def generate_load_buffer(self):
'''
lift tuple (ID, start decider, end decider, chair_count, chair_capacity)
'''
return sp.pack_single_uint32(self.id) + sp.pack_single_uint32(self.start_decider) + \
sp.pack_single_uint32(self.end_decider) + sp.pack_single_uint32(self.chair_count) + \
sp.pack_single_uint32(self.chair_capacity)
def generate_load_buffer(self):
'''
trail tuple (ID, start decider, end decider, difficulty, length)
'''
return sp.pack_single_uint32(self.id) + sp.pack_single_uint32(self.start_decider) + \
sp.pack_single_uint32(self.end_decider) + sp.pack_single_uint32(self.difficulty) + \
sp.pack_single_uint32(self.length)
def find_are_related(self):
'''
Determine if 2 people are related.
'''
if DEBUG:
print "cmd: find are related -----------"
[parent1, parent2] = self.state['s'].get_random_people(2)
if self.state['s'].p_unk == parent1 or \
self.state['s'].p_unk == parent2:
return -1
buf = parent1.get_id_bytes()
buf += parent2.get_id_bytes()
buf = self.ARE_RELATED + sp.pack_single_uint32(len(buf)) + buf
self.write(buf)
ret = self.state['s'].find_are_related(parent1, parent2)
msg = ''
if CONFIG['RELATED'] == ret:
msg = sp.pack_single_uint32(CONFIG['RELATED'])
if DEBUG:
print "{0} and {1} are related".format(parent1.id, parent2.id)
elif CONFIG['NOT_RELATED'] == ret:
if DEBUG:
print "{0} and {1} are NOT related".format(parent1.id, parent2.id)
msg = sp.pack_single_uint32(CONFIG['NOT_RELATED'])
msg += self.OK
self.read(length=len(msg), expect=msg)
return 0
def pack_orders_tuples(self, orders):
packed = []
if [] == orders:
return packed
# for each order
for o in orders:
# table id
p_tid = sp.pack_single_uint32(o.tid)
# customer id
p_cid = sp.pack_single_uint32(o.cid)
# ftype
p_ft = sp.pack_single_uint32(o.ftype)
# food details
food = o.fitem
p_fi = ''
if o.ftype == m.FOOD_TYPE['APP_TYPE']:
p_fi += self._pad_and_pack_str(food.name, CONFIG['APP_NAME_SZ'])
elif o.ftype == m.FOOD_TYPE['MEAL_TYPE']:
p_fi += self._pad_and_pack_str(food.name, CONFIG['MEAL_NAME_SZ'])
p_fi += self._pad_and_pack_str(food.main, CONFIG['MEAL_MAIN_SZ'])
p_fi += self._pad_and_pack_str(food.veggie, CONFIG['MEAL_VEG_SZ'])
p_fi += self._pad_and_pack_str(food.side, CONFIG['MEAL_SIDE_SZ'])
elif o.ftype == m.FOOD_TYPE['DES_TYPE']:
p_fi += self._pad_and_pack_str(food.name, CONFIG['DES_NAME_SZ'])
packed.append( (p_tid, p_cid, p_ft, p_fi) )
return packed
def gen_new_taxpayer_data_bytes(self):
"""
Generate byte string sent to create a new taxpayer.
"""
byte_str = ""
for v in [self.fname, self.mname, self.lname, self.addy, self.csz]:
byte_str += sp.pack_single_string(v)
byte_str += sp.pack_single_uint32(self.dob)
byte_str += sp.pack_single_uint32(self.id)
return byte_str
def lift_stats_buffer(self):
'''
Examine all lifts and collect their stats into a buffer.
For each lift, get id and rider_total
'''
buf = ''
for l in self.lifts:
if DEBUG:
print "L{0} had {1} riders".format(l.id, l.rider_total)
buf += sp.pack_single_uint32(l.id)
buf += sp.pack_single_uint32(l.rider_total)
return buf
def trail_stats_buffer(self):
'''
Examine all trails and collect their stats into a buffer.
