q_size = num_size
if regs is None:
- regs = {}
+ regs = {
+ "n_0": 4,
+ "d_0": 32,
+ "u": 36,
+ "m": 3,
+ "v": 32,
+ "n_scalar": 8,
+ "q": 4,
+ "vn": 32,
+ "un": 36,
+ "product": 46,
+ "r": 8,
+ "t_single": 8,
+ "s_scalar": 10,
+ "t_for_uv_shift": 0,
+ "n_for_unnorm": 32,
+ "t_for_unnorm": 3,
+ "s_for_unnorm": 34,
+ "qhat": 12,
+ "rhat": 0,
+ "t_for_prod": 0,
+ }
self.num_size = num_size
self.denom_size = denom_size
def python(self, n, d, log_regex=False, on_corner_case=lambda desc: None):
do_log = _DivModRegsRegexLogger(enabled=log_regex, regs=self.regs).log
+ do_log(locals(), n=("n_0", self.num_size), d=("d_0", self.denom_size))
+
# switch to names used by Knuth's algorithm D
u = list(n) # dividend
assert len(u) == self.num_size, "numerator has wrong size"
+ do_log(locals(), n=None, u=("u", self.num_size))
m = len(u) # length of dividend
+ do_log(locals(), m="m")
v = list(d) # divisor
assert len(v) == self.denom_size, "denominator has wrong size"
del d # less confusing to debug
+ do_log(locals(), d=None, v=("v", self.denom_size))
n = len(v) # length of divisor
+ do_log(locals(), n="n_scalar")
# allocate outputs/temporaries -- before any normalization so
# the outputs/temporaries can be fixed-length in the assembly version.
q = [0] * self.q_size # quotient
+ do_log(locals(), q=("q", self.q_size))
vn = [None] * self.vn_size # normalized divisor
+ do_log(locals(), vn=("vn", self.vn_size))
un = [None] * self.un_size # normalized dividend
+ do_log(locals(), un=("un", self.un_size))
product = [None] * self.product_size
+ do_log(locals(), product=("product", self.product_size))
# get non-zero length of dividend
while m > 0 and u[m - 1] == 0:
m -= 1
+ do_log(locals())
+
# get non-zero length of divisor
while n > 0 and v[n - 1] == 0:
n -= 1
+ do_log(locals())
+
if n == 0:
raise ZeroDivisionError
if m > self.q_size:
t = u[self.q_size]
m = self.q_size
+ do_log(locals(), t="t_single", n=None)
for i in reversed(range(m)):
# divmod2du
t <<= self.word_size
t += u[i]
q[i] = t // v[0]
t %= v[0]
+ do_log(locals())
r = [0] * self.r_size # remainder
r[0] = t
+ do_log(locals(), t=None, r=("r", self.r_size))
return q, r
if m < n:
r = [None] * self.r_size # remainder
+ do_log(locals(), r=("r", self.r_size), n=None)
# dividend < divisor
for i in range(self.r_size):
r[i] = u[i]
+ do_log(locals())
return q, r
# Knuth's algorithm D starts here:
while (v[n - 1] << s) >> (self.word_size - 1) == 0:
s += 1
+ do_log(locals(), s="s_scalar")
+
if s != 0:
on_corner_case("non-zero shift")
# vn = v << s
t = 0
+ do_log(locals(), t="t_for_uv_shift")
for i in range(n):
# dsld
t |= v[i] << s
+ v[i] = None # mark reg as unused
vn[i] = t % 2 ** self.word_size
t >>= self.word_size
+ do_log(locals())
# un = u << s
t = 0
+ do_log(locals(), v=None)
for i in range(m):
# dsld
t |= u[i] << s
+ u[i] = None # mark reg as unused
un[i] = t % 2 ** self.word_size
t >>= self.word_size
+ do_log(locals())
un[m] = t
+ do_log(locals(), u=None, t=None)
+
# Step D2 and Step D7: loop
for j in range(min(m - n, self.q_size - 1), -1, -1):
# Step D3: calculate q̂
qhat = t // vn[n - 1]
rhat = t % vn[n - 1]
+ do_log(locals(), qhat="qhat", rhat="rhat")
+
while rhat < 2 ** self.word_size:
if qhat * vn[n - 2] > (rhat << self.word_size) + un[j + n - 2]:
on_corner_case("qhat adjustment")
qhat -= 1
rhat += vn[n - 1]
+ do_log(locals())
else:
break
+ do_log(locals(), rhat=None)
+
# Step D4: multiply and subtract
t = 0
+ do_log(locals(), t="t_for_prod")
for i in range(n):
# maddedu
t += vn[i] * qhat
product[i] = t % 2 ** self.word_size
t >>= self.word_size
+ do_log(locals())
product[n] = t
+ do_log(locals(), t=None)
t = 1
for i in range(n + 1):
t += not_product + un[j + i]
un[j + i] = t % 2 ** self.word_size
t = int(t >= 2 ** self.word_size)
+ do_log(locals())
need_fixup = not t
# Step D5: test remainder
on_corner_case("add back")
qhat -= 1
+ do_log(locals())
t = 0
for i in range(n):
t += un[j + i] + vn[i]
un[j + i] = t % 2 ** self.word_size
t = int(t >= 2 ** self.word_size)
+ do_log(locals())
un[j + n] += t
+ do_log(locals())
q[j] = qhat
+ do_log(locals())
# Step D8: un-normalize
+ do_log(locals(), s="s_for_unnorm", vn=None)
r = [0] * self.r_size # remainder
+ do_log(locals(), r=("r", self.r_size), n="n_for_unnorm")
# r = un >> s
t = 0
+ do_log(locals(), t="t_for_unnorm", m=None)
for i in reversed(range(n)):
# dsrd
t <<= self.word_size
t |= (un[i] << self.word_size) >> s
r[i] = t >> self.word_size
t %= 2 ** self.word_size
+ do_log(locals())
return q, r
projects / openpower-isa.git / commitdiff