bra.l _real_ovfl
-# overflow occurred but is disabled. meanwhile, inexact is enabled. therefore,
+# overflow occurred but is disabled. meanwhile, inexact is enabled. Therefore,
# we must jump to real_inex().
fovfl_inex_on:
bra.l _real_unfl
-# undeflow occurred but is disabled. meanwhile, inexact is enabled. therefore,
+# underflow occurred but is disabled. meanwhile, inexact is enabled. Therefore,
# we must jump to real_inex().
funfl_inex_on:
tst.w %d0 # is instr fmovm?
bmi.b iea_dis_fmovm # yes
-# instruction is using an extended precision immediate operand. therefore,
+# instruction is using an extended precision immediate operand. Therefore,
# the total instruction length is 16 bytes.
iea_dis_immed:
mov.l &0x10,%d0 # 16 bytes of instruction
bge.b sok_norm2 # thank goodness no
# the multiply factor that we're trying to create should be a denorm
-# for the multiply to work. therefore, we're going to actually do a
+# for the multiply to work. Therefore, we're going to actually do a
# multiply with a denorm which will cause an unimplemented data type
# exception to be put into the machine which will be caught and corrected
# later. we don't do this with the DENORMs above because this method
#
# operand will underflow AND underflow or inexact is enabled.
-# therefore, we must return the result rounded to extended precision.
+# Therefore, we must return the result rounded to extended precision.
#
fin_sd_unfl_ena:
mov.l FP_SCR0_HI(%a6),FP_SCR1_HI(%a6)
#
# The destination was In Range and the source was a ZERO. The result,
-# therefore, is an INF w/ the proper sign.
+# Therefore, is an INF w/ the proper sign.
# So, determine the sign and return a new INF (w/ the j-bit cleared).
#
global fdiv_inf_load # global for fsgldiv
#
# operand will underflow AND underflow is enabled.
-# therefore, we must return the result rounded to extended precision.
+# Therefore, we must return the result rounded to extended precision.
#
fneg_sd_unfl_ena:
mov.l FP_SCR0_HI(%a6),FP_SCR1_HI(%a6)
#
# operand will underflow AND underflow is enabled.
-# therefore, we must return the result rounded to extended precision.
+# Therefore, we must return the result rounded to extended precision.
#
fabs_sd_unfl_ena:
mov.l FP_SCR0_HI(%a6),FP_SCR1_HI(%a6)
#
# the ZEROes have opposite signs:
-# - therefore, we return +ZERO if the rounding modes are RN,RZ, or RP.
+# - Therefore, we return +ZERO if the rounding modes are RN,RZ, or RP.
# - -ZERO is returned in the case of RM.
#
fadd_zero_2_chk_rm:
#
# the ZEROes have the same signs:
-# - therefore, we return +ZERO if the rounding mode is RN,RZ, or RP
+# - Therefore, we return +ZERO if the rounding mode is RN,RZ, or RP
# - -ZERO is returned in the case of RM.
#
fsub_zero_2_chk_rm:
#
# operand will underflow AND underflow is enabled.
-# therefore, we must return the result rounded to extended precision.
+# Therefore, we must return the result rounded to extended precision.
#
fsqrt_sd_unfl_ena:
mov.l FP_SCR0_HI(%a6),FP_SCR1_HI(%a6)
tst.l %d0
bne.b fout_pack_set
# "mantissa" is all zero which means that the answer is zero. but, the '040
-# algorithm allows the exponent to be non-zero. the 881/2 do not. therefore,
+# algorithm allows the exponent to be non-zero. the 881/2 do not. Therefore,
# if the mantissa is zero, I will zero the exponent, too.
# the question now is whether the exponents sign bit is allowed to be non-zero
# for a zero, also...
rts
# #
-# dnrm_lp(): normalize exponent/mantissa to specified threshhold #
+# dnrm_lp(): normalize exponent/mantissa to specified threshold #
# #
# INPUT: #
# %a0 : points to the operand to be denormalized #
bgt.b unnorm_nrm_zero # yes; denorm only until exp = 0
#
-# exponent would not go < 0. therefore, number stays normalized
+# exponent would not go < 0. Therefore, number stays normalized
#
sub.w %d0, %d1 # shift exponent value
mov.w FTEMP_EX(%a0), %d0 # load old exponent
git://ftp.safe.ca / safe / jmp / linux-2.6 / blobdiff