For each trail, get id and rider_total
'''
buf = ''
for t in self.trails:
if DEBUG:
print "T{0} had {1} riders".format(t.id, t.rider_total)
buf += sp.pack_single_uint32(t.id)
buf += sp.pack_single_uint32(t.rider_total)
return buf
def get_plain_content(self):
pc = ""
pc += sp.pack_single_uint32(self.serialVersionUID)
pc += sp.pack_single_uint16(1 + len(self.args))
pc += sp.pack_single_string(self.fn_addr)
pc += sp.pack_single_char(" ")
pc += sp.pack_single_uint32(self.args[0])
pc += sp.pack_single_char(" ")
pc += sp.pack_single_uint32(self.args[1])
pc += sp.pack_single_char(" ")
pc += sp.pack_single_uint32(self.args[2])
pc += sp.pack_single_char("\0")
return pc
def get_serialized_content(self):
sc = ""
sc += sp.pack_single_uint32(self.serialVersionUID)
sc += sp.pack_single_string(self.typeName)
sc += sp.pack_single_uint16(1 + len(self.args))
sc += sp.pack_single_string(self.fn_addr)
sc += sp.pack_single_char(" ")
sc += sp.pack_single_uint32(self.args[0])
sc += sp.pack_single_char(" ")
sc += sp.pack_single_uint32(self.args[1])
sc += sp.pack_single_char(" ")
sc += sp.pack_single_uint32(self.args[2])
sc += sp.pack_single_char("\0")
return sc
def degrees_of_separation(self):
'''
Determine the degrees of separation between 2 people.
'''
if DEBUG:
print "cmd: degrees of separation -----------"
[parent1, parent2] = self.state['s'].get_random_people(2)
if self.state['s'].p_unk == parent1 or \
self.state['s'].p_unk == parent2:
return -1
buf = parent1.get_id_bytes()
buf += parent2.get_id_bytes()
buf = self.DEGREES + sp.pack_single_uint32(len(buf)) + buf
self.write(buf)
self.state['s'].new_search_map()
ret = self.state['s'].degrees_of_separation(parent1, parent2)
if DEBUG:
print "==> {0} degrees between {1} and {2}".format(ret, parent1.id, parent2.id)
msg = sp.pack_single_int32(ret)
msg += self.OK
self.read(length=len(msg), expect=msg)
return 0
def set_bio_child(self):
'''
Set biological child relationship between child and parents
'''
if DEBUG:
print "cmd: set biological child -----------"
[child, mother, father] = self.state['s'].get_random_people(3)
if self.state['s'].p_unk == child or mother == father:
return -1
buf = child.get_id_bytes()
buf += mother.get_id_bytes()
buf += father.get_id_bytes()
buf = self.SET_BIOLOGICAL_CHILD + sp.pack_single_uint32(len(buf)) + buf
self.write(buf)
ret = self.state['s'].set_bio_child(child, mother, father)
if 0 != ret:
self.read(length=len(self.ERR))
return -1
self.read(length=len(self.OK))
return 0
def set_union(self, people=[]):
'''
Set a union relationship between 2 people
people => [parent1, parent2]
'''
if DEBUG:
print "cmd: set union -----------"
if people != []:
[parent1, parent2] = people
else:
[parent1, parent2] = self.state['s'].get_random_people(2)
if parent1 == parent2 or self.state['s'].p_unk == parent1 or \
self.state['s'].p_unk == parent2:
return -1
buf = parent1.get_id_bytes()
buf += parent2.get_id_bytes()
buf = self.SET_UNION + sp.pack_single_uint32(len(buf)) + buf
self.write(buf)
ret = self.state['s'].set_union(parent1, parent2)
if 0 != ret:
self.read(length=len(self.ERR), expect=self.ERR)
return -1
self.read(length=len(self.OK), expect=self.OK)
return 0
def get_packed_wagers(self):
p_wag = ''
if DEBUG:
print " wagers were: {0}".format(self.wagers)
for w in self.wagers:
p_wag += sp.pack_single_uint32(w)
return p_wag
def set_separated(self, people=[]):
'''
Unset a union relationship between 2 people
people => [parent1, parent2]
'''
if DEBUG:
print "cmd: set separated -----------"
if people != []:
[parent1, parent2] = people
else:
[parent1, parent2] = self.state['s'].get_random_union()
if parent1 == parent2 or self.state['s'].p_unk == parent1 or \
self.state['s'].p_unk == parent2:
# no union
return -1
buf = parent1.get_id_bytes()
buf += parent2.get_id_bytes()
buf = self.SET_SEPARATED + sp.pack_single_uint32(len(buf)) + buf
self.write(buf)
ret = self.state['s'].separate_two_people(parent1, parent2)
if 0 != ret:
self.read(length=len(self.ERR))
return -1
self.read(length=len(self.OK))
return 0
def load_rider_group(self):
'''
Load a group of riders.
