwardRecipe, distForward)
while i < w:
j = 0
while j < h:
g.setcell(i, j, update[i][j])
j += 1
i += 1
g.update()
return update
try:
g.new("Conway's Game of life")
g.setrule("Life")
g.setcolors([1, 255, 255, 255])
g.setcolors([0, 0, 0, 0])
maxsize = 100000
count = 0
width = int( g.getstring("Enter a width for the game of life:", "100") )
height = int( g.getstring("Enter a height for the game of life:", "100") )
g.select([0, 0, width, height])
g.randfill(50)
update = [[0 for x in range(width + 1)] for x in range(height + 1)]
while count < maxsize:
g.show("In main " + str(count))
update = main(width, height, update)
count += 1
finally:
g.note("Goodbye")