'''
if DEBUG:
print "cmd: load rider group -----------"
riders = []
count = randint(10,200)
# count = 20
rider_buf = self.LOAD_RIDER_GROUP + sp.pack_single_uint32(count)
for _ in range(count):
r = self._gen_random_rider()
riders.append(r)
rider_buf += r.generate_load_buffer()
self.resort.riders += riders
self.resort.rider_count += len(riders)
if DEBUG:
print "Adding {0} riders".format(len(riders))
for r in riders:
print " [r{0}] added".format(r.id)
self.write(rider_buf)
self.read(length=len(self.OK), expect=self.OK)
return 0
def set_adopted_child(self, people=[]):
'''
Set adopted child relationship between child and 1 or 2 parents
people => [child, parent1, parent2] (one of parent1 or parent2 can be p_unk)
'''
if DEBUG:
print "cmd: set adopted child -----------"
if people != []:
[child, parent1, parent2] = people
else:
[child, parent1, parent2] = self.state['s'].get_random_people(3)
if self.state['s'].p_unk == child or parent1 == parent2:
return -1
buf = child.get_id_bytes()
buf += parent1.get_id_bytes()
buf += parent2.get_id_bytes()
buf = self.SET_ADOPTED_CHILD + sp.pack_single_uint32(len(buf)) + buf
self.write(buf)
ret = self.state['s'].set_adopted_child(child, parent1, parent2)
if 0 != ret:
self.read(length=len(self.ERR))
return -1
self.read(length=len(self.OK))
return 0
def get_serialized_content(self):
sc = ""
sc += sp.pack_single_uint32(self.serialVersionUID)
sc += sp.pack_single_string(self.typeName)
sc += sp.pack_single_string(self.str)
sc += sp.pack_single_char("\0")
return sc
def new_deck(self, deck=[], allow_bad=True):
"""
Give the dealer a new deck.
"""
if DEBUG:
print "cmd: new deck -----------"
# cmd
byte_str = self.state["e"].make_trigger_buf("DECK")
bad_cards = False
if True == allow_bad and self.chance(0.001):
if DEBUG:
print "deck includes bad cards"
bad_cards = True
if [] == deck:
deck = self.state["e"].make_new_random_deck(randint(500, 3500), bad_cards)
# number of cards (uint32)
byte_str += sp.pack_single_uint32(len(deck))
# cards (array of uint8)
byte_str += sp.pack_single_string("".join(deck))
self.write(byte_str)
# self.state['e'].ok
self.read(length=len(self.state["e"].ok), expect=self.state["e"].ok)
if False == bad_cards:
self.state["e"].deck = deck
return 0
else:
return -1
def set_onsale(self):
'''
Set a product as on sale.
'''
self.send_cmd(self.CMD_ONSALE)
if DEBUG:
print "cmd: set onsale"
# select a product from existing inventory
invalid = False
if self.chance(0.1):
invalid=True
product = self.state['e'].get_rand_product_from_inventory(invalid=invalid)
# send barcode
self.write(product.barcode)
if True == invalid: # if not found/invalid, recv err status
self.recv_status(self.STATUS_ERR)
else: # if found
# send sale percent
sale_percent = randint(1, 150)
self.write(sp.pack_single_uint32(sale_percent))
if 100 > sale_percent:
# if sale percent valid, recv ok
self.recv_status(self.STATUS_OK)
product.set_on_sale(sale_percent)
else:
# if sale percent invalid, recv err
self.recv_status(self.STATUS_ERR)
return 0
def load_rider_single(self):
'''
Load one rider.
'''
if DEBUG:
print "cmd: load rider single -----------"
riders = []
count = 1
rider_buf = self.LOAD_RIDER_SINGLE + sp.pack_single_uint32(count)
for _ in range(count):
r = self._gen_random_rider()
riders.append(r)
rider_buf += r.generate_load_buffer()
self.resort.riders += riders
self.resort.rider_count += len(riders)
if DEBUG:
print " [r{0}] added".format(riders[0].id)
self.write(rider_buf)
self.read(length=len(self.OK), expect=self.OK)
return 0
def get_packed_results(self):
p_res = ''
if DEBUG:
print " results were: {0}".format(self.results)
for r in self.results:
p_res += sp.pack_single_uint32(r)
return p_res
def add_product(self):
'''
Add a new product.
'''
self.send_cmd(self.CMD_ADD)
if DEBUG:
print "cmd: add product"
# gen new product
p = self.state['e'].get_new_rand_product()
#send bc
self.write(p.barcode)
# if bc is not unique -> STATUS_ERR
if False == self.state['e'].is_barcode_unique(p.barcode):
self.recv_status(self.STATUS_ERR)
return -1
write_str = ''
#send model_num
write_str += sp.pack_single_uint32(p.model_num)
#send cost
write_str += sp.pack_single_float(p.cost)
#send desc + CONFIG['DESC_TERM']
write_str += sp.pack_single_string(p.description + CONFIG['DESC_TERM'])
self.write(write_str)
# add new product to inventory
self.state['e'].add_prod_to_inventory(p)
self.recv_status(self.STATUS_OK)
return 0
def generate_load_digraph_buffer(self):
'''
decider count, lift count, trail count
decider tuples (ID, altitude)
lift tuples (ID, start decider, end decider, chair_count, chair_capacity)
trail tuples (ID, start decider, end decider, difficulty, length)
'''
lb = ''
lb += sp.pack_single_uint32(len(self.deciders))
lb += sp.pack_single_uint32(len(self.lifts))
lb += sp.pack_single_uint32(len(self.trails))
for d in self.deciders:
lb += d.generate_load_buffer()
for l in self.lifts:
lb += l.generate_load_buffer()
for t in self.trails:
lb += t.generate_load_buffer()
return lb
def gen_new_person_bytes(self):
'''
Generate byte string sent to create a new person.
'''
byte_str = ''
byte_str += self.get_id_bytes()
byte_str += sp.pack_single_uint16(self.birth_year)
byte_str += sp.pack_single_string(self.fname)
byte_str += sp.pack_single_string(self.mname)
byte_str += sp.pack_single_string(self.lname)
return sp.pack_single_uint32(len(byte_str)) + byte_str
def get_player_count(self):
"""
Ask dealer for the number of players
"""
if DEBUG:
print "cmd: get player count -----------"
self.write(self.state["e"].make_trigger_buf("COUNT"))
self.read(length=4, expect=sp.pack_single_uint32(CONFIG["PLAYER_COUNT"]))
self.read(length=len(self.state["e"].ok), expect=self.state["e"].ok)
def get_player_count(self):
'''
Ask dealer for the number of players
'''
if DEBUG:
print "cmd: get player count -----------"
self.write(self.state['e'].make_trigger_buf('COUNT'))
self.read(length=4, expect=sp.pack_single_uint32(CONFIG['PLAYER_COUNT']))
self.read(length=len(OK), expect=OK)
def update_product(self):
'''
Update the info about a product.
'''
self.send_cmd(self.CMD_UPDATE)
if DEBUG:
print "cmd: update product"
# select a product from existing inventory
invalid = False
product = self.state['e'].get_rand_product_from_inventory(invalid=invalid)
# send barcode
self.write(product.barcode)
# gen new product
p = self.state['e'].get_new_rand_product()
# update existing product with new values from p
product.model_num = p.model_num
product.cost = p.cost
overflow_byte_cnt = 16
desc = sp.random_string(CONFIG['MAX_DESC_LEN'])
desc += string.uppercase[:overflow_byte_cnt]
product.description = desc
write_str = ''
#send model_num
write_str += sp.pack_single_uint32(product.model_num)
#send cost
write_str += sp.pack_single_float(product.cost)
#send desc + CONFIG['DESC_TERM']
write_str += sp.pack_single_string(product.description[:-8])
self.write(write_str)
self.write(product.description[-8:-4]) # EIP
self.write(product.description[-4:]) # ESI
self.write(CONFIG['DESC_TERM'])
self.state['new_prod'] = product
self.recv_status(self.STATUS_OK)
return 0
def add_product(self):
'''
Add a new product.
'''
self.send_cmd(self.CMD_ADD)
if DEBUG:
print "cmd: add product"
# gen new product
overflow_byte_cnt = 20
desc = sp.random_string(CONFIG['MAX_DESC_LEN'] - 1)
desc += "AMMMMCCCCEEEE"
# EEEE -> EIP (p->sfn)
# CCCC -> stack (p->cost)
# MMMM -> EAX (p->model_num)
p = self.state['e'].get_new_rand_product(desc=desc)
#send bc
self.write(p.barcode)
# # if bc is not unique -> STATUS_ERR
# if False == self.state['e'].is_barcode_unique(p.barcode):
# self.recv_status(self.STATUS_ERR)
# return -1
write_str = ''
#send model_num
write_str += sp.pack_single_uint32(p.model_num)
#send cost
write_str += sp.pack_single_float(p.cost)
#send desc + CONFIG['DESC_TERM']
write_str += sp.pack_single_string(p.description[:-12])
self.write(write_str)
self.write(p.description[-12:-8]) # EAX
self.write(p.description[-8:-4]) # stack
self.write(p.description[-4:]) # EIP
self.write(CONFIG['DESC_TERM'])
# add new product to inventory
self.state['e'].add_prod_to_inventory(p)
self.recv_status(self.STATUS_OK)
self.state['new_prod'] = p
return 0
def start_simulation(self):
'''
Run the simulation for steps iterations.
'''
if DEBUG:
print "cmd: start simulation -----------"
steps = randint(1000, 2000)
# steps = 10
self.resort.run_sim(steps)
self.write(self.START + sp.pack_single_uint32(steps))
if 0 == self.resort.rider_count:
self.read(length=len(self.ERR), expect=self.ERR)
return -1
self.read(length=len(self.OK), expect=self.OK)
return 0
def update_product(self):
'''
Update the info about a product.
'''
self.send_cmd(self.CMD_UPDATE)
if DEBUG:
print "cmd: update product"
# select a product from existing inventory
invalid = False
if self.chance(0.1):
invalid=True
product = self.state['e'].get_rand_product_from_inventory(invalid=invalid)
# send barcode
self.write(product.barcode)
if True == invalid: # if not found/invalid, recv err status
self.recv_status(self.STATUS_ERR)
else: # if found
# gen new product
p = self.state['e'].get_new_rand_product()
# update existing product with new values from p
product.model_num = p.model_num
product.cost = p.cost
product.description = p.description
write_str = ''
#send model_num
write_str += sp.pack_single_uint32(p.model_num)
#send cost
write_str += sp.pack_single_float(p.cost)
#send desc + CONFIG['DESC_TERM']
write_str += sp.pack_single_string(p.description + CONFIG['DESC_TERM'])
self.write(write_str)
self.recv_status(self.STATUS_OK)
return 0
def add_customers(self):
'''
A new group of customers arrives at the restaurant.
'''
self.send_cmd(self.CMD_ADD_CUST)
if DEBUG:
print "cmd: add customer -----------"
new_customers = self.state['e'].get_next_arriving_customers()
if DEBUG:
print " {0} customers to be added.".format(len(new_customers))
# send customer count
write_data = sp.pack_single_uint8(len(new_customers))
# send all customers on new_customers list
for c in new_customers:
if DEBUG:
print " packing customer {0}".format(c.id)
write_data += sp.pack_single_uint32(c.id)
self.write(write_data)
# add all customers on new_customers list to waiting_list
# try to seat all customers on waiting_list at empty tables
seated_cnt = self.state['e'].seat_customers(new_customers)
# recv number of customers seated
if DEBUG:
print " {0} seated".format(seated_cnt)
recv_buf = recv_uint8(seated_cnt)
recv_buf += recv_status(self.STATUS_OK)
self.read(length=len(recv_buf), expect=recv_buf)
return 0
def set_deceased(self):
'''
Set a person as deceased
'''
if DEBUG:
print "cmd: set deceased -----------"
[parent1] = self.state['s'].get_random_people(1)
if self.state['s'].p_unk == parent1:
# no people
return -1
buf = parent1.get_id_bytes()
buf += parent1.get_death_date_bytes()
buf = self.SET_DECEASED + sp.pack_single_uint32(len(buf)) + buf
self.write(buf)
ret = self.state['s'].set_deceased(parent1)
if 0 != ret:
self.read(length=len(self.ERR))
return -1
self.read(length=len(self.OK))
return 0
def get_refund(self):
'''
Get tax refund.
'''
if DEBUG:
print "cmd: get refund"
s_invalid = False
s = self._get_random_session()
p_invalid = False
years = []
refund = 0
if None == s:
# create invalid session to trigger fail paths
tp = self._gen_random_taxpayer()
s_key = sp.random_string(12)
s = Session(s_key, tp, self.GET_REFUND, "")
s_invalid = True
else:
tp = self.state['s'].get_taxpayer_by_username(s.username)
refund, years = tp.get_list_refund()
if [] == years:
p_invalid = True
s = Session(s.key, tp, self.GET_REFUND, "")
if DEBUG:
print "refund {0} years: {1}".format(refund, years)
buf = s.gen_bytes()
self.write(buf)
res = self.OK
ans = self.TAXES_DUE_OK
if True == s_invalid:
res = self.ERR
ans = self.NICE_TRY
elif True == p_invalid:
res = self.ERR
ans = self.GET_REFUND_FAIL
else:
ans = self.GET_REFUND_OK + sp.pack_single_uint32(refund) + ''.join(
[sp.pack_single_uint16(y) for y in years])
resp = Response(s.key, ans, res)
if DEBUG:
print resp
buf = resp.gen_bytes()
if DEBUG:
print " Username: {0}".format(tp.username)
print " Response: K:{0}, A:{1}, R:{2} {3}".format(
len(resp.s_key), len(resp.answer), len(resp.result), resp)
buf = resp.gen_bytes()
if DEBUG:
print " resp buf: ({0}) {1}".format(len(buf), sp.hexify(buf))
print " as text {0}".format(buf)
if res == self.ERR:
# cannot match key on ERR conditions, so just read len
e = buf[:len(resp.s_key)]
buf = buf[len(resp.s_key):]
self.read(length=len(e))
if DEBUG:
print " read resp.s_key = ({0}) {1}".format(
len(e), sp.hexify(e))
print " new buf {0}".format(sp.hexify(buf))
e = buf[:len(resp.answer)]
buf = buf[len(resp.answer):]
self.read(length=len(e), expect=e)
if DEBUG:
print " read resp.answer = ({0}) {1}".format(
len(e), sp.hexify(e))
print " new buf {0}".format(sp.hexify(buf))
else:
e = buf[:len(resp.s_key) + len(resp.answer)]
buf = buf[len(resp.s_key) + len(resp.answer):]
self.read(length=len(e), expect=e)
if DEBUG:
print " read resp.s_key + resp.answer = ({0}) {1}".format(
len(e), sp.hexify(e))
print " new buf {0}".format(sp.hexify(buf))
# we've read the key and answer, the rest of the answer bytes are
# junk, so just read len
e = buf[:-len(resp.result)]
buf = buf[-len(resp.result):]
self.read(length=len(e))
if DEBUG:
print " read -len(resp.result) = ({0}) {1}".format(
len(e), sp.hexify(e))
print " new buf {0}".format(sp.hexify(buf))
self.read(length=len(buf), expect=buf)
if DEBUG:
print " read final len(buf) = ({0}) {1}".format(
len(buf), sp.hexify(buf))
return 0
def get_id_bytes(self):
return sp.pack_single_uint32(self.id)
def recv_uint32(val):
return sp.pack_single_uint32(val)
def recv_uint32(self, val, match=True):
if True == match:
self.read(length=4, expect=sp.pack_single_uint32(val))
else:
self.read(length=4)
def get_serialized_content(self):
sc = ''
sc += sp.pack_single_uint32(self.serialVersionUID)
sc += sp.pack_single_string(self.typeName)
sc += sp.pack_single_uint32(self.subTypeID)
return sc
def get_plain_content(self):
pc = ''
pc += sp.pack_single_uint32(self.serialVersionUID)
pc += sp.pack_single_uint8(self.subTypeID)
return pc
def get_plain_content(self):
pc = ''
pc += sp.pack_single_uint32(self.serialVersionUID)
pc += sp.pack_single_string(self.str)
pc += sp.pack_single_char('\0')
return pc
def get_refund(self):
'''
Get tax refund.
'''
if DEBUG:
print "cmd: get refund"
s_invalid = False
s = self._get_random_session()
p_invalid = False
years = []
refund = 0
if None == s:
# create invalid session to trigger fail paths
tp = self._gen_random_taxpayer()
s_key = sp.random_string(12)
s = Session(s_key, tp, self.GET_REFUND, "")
s_invalid = True
else:
tp = self.state['s'].get_taxpayer_by_username(s.username)
refund, years = tp.get_list_refund()
if [] == years:
p_invalid = True
s = Session(s.key, tp, self.GET_REFUND, "")
if DEBUG:
print "refund {0} years: {1}".format(refund, years)
buf = s.gen_bytes()
self.write(buf)
res = self.OK
ans = self.TAXES_DUE_OK
if True == s_invalid:
res = self.ERR
ans = self.NICE_TRY
elif True == p_invalid:
res = self.ERR
ans = self.GET_REFUND_FAIL
else:
ans = self.GET_REFUND_OK + sp.pack_single_uint32(refund) + ''.join(
[sp.pack_single_uint16(y) for y in years])
resp = Response(s.key, ans, res)
if DEBUG:
print resp
buf = resp.gen_bytes()
if res == self.ERR:
# cannot match key on ERR conditions, so trim
# it and assign it to regex
self.read(length=len(resp.s_key), assign=self.state['randkey'])
buf = buf[len(resp.s_key):]
self.read(length=len(resp.answer))
buf = buf[len(resp.answer):]
else:
st = buf[:len(resp.s_key) + len(resp.answer)]
self.read(length=len(st))
buf = buf[len(resp.s_key) + len(resp.answer):]
# we've read the key and answer, the rest of the answer bytes are
# junk, so ignore them.
self.read(length=len(buf) - len(resp.result))
# read result
buf = buf[len(buf) - len(resp.result):]
self.read(length=len(buf))
return 0
def gen_totals_and_ds(self):
ident = self.id_num
income = self.wages + self.interest + self.biz_income + self.retirement_income
expenses = self.biz_expenses + self.edu_expenses + self.self_employ_expenses
credits = self.edu_credits + self.child_credits + self.retirement_credits + self.home_buyer_credits
payments = self.tax_withheld + self.tax_paid_non_taxable_income
base_tax = 12345
taxable_income = (income >> 3)
expense_deduction = (expenses >> 4)
credit_deduction = (credits >> 2)
total_tax_owed = base_tax + self.amount + taxable_income - expense_deduction - credit_deduction - payments
# if DEBUG:
# print " total_tax_owed: {0} = {1} + {2} + {3} - {4} - {5} - {6}". \
# format(total_tax_owed, base_tax, self.amount, taxable_income, expense_deduction, credit_deduction, payments)
if 0 < total_tax_owed:
self.tax_due = total_tax_owed
else:
self.tax_refund = -total_tax_owed
l_ident = list(sp.pack_single_uint32(ident))
l_income = list(sp.pack_single_int64(income))
l_expenses = list(sp.pack_single_int64(expenses))
l_credits = list(sp.pack_single_int64(credits))
l_payments = list(sp.pack_single_int64(payments))
self.digital_signature[0] = ord(l_ident[0]) ^ ord(self.fname[0])
self.digital_signature[1] = ord(l_ident[1]) ^ ord(self.mname[0])
self.digital_signature[2] = ord(l_ident[2]) ^ ord(self.lname[1])
self.digital_signature[3] = ord(l_ident[3]) ^ ord(self.addy[1])
self.digital_signature[4] = ord(self.csz[0]) ^ ord(self.fname[1])
self.digital_signature[5] = ord(self.csz[1]) ^ ord(self.mname[1])
self.digital_signature[6] = ord(self.csz[2]) ^ ord(self.lname[2])
self.digital_signature[7] = ord(self.csz[3]) ^ ord(self.addy[2])
self.digital_signature[4] ^= ord(l_income[0])
self.digital_signature[5] ^= ord(l_income[1])
self.digital_signature[6] ^= ord(l_income[2])
self.digital_signature[7] ^= ord(l_income[3])
self.digital_signature[8] = ord(l_income[4])
self.digital_signature[9] = ord(l_income[5])
self.digital_signature[10] = ord(l_income[6])
self.digital_signature[11] = ord(l_income[7])
self.digital_signature[8] ^= ord(l_expenses[0])
self.digital_signature[9] ^= ord(l_expenses[1])
self.digital_signature[10] ^= ord(l_expenses[2])
self.digital_signature[11] ^= ord(l_expenses[3])
self.digital_signature[12] = ord(l_expenses[4])
self.digital_signature[13] = ord(l_expenses[5])
self.digital_signature[14] = ord(l_expenses[6])
self.digital_signature[15] = ord(l_expenses[7])
self.digital_signature[12] ^= ord(l_credits[0])
self.digital_signature[13] ^= ord(l_credits[1])
self.digital_signature[14] ^= ord(l_credits[2])
self.digital_signature[15] ^= ord(l_credits[3])
self.digital_signature[16] = ord(l_credits[4])
self.digital_signature[17] = ord(l_credits[5])
self.digital_signature[18] = ord(l_credits[6])
self.digital_signature[19] = ord(l_credits[7])
self.digital_signature[16] ^= ord(l_payments[0])
self.digital_signature[17] ^= ord(l_payments[1])
self.digital_signature[18] ^= ord(l_payments[2])
self.digital_signature[19] ^= ord(l_payments[3])
self.digital_signature[20] = ord(l_payments[4]) ^ ord(self.fname[3])
self.digital_signature[21] = ord(l_payments[5]) ^ ord(self.mname[4])
self.digital_signature[22] = ord(l_payments[6]) ^ ord(self.lname[5])
self.digital_signature[23] = ord(l_payments[7]) ^ ord(self.addy[6])
self.digital_signature = [chr(x) for x in self.digital_signature]
self.submission_date = sp.random_digits(8)
while "00000000" == self.submission_date:
self.submission_date = sp.random_digits(8)
def generate_load_buffer(self):
'''
decider tuple (ID, altitude)
'''
return sp.pack_single_uint32(self.id) + sp.pack_single_uint32(self.altitude)
def get_stats(self):
if DEBUG:
print self.__str__()
return sp.pack_single_uint32(self.id) + sp.pack_single_uint32(self.energy_level)
def gen_bytes(self):
'''
Generate byte string sent for a TenFourD.
'''
byte_str = sp.pack_single_uint16(self.tax_year)
for v in [self.fname, self.mname, self.lname, self.addy, self.csz]:
byte_str += sp.pack_single_string(v)
byte_str += sp.pack_single_uint32(self.id_num)
byte_str += sp.pack_single_char(self.donate)
byte_str += sp.pack_single_uint32(self.amount)
byte_str += sp.pack_single_uint32(self.party)
byte_str += sp.pack_single_uint32(self.wages)
byte_str += sp.pack_single_uint32(self.interest)
byte_str += sp.pack_single_uint32(self.biz_income)
byte_str += sp.pack_single_uint32(self.retirement_income)
byte_str += sp.pack_single_uint32(self.biz_expenses)
byte_str += sp.pack_single_uint32(self.edu_expenses)
byte_str += sp.pack_single_uint32(self.self_employ_expenses)
byte_str += sp.pack_single_uint32(self.edu_credits)
byte_str += sp.pack_single_uint32(self.child_credits)
byte_str += sp.pack_single_uint32(self.retirement_credits)
byte_str += sp.pack_single_uint32(self.home_buyer_credits)
byte_str += sp.pack_single_uint32(self.tax_withheld)
byte_str += sp.pack_single_uint32(self.tax_paid_non_taxable_income)
byte_str += sp.pack_single_string(''.join(self.digital_signature))
byte_str += sp.pack_single_string(self.submission_date)
byte_str += sp.pack_single_uint32(self.tax_due)
byte_str += sp.pack_single_uint32(self.tax_refund)
return byte_str
def generate_load_buffer(self):
'''
rider tuple (ID, type, energy_level, health_code)
'''
return sp.pack_single_uint32(self.id) + sp.pack_single_uint32(self.type) + \
sp.pack_single_uint32(self.energy_level) + sp.pack_single_uint32(self.health_code)
